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/* auto-generated on 2021-01-20 13:20:49 -0500. Do not edit! */
/* begin file src/simdjson.cpp */
#include "../include/simdjson.h"
SIMDJSON_PUSH_DISABLE_WARNINGS
SIMDJSON_DISABLE_UNDESIRED_WARNINGS
/* begin file src/to_chars.cpp */
#include <cstring>
#include <cstdint>
#include <array>
namespace simdjson {
namespace internal {
/*!
implements the Grisu2 algorithm for binary to decimal floating-point
conversion.
Adapted from JSON for Modern C++
This implementation is a slightly modified version of the reference
implementation which may be obtained from
http://florian.loitsch.com/publications (bench.tar.gz).
The code is distributed under the MIT license, Copyright (c) 2009 Florian
Loitsch. For a detailed description of the algorithm see: [1] Loitsch, "Printing
Floating-Point Numbers Quickly and Accurately with Integers", Proceedings of the
ACM SIGPLAN 2010 Conference on Programming Language Design and Implementation,
PLDI 2010 [2] Burger, Dybvig, "Printing Floating-Point Numbers Quickly and
Accurately", Proceedings of the ACM SIGPLAN 1996 Conference on Programming
Language Design and Implementation, PLDI 1996
*/
namespace dtoa_impl {
template <typename Target, typename Source>
Target reinterpret_bits(const Source source) {
static_assert(sizeof(Target) == sizeof(Source), "size mismatch");
Target target;
std::memcpy(&target, &source, sizeof(Source));
return target;
}
struct diyfp // f * 2^e
{
static constexpr int kPrecision = 64; // = q
std::uint64_t f = 0;
int e = 0;
constexpr diyfp(std::uint64_t f_, int e_) noexcept : f(f_), e(e_) {}
/*!
@brief returns x - y
@pre x.e == y.e and x.f >= y.f
*/
static diyfp sub(const diyfp &x, const diyfp &y) noexcept {
return {x.f - y.f, x.e};
}
/*!
@brief returns x * y
@note The result is rounded. (Only the upper q bits are returned.)
*/
static diyfp mul(const diyfp &x, const diyfp &y) noexcept {
static_assert(kPrecision == 64, "internal error");
// Computes:
// f = round((x.f * y.f) / 2^q)
// e = x.e + y.e + q
// Emulate the 64-bit * 64-bit multiplication:
//
// p = u * v
// = (u_lo + 2^32 u_hi) (v_lo + 2^32 v_hi)
// = (u_lo v_lo ) + 2^32 ((u_lo v_hi ) + (u_hi v_lo )) +
// 2^64 (u_hi v_hi ) = (p0 ) + 2^32 ((p1 ) + (p2 ))
// + 2^64 (p3 ) = (p0_lo + 2^32 p0_hi) + 2^32 ((p1_lo +
// 2^32 p1_hi) + (p2_lo + 2^32 p2_hi)) + 2^64 (p3 ) =
// (p0_lo ) + 2^32 (p0_hi + p1_lo + p2_lo ) + 2^64 (p1_hi +
// p2_hi + p3) = (p0_lo ) + 2^32 (Q ) + 2^64 (H ) = (p0_lo ) +
// 2^32 (Q_lo + 2^32 Q_hi ) + 2^64 (H )
//
// (Since Q might be larger than 2^32 - 1)
//
// = (p0_lo + 2^32 Q_lo) + 2^64 (Q_hi + H)
//
// (Q_hi + H does not overflow a 64-bit int)
//
// = p_lo + 2^64 p_hi
const std::uint64_t u_lo = x.f & 0xFFFFFFFFu;
const std::uint64_t u_hi = x.f >> 32u;
const std::uint64_t v_lo = y.f & 0xFFFFFFFFu;
const std::uint64_t v_hi = y.f >> 32u;
const std::uint64_t p0 = u_lo * v_lo;
const std::uint64_t p1 = u_lo * v_hi;
const std::uint64_t p2 = u_hi * v_lo;
const std::uint64_t p3 = u_hi * v_hi;
const std::uint64_t p0_hi = p0 >> 32u;
const std::uint64_t p1_lo = p1 & 0xFFFFFFFFu;
const std::uint64_t p1_hi = p1 >> 32u;
const std::uint64_t p2_lo = p2 & 0xFFFFFFFFu;
const std::uint64_t p2_hi = p2 >> 32u;
std::uint64_t Q = p0_hi + p1_lo + p2_lo;
// The full product might now be computed as
//
// p_hi = p3 + p2_hi + p1_hi + (Q >> 32)
// p_lo = p0_lo + (Q << 32)
//
// But in this particular case here, the full p_lo is not required.
// Effectively we only need to add the highest bit in p_lo to p_hi (and
// Q_hi + 1 does not overflow).
Q += std::uint64_t{1} << (64u - 32u - 1u); // round, ties up
const std::uint64_t h = p3 + p2_hi + p1_hi + (Q >> 32u);
return {h, x.e + y.e + 64};
}
/*!
@brief normalize x such that the significand is >= 2^(q-1)
@pre x.f != 0
*/
static diyfp normalize(diyfp x) noexcept {
while ((x.f >> 63u) == 0) {
x.f <<= 1u;
x.e--;
}
return x;
}
/*!
@brief normalize x such that the result has the exponent E
@pre e >= x.e and the upper e - x.e bits of x.f must be zero.
*/
static diyfp normalize_to(const diyfp &x,
const int target_exponent) noexcept {
const int delta = x.e - target_exponent;
return {x.f << delta, target_exponent};
}
};
struct boundaries {
diyfp w;
diyfp minus;
diyfp plus;
};
/*!
Compute the (normalized) diyfp representing the input number 'value' and its
boundaries.
@pre value must be finite and positive
*/
template <typename FloatType> boundaries compute_boundaries(FloatType value) {
// Convert the IEEE representation into a diyfp.
//
// If v is denormal:
// value = 0.F * 2^(1 - bias) = ( F) * 2^(1 - bias - (p-1))
// If v is normalized:
// value = 1.F * 2^(E - bias) = (2^(p-1) + F) * 2^(E - bias - (p-1))
static_assert(std::numeric_limits<FloatType>::is_iec559,
"internal error: dtoa_short requires an IEEE-754 "
"floating-point implementation");
constexpr int kPrecision =
std::numeric_limits<FloatType>::digits; // = p (includes the hidden bit)
constexpr int kBias =
std::numeric_limits<FloatType>::max_exponent - 1 + (kPrecision - 1);
constexpr int kMinExp = 1 - kBias;
constexpr std::uint64_t kHiddenBit = std::uint64_t{1}
<< (kPrecision - 1); // = 2^(p-1)
using bits_type = typename std::conditional<kPrecision == 24, std::uint32_t,
std::uint64_t>::type;
const std::uint64_t bits = reinterpret_bits<bits_type>(value);
const std::uint64_t E = bits >> (kPrecision - 1);
const std::uint64_t F = bits & (kHiddenBit - 1);
const bool is_denormal = E == 0;
const diyfp v = is_denormal
? diyfp(F, kMinExp)
: diyfp(F + kHiddenBit, static_cast<int>(E) - kBias);
// Compute the boundaries m- and m+ of the floating-point value
// v = f * 2^e.
//
// Determine v- and v+, the floating-point predecessor and successor if v,
// respectively.
//
// v- = v - 2^e if f != 2^(p-1) or e == e_min (A)
// = v - 2^(e-1) if f == 2^(p-1) and e > e_min (B)
//
// v+ = v + 2^e
//
// Let m- = (v- + v) / 2 and m+ = (v + v+) / 2. All real numbers _strictly_
// between m- and m+ round to v, regardless of how the input rounding
// algorithm breaks ties.
//
// ---+-------------+-------------+-------------+-------------+--- (A)
// v- m- v m+ v+
//
// -----------------+------+------+-------------+-------------+--- (B)
// v- m- v m+ v+
const bool lower_boundary_is_closer = F == 0 && E > 1;
const diyfp m_plus = diyfp(2 * v.f + 1, v.e - 1);
const diyfp m_minus = lower_boundary_is_closer
? diyfp(4 * v.f - 1, v.e - 2) // (B)
: diyfp(2 * v.f - 1, v.e - 1); // (A)
// Determine the normalized w+ = m+.
const diyfp w_plus = diyfp::normalize(m_plus);
// Determine w- = m- such that e_(w-) = e_(w+).
const diyfp w_minus = diyfp::normalize_to(m_minus, w_plus.e);
return {diyfp::normalize(v), w_minus, w_plus};
}
// Given normalized diyfp w, Grisu needs to find a (normalized) cached
// power-of-ten c, such that the exponent of the product c * w = f * 2^e lies
// within a certain range [alpha, gamma] (Definition 3.2 from [1])
//
// alpha <= e = e_c + e_w + q <= gamma
//
// or
//
// f_c * f_w * 2^alpha <= f_c 2^(e_c) * f_w 2^(e_w) * 2^q
// <= f_c * f_w * 2^gamma
//
// Since c and w are normalized, i.e. 2^(q-1) <= f < 2^q, this implies
//
// 2^(q-1) * 2^(q-1) * 2^alpha <= c * w * 2^q < 2^q * 2^q * 2^gamma
//
// or
//
// 2^(q - 2 + alpha) <= c * w < 2^(q + gamma)
//
// The choice of (alpha,gamma) determines the size of the table and the form of
// the digit generation procedure. Using (alpha,gamma)=(-60,-32) works out well
// in practice:
//
// The idea is to cut the number c * w = f * 2^e into two parts, which can be
// processed independently: An integral part p1, and a fractional part p2:
//
// f * 2^e = ( (f div 2^-e) * 2^-e + (f mod 2^-e) ) * 2^e
// = (f div 2^-e) + (f mod 2^-e) * 2^e
// = p1 + p2 * 2^e
//
// The conversion of p1 into decimal form requires a series of divisions and
// modulos by (a power of) 10. These operations are faster for 32-bit than for
// 64-bit integers, so p1 should ideally fit into a 32-bit integer. This can be
// achieved by choosing
//
// -e >= 32 or e <= -32 := gamma
//
// In order to convert the fractional part
//
// p2 * 2^e = p2 / 2^-e = d[-1] / 10^1 + d[-2] / 10^2 + ...
//
// into decimal form, the fraction is repeatedly multiplied by 10 and the digits
// d[-i] are extracted in order:
//
// (10 * p2) div 2^-e = d[-1]
// (10 * p2) mod 2^-e = d[-2] / 10^1 + ...
//
// The multiplication by 10 must not overflow. It is sufficient to choose
//
// 10 * p2 < 16 * p2 = 2^4 * p2 <= 2^64.
//
// Since p2 = f mod 2^-e < 2^-e,
//
// -e <= 60 or e >= -60 := alpha
constexpr int kAlpha = -60;
constexpr int kGamma = -32;
struct cached_power // c = f * 2^e ~= 10^k
{
std::uint64_t f;
int e;
int k;
};
/*!
For a normalized diyfp w = f * 2^e, this function returns a (normalized) cached
power-of-ten c = f_c * 2^e_c, such that the exponent of the product w * c
satisfies (Definition 3.2 from [1])
alpha <= e_c + e + q <= gamma.
*/
inline cached_power get_cached_power_for_binary_exponent(int e) {
// Now
//
// alpha <= e_c + e + q <= gamma (1)
// ==> f_c * 2^alpha <= c * 2^e * 2^q
//
// and since the c's are normalized, 2^(q-1) <= f_c,
//
// ==> 2^(q - 1 + alpha) <= c * 2^(e + q)
// ==> 2^(alpha - e - 1) <= c
//
// If c were an exact power of ten, i.e. c = 10^k, one may determine k as
//
// k = ceil( log_10( 2^(alpha - e - 1) ) )
// = ceil( (alpha - e - 1) * log_10(2) )
//
// From the paper:
// "In theory the result of the procedure could be wrong since c is rounded,
// and the computation itself is approximated [...]. In practice, however,
// this simple function is sufficient."
//
// For IEEE double precision floating-point numbers converted into
// normalized diyfp's w = f * 2^e, with q = 64,
//
// e >= -1022 (min IEEE exponent)
// -52 (p - 1)
// -52 (p - 1, possibly normalize denormal IEEE numbers)
// -11 (normalize the diyfp)
// = -1137
//
// and
//
// e <= +1023 (max IEEE exponent)
// -52 (p - 1)
// -11 (normalize the diyfp)
// = 960
//
// This binary exponent range [-1137,960] results in a decimal exponent
// range [-307,324]. One does not need to store a cached power for each
// k in this range. For each such k it suffices to find a cached power
// such that the exponent of the product lies in [alpha,gamma].
// This implies that the difference of the decimal exponents of adjacent
// table entries must be less than or equal to
//
// floor( (gamma - alpha) * log_10(2) ) = 8.
//
// (A smaller distance gamma-alpha would require a larger table.)
// NB:
// Actually this function returns c, such that -60 <= e_c + e + 64 <= -34.
constexpr int kCachedPowersMinDecExp = -300;
constexpr int kCachedPowersDecStep = 8;
static constexpr std::array<cached_power, 79> kCachedPowers = {{
{0xAB70FE17C79AC6CA, -1060, -300}, {0xFF77B1FCBEBCDC4F, -1034, -292},
{0xBE5691EF416BD60C, -1007, -284}, {0x8DD01FAD907FFC3C, -980, -276},
{0xD3515C2831559A83, -954, -268}, {0x9D71AC8FADA6C9B5, -927, -260},
{0xEA9C227723EE8BCB, -901, -252}, {0xAECC49914078536D, -874, -244},
{0x823C12795DB6CE57, -847, -236}, {0xC21094364DFB5637, -821, -228},
{0x9096EA6F3848984F, -794, -220}, {0xD77485CB25823AC7, -768, -212},
{0xA086CFCD97BF97F4, -741, -204}, {0xEF340A98172AACE5, -715, -196},
{0xB23867FB2A35B28E, -688, -188}, {0x84C8D4DFD2C63F3B, -661, -180},
{0xC5DD44271AD3CDBA, -635, -172}, {0x936B9FCEBB25C996, -608, -164},
{0xDBAC6C247D62A584, -582, -156}, {0xA3AB66580D5FDAF6, -555, -148},
{0xF3E2F893DEC3F126, -529, -140}, {0xB5B5ADA8AAFF80B8, -502, -132},
{0x87625F056C7C4A8B, -475, -124}, {0xC9BCFF6034C13053, -449, -116},
{0x964E858C91BA2655, -422, -108}, {0xDFF9772470297EBD, -396, -100},
{0xA6DFBD9FB8E5B88F, -369, -92}, {0xF8A95FCF88747D94, -343, -84},
{0xB94470938FA89BCF, -316, -76}, {0x8A08F0F8BF0F156B, -289, -68},
{0xCDB02555653131B6, -263, -60}, {0x993FE2C6D07B7FAC, -236, -52},
{0xE45C10C42A2B3B06, -210, -44}, {0xAA242499697392D3, -183, -36},
{0xFD87B5F28300CA0E, -157, -28}, {0xBCE5086492111AEB, -130, -20},
{0x8CBCCC096F5088CC, -103, -12}, {0xD1B71758E219652C, -77, -4},
{0x9C40000000000000, -50, 4}, {0xE8D4A51000000000, -24, 12},
{0xAD78EBC5AC620000, 3, 20}, {0x813F3978F8940984, 30, 28},
{0xC097CE7BC90715B3, 56, 36}, {0x8F7E32CE7BEA5C70, 83, 44},
{0xD5D238A4ABE98068, 109, 52}, {0x9F4F2726179A2245, 136, 60},
{0xED63A231D4C4FB27, 162, 68}, {0xB0DE65388CC8ADA8, 189, 76},
{0x83C7088E1AAB65DB, 216, 84}, {0xC45D1DF942711D9A, 242, 92},
{0x924D692CA61BE758, 269, 100}, {0xDA01EE641A708DEA, 295, 108},
{0xA26DA3999AEF774A, 322, 116}, {0xF209787BB47D6B85, 348, 124},
{0xB454E4A179DD1877, 375, 132}, {0x865B86925B9BC5C2, 402, 140},
{0xC83553C5C8965D3D, 428, 148}, {0x952AB45CFA97A0B3, 455, 156},
{0xDE469FBD99A05FE3, 481, 164}, {0xA59BC234DB398C25, 508, 172},
{0xF6C69A72A3989F5C, 534, 180}, {0xB7DCBF5354E9BECE, 561, 188},
{0x88FCF317F22241E2, 588, 196}, {0xCC20CE9BD35C78A5, 614, 204},
{0x98165AF37B2153DF, 641, 212}, {0xE2A0B5DC971F303A, 667, 220},
{0xA8D9D1535CE3B396, 694, 228}, {0xFB9B7CD9A4A7443C, 720, 236},
{0xBB764C4CA7A44410, 747, 244}, {0x8BAB8EEFB6409C1A, 774, 252},
{0xD01FEF10A657842C, 800, 260}, {0x9B10A4E5E9913129, 827, 268},
{0xE7109BFBA19C0C9D, 853, 276}, {0xAC2820D9623BF429, 880, 284},
{0x80444B5E7AA7CF85, 907, 292}, {0xBF21E44003ACDD2D, 933, 300},
{0x8E679C2F5E44FF8F, 960, 308}, {0xD433179D9C8CB841, 986, 316},
{0x9E19DB92B4E31BA9, 1013, 324},
}};
// This computation gives exactly the same results for k as
// k = ceil((kAlpha - e - 1) * 0.30102999566398114)
// for |e| <= 1500, but doesn't require floating-point operations.
// NB: log_10(2) ~= 78913 / 2^18
const int f = kAlpha - e - 1;
const int k = (f * 78913) / (1 << 18) + static_cast<int>(f > 0);
const int index = (-kCachedPowersMinDecExp + k + (kCachedPowersDecStep - 1)) /
kCachedPowersDecStep;
const cached_power cached = kCachedPowers[static_cast<std::size_t>(index)];
return cached;
}
/*!
For n != 0, returns k, such that pow10 := 10^(k-1) <= n < 10^k.
For n == 0, returns 1 and sets pow10 := 1.
*/
inline int find_largest_pow10(const std::uint32_t n, std::uint32_t &pow10) {
// LCOV_EXCL_START
if (n >= 1000000000) {
pow10 = 1000000000;
return 10;
}
// LCOV_EXCL_STOP
else if (n >= 100000000) {
pow10 = 100000000;
return 9;
} else if (n >= 10000000) {
pow10 = 10000000;
return 8;
} else if (n >= 1000000) {
pow10 = 1000000;
return 7;
} else if (n >= 100000) {
pow10 = 100000;
return 6;
} else if (n >= 10000) {
pow10 = 10000;
return 5;
} else if (n >= 1000) {
pow10 = 1000;
return 4;
} else if (n >= 100) {
pow10 = 100;
return 3;
} else if (n >= 10) {
pow10 = 10;
return 2;
} else {
pow10 = 1;
return 1;
}
}
inline void grisu2_round(char *buf, int len, std::uint64_t dist,
std::uint64_t delta, std::uint64_t rest,
std::uint64_t ten_k) {
// <--------------------------- delta ---->
// <---- dist --------->
// --------------[------------------+-------------------]--------------
// M- w M+
//
// ten_k
// <------>
// <---- rest ---->
// --------------[------------------+----+--------------]--------------
// w V
// = buf * 10^k
//
// ten_k represents a unit-in-the-last-place in the decimal representation
// stored in buf.
// Decrement buf by ten_k while this takes buf closer to w.
// The tests are written in this order to avoid overflow in unsigned
// integer arithmetic.
while (rest < dist && delta - rest >= ten_k &&
(rest + ten_k < dist || dist - rest > rest + ten_k - dist)) {
buf[len - 1]--;
rest += ten_k;
}
}
/*!
Generates V = buffer * 10^decimal_exponent, such that M- <= V <= M+.
M- and M+ must be normalized and share the same exponent -60 <= e <= -32.
*/
inline void grisu2_digit_gen(char *buffer, int &length, int &decimal_exponent,
diyfp M_minus, diyfp w, diyfp M_plus) {
static_assert(kAlpha >= -60, "internal error");
static_assert(kGamma <= -32, "internal error");
// Generates the digits (and the exponent) of a decimal floating-point
// number V = buffer * 10^decimal_exponent in the range [M-, M+]. The diyfp's
// w, M- and M+ share the same exponent e, which satisfies alpha <= e <=
// gamma.
//
// <--------------------------- delta ---->
// <---- dist --------->
// --------------[------------------+-------------------]--------------
// M- w M+
//
// Grisu2 generates the digits of M+ from left to right and stops as soon as
// V is in [M-,M+].
std::uint64_t delta =
diyfp::sub(M_plus, M_minus)
.f; // (significand of (M+ - M-), implicit exponent is e)
std::uint64_t dist =
diyfp::sub(M_plus, w)
.f; // (significand of (M+ - w ), implicit exponent is e)
// Split M+ = f * 2^e into two parts p1 and p2 (note: e < 0):
//
// M+ = f * 2^e
// = ((f div 2^-e) * 2^-e + (f mod 2^-e)) * 2^e
// = ((p1 ) * 2^-e + (p2 )) * 2^e
// = p1 + p2 * 2^e
const diyfp one(std::uint64_t{1} << -M_plus.e, M_plus.e);
auto p1 = static_cast<std::uint32_t>(
M_plus.f >>
-one.e); // p1 = f div 2^-e (Since -e >= 32, p1 fits into a 32-bit int.)
std::uint64_t p2 = M_plus.f & (one.f - 1); // p2 = f mod 2^-e
// 1)
//
// Generate the digits of the integral part p1 = d[n-1]...d[1]d[0]
std::uint32_t pow10;
const int k = find_largest_pow10(p1, pow10);
// 10^(k-1) <= p1 < 10^k, pow10 = 10^(k-1)
//
// p1 = (p1 div 10^(k-1)) * 10^(k-1) + (p1 mod 10^(k-1))
// = (d[k-1] ) * 10^(k-1) + (p1 mod 10^(k-1))
//
// M+ = p1 + p2 * 2^e
// = d[k-1] * 10^(k-1) + (p1 mod 10^(k-1)) + p2 * 2^e
// = d[k-1] * 10^(k-1) + ((p1 mod 10^(k-1)) * 2^-e + p2) * 2^e
// = d[k-1] * 10^(k-1) + ( rest) * 2^e
//
// Now generate the digits d[n] of p1 from left to right (n = k-1,...,0)
//
// p1 = d[k-1]...d[n] * 10^n + d[n-1]...d[0]
//
// but stop as soon as
//
// rest * 2^e = (d[n-1]...d[0] * 2^-e + p2) * 2^e <= delta * 2^e
int n = k;
while (n > 0) {
// Invariants:
// M+ = buffer * 10^n + (p1 + p2 * 2^e) (buffer = 0 for n = k)
// pow10 = 10^(n-1) <= p1 < 10^n
//
const std::uint32_t d = p1 / pow10; // d = p1 div 10^(n-1)
const std::uint32_t r = p1 % pow10; // r = p1 mod 10^(n-1)
//
// M+ = buffer * 10^n + (d * 10^(n-1) + r) + p2 * 2^e
// = (buffer * 10 + d) * 10^(n-1) + (r + p2 * 2^e)
//
buffer[length++] = static_cast<char>('0' + d); // buffer := buffer * 10 + d
//
// M+ = buffer * 10^(n-1) + (r + p2 * 2^e)
//
p1 = r;
n--;
//
// M+ = buffer * 10^n + (p1 + p2 * 2^e)
// pow10 = 10^n
//
// Now check if enough digits have been generated.
// Compute
//
// p1 + p2 * 2^e = (p1 * 2^-e + p2) * 2^e = rest * 2^e
//
// Note:
// Since rest and delta share the same exponent e, it suffices to
// compare the significands.
const std::uint64_t rest = (std::uint64_t{p1} << -one.e) + p2;
if (rest <= delta) {
// V = buffer * 10^n, with M- <= V <= M+.
decimal_exponent += n;
// We may now just stop. But instead look if the buffer could be
// decremented to bring V closer to w.
//
// pow10 = 10^n is now 1 ulp in the decimal representation V.
// The rounding procedure works with diyfp's with an implicit
// exponent of e.
//
// 10^n = (10^n * 2^-e) * 2^e = ulp * 2^e
//
const std::uint64_t ten_n = std::uint64_t{pow10} << -one.e;
grisu2_round(buffer, length, dist, delta, rest, ten_n);
return;
}
pow10 /= 10;
//
// pow10 = 10^(n-1) <= p1 < 10^n
// Invariants restored.
}
// 2)
//
// The digits of the integral part have been generated:
//
// M+ = d[k-1]...d[1]d[0] + p2 * 2^e
// = buffer + p2 * 2^e
//
// Now generate the digits of the fractional part p2 * 2^e.
//
// Note:
// No decimal point is generated: the exponent is adjusted instead.
//
// p2 actually represents the fraction
//
// p2 * 2^e
// = p2 / 2^-e
// = d[-1] / 10^1 + d[-2] / 10^2 + ...
//
// Now generate the digits d[-m] of p1 from left to right (m = 1,2,...)
//
// p2 * 2^e = d[-1]d[-2]...d[-m] * 10^-m
// + 10^-m * (d[-m-1] / 10^1 + d[-m-2] / 10^2 + ...)
//
// using
//
// 10^m * p2 = ((10^m * p2) div 2^-e) * 2^-e + ((10^m * p2) mod 2^-e)
// = ( d) * 2^-e + ( r)
//
// or
// 10^m * p2 * 2^e = d + r * 2^e
//
// i.e.
//
// M+ = buffer + p2 * 2^e
// = buffer + 10^-m * (d + r * 2^e)
// = (buffer * 10^m + d) * 10^-m + 10^-m * r * 2^e
//
// and stop as soon as 10^-m * r * 2^e <= delta * 2^e
int m = 0;
for (;;) {
// Invariant:
// M+ = buffer * 10^-m + 10^-m * (d[-m-1] / 10 + d[-m-2] / 10^2 + ...)
// * 2^e
// = buffer * 10^-m + 10^-m * (p2 )
// * 2^e = buffer * 10^-m + 10^-m * (1/10 * (10 * p2) ) * 2^e =
// buffer * 10^-m + 10^-m * (1/10 * ((10*p2 div 2^-e) * 2^-e +
// (10*p2 mod 2^-e)) * 2^e
//
p2 *= 10;
const std::uint64_t d = p2 >> -one.e; // d = (10 * p2) div 2^-e
const std::uint64_t r = p2 & (one.f - 1); // r = (10 * p2) mod 2^-e
//
// M+ = buffer * 10^-m + 10^-m * (1/10 * (d * 2^-e + r) * 2^e
// = buffer * 10^-m + 10^-m * (1/10 * (d + r * 2^e))
// = (buffer * 10 + d) * 10^(-m-1) + 10^(-m-1) * r * 2^e
//
buffer[length++] = static_cast<char>('0' + d); // buffer := buffer * 10 + d
//
// M+ = buffer * 10^(-m-1) + 10^(-m-1) * r * 2^e
//
p2 = r;
m++;
//
// M+ = buffer * 10^-m + 10^-m * p2 * 2^e
// Invariant restored.
// Check if enough digits have been generated.
//
// 10^-m * p2 * 2^e <= delta * 2^e
// p2 * 2^e <= 10^m * delta * 2^e
// p2 <= 10^m * delta
delta *= 10;
dist *= 10;
if (p2 <= delta) {
break;
}
}
// V = buffer * 10^-m, with M- <= V <= M+.
decimal_exponent -= m;
// 1 ulp in the decimal representation is now 10^-m.
// Since delta and dist are now scaled by 10^m, we need to do the
// same with ulp in order to keep the units in sync.
//
// 10^m * 10^-m = 1 = 2^-e * 2^e = ten_m * 2^e
//
const std::uint64_t ten_m = one.f;
grisu2_round(buffer, length, dist, delta, p2, ten_m);
// By construction this algorithm generates the shortest possible decimal
// number (Loitsch, Theorem 6.2) which rounds back to w.
// For an input number of precision p, at least
//
// N = 1 + ceil(p * log_10(2))
//
// decimal digits are sufficient to identify all binary floating-point
// numbers (Matula, "In-and-Out conversions").
// This implies that the algorithm does not produce more than N decimal
// digits.
//
// N = 17 for p = 53 (IEEE double precision)
// N = 9 for p = 24 (IEEE single precision)
}
/*!
v = buf * 10^decimal_exponent
len is the length of the buffer (number of decimal digits)
The buffer must be large enough, i.e. >= max_digits10.
*/
inline void grisu2(char *buf, int &len, int &decimal_exponent, diyfp m_minus,
diyfp v, diyfp m_plus) {
// --------(-----------------------+-----------------------)-------- (A)
// m- v m+
//
// --------------------(-----------+-----------------------)-------- (B)
// m- v m+
//
// First scale v (and m- and m+) such that the exponent is in the range
// [alpha, gamma].
const cached_power cached = get_cached_power_for_binary_exponent(m_plus.e);
const diyfp c_minus_k(cached.f, cached.e); // = c ~= 10^-k
// The exponent of the products is = v.e + c_minus_k.e + q and is in the range
// [alpha,gamma]
const diyfp w = diyfp::mul(v, c_minus_k);
const diyfp w_minus = diyfp::mul(m_minus, c_minus_k);
const diyfp w_plus = diyfp::mul(m_plus, c_minus_k);
// ----(---+---)---------------(---+---)---------------(---+---)----
// w- w w+
// = c*m- = c*v = c*m+
//
// diyfp::mul rounds its result and c_minus_k is approximated too. w, w- and
// w+ are now off by a small amount.
// In fact:
//
// w - v * 10^k < 1 ulp
//
// To account for this inaccuracy, add resp. subtract 1 ulp.
//
// --------+---[---------------(---+---)---------------]---+--------
// w- M- w M+ w+
//
// Now any number in [M-, M+] (bounds included) will round to w when input,
// regardless of how the input rounding algorithm breaks ties.
//
// And digit_gen generates the shortest possible such number in [M-, M+].
// Note that this does not mean that Grisu2 always generates the shortest
// possible number in the interval (m-, m+).
const diyfp M_minus(w_minus.f + 1, w_minus.e);
const diyfp M_plus(w_plus.f - 1, w_plus.e);
decimal_exponent = -cached.k; // = -(-k) = k
grisu2_digit_gen(buf, len, decimal_exponent, M_minus, w, M_plus);
}
/*!
v = buf * 10^decimal_exponent
len is the length of the buffer (number of decimal digits)
The buffer must be large enough, i.e. >= max_digits10.
*/
template <typename FloatType>
void grisu2(char *buf, int &len, int &decimal_exponent, FloatType value) {
static_assert(diyfp::kPrecision >= std::numeric_limits<FloatType>::digits + 3,
"internal error: not enough precision");
// If the neighbors (and boundaries) of 'value' are always computed for
// double-precision numbers, all float's can be recovered using strtod (and
// strtof). However, the resulting decimal representations are not exactly
// "short".
//
// The documentation for 'std::to_chars'
// (https://en.cppreference.com/w/cpp/utility/to_chars) says "value is
// converted to a string as if by std::sprintf in the default ("C") locale"
// and since sprintf promotes float's to double's, I think this is exactly
// what 'std::to_chars' does. On the other hand, the documentation for
// 'std::to_chars' requires that "parsing the representation using the
// corresponding std::from_chars function recovers value exactly". That
// indicates that single precision floating-point numbers should be recovered
// using 'std::strtof'.
//
// NB: If the neighbors are computed for single-precision numbers, there is a
// single float
// (7.0385307e-26f) which can't be recovered using strtod. The resulting
// double precision value is off by 1 ulp.
#if 0
const boundaries w = compute_boundaries(static_cast<double>(value));
#else
const boundaries w = compute_boundaries(value);
#endif
grisu2(buf, len, decimal_exponent, w.minus, w.w, w.plus);
}
/*!
@brief appends a decimal representation of e to buf
@return a pointer to the element following the exponent.
@pre -1000 < e < 1000
*/
inline char *append_exponent(char *buf, int e) {
if (e < 0) {
e = -e;
*buf++ = '-';
} else {
*buf++ = '+';
}
auto k = static_cast<std::uint32_t>(e);
if (k < 10) {
// Always print at least two digits in the exponent.
// This is for compatibility with printf("%g").
*buf++ = '0';
*buf++ = static_cast<char>('0' + k);
} else if (k < 100) {
*buf++ = static_cast<char>('0' + k / 10);
k %= 10;
*buf++ = static_cast<char>('0' + k);
} else {
*buf++ = static_cast<char>('0' + k / 100);
k %= 100;
*buf++ = static_cast<char>('0' + k / 10);
k %= 10;
*buf++ = static_cast<char>('0' + k);
}
return buf;
}
/*!
@brief prettify v = buf * 10^decimal_exponent
If v is in the range [10^min_exp, 10^max_exp) it will be printed in fixed-point
notation. Otherwise it will be printed in exponential notation.
@pre min_exp < 0
@pre max_exp > 0
*/
inline char *format_buffer(char *buf, int len, int decimal_exponent,
int min_exp, int max_exp) {
const int k = len;
const int n = len + decimal_exponent;
// v = buf * 10^(n-k)
// k is the length of the buffer (number of decimal digits)
// n is the position of the decimal point relative to the start of the buffer.
if (k <= n && n <= max_exp) {
// digits[000]
// len <= max_exp + 2
std::memset(buf + k, '0', static_cast<size_t>(n) - static_cast<size_t>(k));
// Make it look like a floating-point number (#362, #378)
buf[n + 0] = '.';
buf[n + 1] = '0';
return buf + (static_cast<size_t>(n) + 2);
}
if (0 < n && n <= max_exp) {
// dig.its
// len <= max_digits10 + 1
std::memmove(buf + (static_cast<size_t>(n) + 1), buf + n,
static_cast<size_t>(k) - static_cast<size_t>(n));
buf[n] = '.';
return buf + (static_cast<size_t>(k) + 1U);
}
if (min_exp < n && n <= 0) {
// 0.[000]digits
// len <= 2 + (-min_exp - 1) + max_digits10
std::memmove(buf + (2 + static_cast<size_t>(-n)), buf,
static_cast<size_t>(k));
buf[0] = '0';
buf[1] = '.';
std::memset(buf + 2, '0', static_cast<size_t>(-n));
return buf + (2U + static_cast<size_t>(-n) + static_cast<size_t>(k));
}
if (k == 1) {
// dE+123
// len <= 1 + 5
buf += 1;
} else {
// d.igitsE+123
// len <= max_digits10 + 1 + 5
std::memmove(buf + 2, buf + 1, static_cast<size_t>(k) - 1);
buf[1] = '.';
buf += 1 + static_cast<size_t>(k);
}
*buf++ = 'e';
return append_exponent(buf, n - 1);
}
} // namespace dtoa_impl
/*!
The format of the resulting decimal representation is similar to printf's %g
format. Returns an iterator pointing past-the-end of the decimal representation.
@note The input number must be finite, i.e. NaN's and Inf's are not supported.
@note The buffer must be large enough.
@note The result is NOT null-terminated.
*/
char *to_chars(char *first, const char *last, double value) {
static_cast<void>(last); // maybe unused - fix warning
if (value <= -0) {
value = -value;
*first++ = '-';
}
if (value == 0) // +-0
{
*first++ = '0';
// Make it look like a floating-point number (#362, #378)
*first++ = '.';
*first++ = '0';
return first;
}
// Compute v = buffer * 10^decimal_exponent.
// The decimal digits are stored in the buffer, which needs to be interpreted
// as an unsigned decimal integer.
// len is the length of the buffer, i.e. the number of decimal digits.
int len = 0;
int decimal_exponent = 0;
dtoa_impl::grisu2(first, len, decimal_exponent, value);
// Format the buffer like printf("%.*g", prec, value)
constexpr int kMinExp = -4;
constexpr int kMaxExp = std::numeric_limits<double>::digits10;
return dtoa_impl::format_buffer(first, len, decimal_exponent, kMinExp,
kMaxExp);
}
} // namespace internal
} // namespace simdjson
/* end file src/to_chars.cpp */
/* begin file src/from_chars.cpp */
#include <limits>
namespace simdjson {
namespace internal {
/**
* The code in the internal::from_chars function is meant to handle the floating-point number parsing
* when we have more than 19 digits in the decimal mantissa. This should only be seen
* in adversarial scenarios: we do not expect production systems to even produce
* such floating-point numbers.
*
* The parser is based on work by Nigel Tao (at https://github.com/google/wuffs/)
* who credits Ken Thompson for the design (via a reference to the Go source
* code). See
* https://github.com/google/wuffs/blob/aa46859ea40c72516deffa1b146121952d6dfd3b/internal/cgen/base/floatconv-submodule-data.c
* https://github.com/google/wuffs/blob/46cd8105f47ca07ae2ba8e6a7818ef9c0df6c152/internal/cgen/base/floatconv-submodule-code.c
* It is probably not very fast but it is a fallback that should almost never be
* called in real life. Google Wuffs is published under APL 2.0.
**/
namespace {
constexpr uint32_t max_digits = 768;
constexpr int32_t decimal_point_range = 2047;
} // namespace
struct adjusted_mantissa {
uint64_t mantissa;
int power2;
adjusted_mantissa() : mantissa(0), power2(0) {}
};
struct decimal {
uint32_t num_digits;
int32_t decimal_point;
bool negative;
bool truncated;
uint8_t digits[max_digits];
};
template <typename T> struct binary_format {
static constexpr int mantissa_explicit_bits();
static constexpr int minimum_exponent();
static constexpr int infinite_power();
static constexpr int sign_index();
};
template <> constexpr int binary_format<double>::mantissa_explicit_bits() {
return 52;
}
template <> constexpr int binary_format<double>::minimum_exponent() {
return -1023;
}
template <> constexpr int binary_format<double>::infinite_power() {
return 0x7FF;
}
template <> constexpr int binary_format<double>::sign_index() { return 63; }
bool is_integer(char c) noexcept { return (c >= '0' && c <= '9'); }
// This should always succeed since it follows a call to parse_number.
decimal parse_decimal(const char *&p) noexcept {
decimal answer;
answer.num_digits = 0;
answer.decimal_point = 0;
answer.truncated = false;
answer.negative = (*p == '-');
if ((*p == '-') || (*p == '+')) {
++p;
}
while (*p == '0') {
++p;
}
while (is_integer(*p)) {
if (answer.num_digits < max_digits) {
answer.digits[answer.num_digits] = uint8_t(*p - '0');
}
answer.num_digits++;
++p;
}
if (*p == '.') {
++p;
const char *first_after_period = p;
// if we have not yet encountered a zero, we have to skip it as well
if (answer.num_digits == 0) {
// skip zeros
while (*p == '0') {
++p;
}
}
while (is_integer(*p)) {
if (answer.num_digits < max_digits) {
answer.digits[answer.num_digits] = uint8_t(*p - '0');
}
answer.num_digits++;
++p;
}
answer.decimal_point = int32_t(first_after_period - p);
}
if(answer.num_digits > 0) {
const char *preverse = p - 1;
int32_t trailing_zeros = 0;
while ((*preverse == '0') || (*preverse == '.')) {
if(*preverse == '0') { trailing_zeros++; };
--preverse;
}
answer.decimal_point += int32_t(answer.num_digits);
answer.num_digits -= uint32_t(trailing_zeros);
}
if(answer.num_digits > max_digits ) {
answer.num_digits = max_digits;
answer.truncated = true;
}
if (('e' == *p) || ('E' == *p)) {
++p;
bool neg_exp = false;
if ('-' == *p) {
neg_exp = true;
++p;
} else if ('+' == *p) {
++p;
}
int32_t exp_number = 0; // exponential part
while (is_integer(*p)) {
uint8_t digit = uint8_t(*p - '0');
if (exp_number < 0x10000) {
exp_number = 10 * exp_number + digit;
}
++p;
}
answer.decimal_point += (neg_exp ? -exp_number : exp_number);
}
return answer;
}
namespace {
// remove all final zeroes
inline void trim(decimal &h) {
while ((h.num_digits > 0) && (h.digits[h.num_digits - 1] == 0)) {
h.num_digits--;
}
}
uint32_t number_of_digits_decimal_left_shift(decimal &h, uint32_t shift) {
shift &= 63;
const static uint16_t number_of_digits_decimal_left_shift_table[65] = {
0x0000, 0x0800, 0x0801, 0x0803, 0x1006, 0x1009, 0x100D, 0x1812, 0x1817,
0x181D, 0x2024, 0x202B, 0x2033, 0x203C, 0x2846, 0x2850, 0x285B, 0x3067,
0x3073, 0x3080, 0x388E, 0x389C, 0x38AB, 0x38BB, 0x40CC, 0x40DD, 0x40EF,
0x4902, 0x4915, 0x4929, 0x513E, 0x5153, 0x5169, 0x5180, 0x5998, 0x59B0,
0x59C9, 0x61E3, 0x61FD, 0x6218, 0x6A34, 0x6A50, 0x6A6D, 0x6A8B, 0x72AA,
0x72C9, 0x72E9, 0x7B0A, 0x7B2B, 0x7B4D, 0x8370, 0x8393, 0x83B7, 0x83DC,
0x8C02, 0x8C28, 0x8C4F, 0x9477, 0x949F, 0x94C8, 0x9CF2, 0x051C, 0x051C,
0x051C, 0x051C,
};
uint32_t x_a = number_of_digits_decimal_left_shift_table[shift];
uint32_t x_b = number_of_digits_decimal_left_shift_table[shift + 1];
uint32_t num_new_digits = x_a >> 11;
uint32_t pow5_a = 0x7FF & x_a;
uint32_t pow5_b = 0x7FF & x_b;
const static uint8_t
number_of_digits_decimal_left_shift_table_powers_of_5[0x051C] = {
5, 2, 5, 1, 2, 5, 6, 2, 5, 3, 1, 2, 5, 1, 5, 6, 2, 5, 7, 8, 1, 2, 5,
3, 9, 0, 6, 2, 5, 1, 9, 5, 3, 1, 2, 5, 9, 7, 6, 5, 6, 2, 5, 4, 8, 8,
2, 8, 1, 2, 5, 2, 4, 4, 1, 4, 0, 6, 2, 5, 1, 2, 2, 0, 7, 0, 3, 1, 2,
5, 6, 1, 0, 3, 5, 1, 5, 6, 2, 5, 3, 0, 5, 1, 7, 5, 7, 8, 1, 2, 5, 1,
5, 2, 5, 8, 7, 8, 9, 0, 6, 2, 5, 7, 6, 2, 9, 3, 9, 4, 5, 3, 1, 2, 5,
3, 8, 1, 4, 6, 9, 7, 2, 6, 5, 6, 2, 5, 1, 9, 0, 7, 3, 4, 8, 6, 3, 2,
8, 1, 2, 5, 9, 5, 3, 6, 7, 4, 3, 1, 6, 4, 0, 6, 2, 5, 4, 7, 6, 8, 3,
7, 1, 5, 8, 2, 0, 3, 1, 2, 5, 2, 3, 8, 4, 1, 8, 5, 7, 9, 1, 0, 1, 5,
6, 2, 5, 1, 1, 9, 2, 0, 9, 2, 8, 9, 5, 5, 0, 7, 8, 1, 2, 5, 5, 9, 6,
0, 4, 6, 4, 4, 7, 7, 5, 3, 9, 0, 6, 2, 5, 2, 9, 8, 0, 2, 3, 2, 2, 3,
8, 7, 6, 9, 5, 3, 1, 2, 5, 1, 4, 9, 0, 1, 1, 6, 1, 1, 9, 3, 8, 4, 7,
6, 5, 6, 2, 5, 7, 4, 5, 0, 5, 8, 0, 5, 9, 6, 9, 2, 3, 8, 2, 8, 1, 2,
5, 3, 7, 2, 5, 2, 9, 0, 2, 9, 8, 4, 6, 1, 9, 1, 4, 0, 6, 2, 5, 1, 8,
6, 2, 6, 4, 5, 1, 4, 9, 2, 3, 0, 9, 5, 7, 0, 3, 1, 2, 5, 9, 3, 1, 3,
2, 2, 5, 7, 4, 6, 1, 5, 4, 7, 8, 5, 1, 5, 6, 2, 5, 4, 6, 5, 6, 6, 1,
2, 8, 7, 3, 0, 7, 7, 3, 9, 2, 5, 7, 8, 1, 2, 5, 2, 3, 2, 8, 3, 0, 6,
4, 3, 6, 5, 3, 8, 6, 9, 6, 2, 8, 9, 0, 6, 2, 5, 1, 1, 6, 4, 1, 5, 3,
2, 1, 8, 2, 6, 9, 3, 4, 8, 1, 4, 4, 5, 3, 1, 2, 5, 5, 8, 2, 0, 7, 6,
6, 0, 9, 1, 3, 4, 6, 7, 4, 0, 7, 2, 2, 6, 5, 6, 2, 5, 2, 9, 1, 0, 3,
8, 3, 0, 4, 5, 6, 7, 3, 3, 7, 0, 3, 6, 1, 3, 2, 8, 1, 2, 5, 1, 4, 5,
5, 1, 9, 1, 5, 2, 2, 8, 3, 6, 6, 8, 5, 1, 8, 0, 6, 6, 4, 0, 6, 2, 5,
7, 2, 7, 5, 9, 5, 7, 6, 1, 4, 1, 8, 3, 4, 2, 5, 9, 0, 3, 3, 2, 0, 3,
1, 2, 5, 3, 6, 3, 7, 9, 7, 8, 8, 0, 7, 0, 9, 1, 7, 1, 2, 9, 5, 1, 6,
6, 0, 1, 5, 6, 2, 5, 1, 8, 1, 8, 9, 8, 9, 4, 0, 3, 5, 4, 5, 8, 5, 6,
4, 7, 5, 8, 3, 0, 0, 7, 8, 1, 2, 5, 9, 0, 9, 4, 9, 4, 7, 0, 1, 7, 7,
2, 9, 2, 8, 2, 3, 7, 9, 1, 5, 0, 3, 9, 0, 6, 2, 5, 4, 5, 4, 7, 4, 7,
3, 5, 0, 8, 8, 6, 4, 6, 4, 1, 1, 8, 9, 5, 7, 5, 1, 9, 5, 3, 1, 2, 5,
2, 2, 7, 3, 7, 3, 6, 7, 5, 4, 4, 3, 2, 3, 2, 0, 5, 9, 4, 7, 8, 7, 5,
9, 7, 6, 5, 6, 2, 5, 1, 1, 3, 6, 8, 6, 8, 3, 7, 7, 2, 1, 6, 1, 6, 0,
2, 9, 7, 3, 9, 3, 7, 9, 8, 8, 2, 8, 1, 2, 5, 5, 6, 8, 4, 3, 4, 1, 8,
8, 6, 0, 8, 0, 8, 0, 1, 4, 8, 6, 9, 6, 8, 9, 9, 4, 1, 4, 0, 6, 2, 5,
2, 8, 4, 2, 1, 7, 0, 9, 4, 3, 0, 4, 0, 4, 0, 0, 7, 4, 3, 4, 8, 4, 4,
9, 7, 0, 7, 0, 3, 1, 2, 5, 1, 4, 2, 1, 0, 8, 5, 4, 7, 1, 5, 2, 0, 2,
0, 0, 3, 7, 1, 7, 4, 2, 2, 4, 8, 5, 3, 5, 1, 5, 6, 2, 5, 7, 1, 0, 5,
4, 2, 7, 3, 5, 7, 6, 0, 1, 0, 0, 1, 8, 5, 8, 7, 1, 1, 2, 4, 2, 6, 7,
5, 7, 8, 1, 2, 5, 3, 5, 5, 2, 7, 1, 3, 6, 7, 8, 8, 0, 0, 5, 0, 0, 9,
2, 9, 3, 5, 5, 6, 2, 1, 3, 3, 7, 8, 9, 0, 6, 2, 5, 1, 7, 7, 6, 3, 5,
6, 8, 3, 9, 4, 0, 0, 2, 5, 0, 4, 6, 4, 6, 7, 7, 8, 1, 0, 6, 6, 8, 9,
4, 5, 3, 1, 2, 5, 8, 8, 8, 1, 7, 8, 4, 1, 9, 7, 0, 0, 1, 2, 5, 2, 3,
2, 3, 3, 8, 9, 0, 5, 3, 3, 4, 4, 7, 2, 6, 5, 6, 2, 5, 4, 4, 4, 0, 8,
9, 2, 0, 9, 8, 5, 0, 0, 6, 2, 6, 1, 6, 1, 6, 9, 4, 5, 2, 6, 6, 7, 2,
3, 6, 3, 2, 8, 1, 2, 5, 2, 2, 2, 0, 4, 4, 6, 0, 4, 9, 2, 5, 0, 3, 1,
3, 0, 8, 0, 8, 4, 7, 2, 6, 3, 3, 3, 6, 1, 8, 1, 6, 4, 0, 6, 2, 5, 1,
1, 1, 0, 2, 2, 3, 0, 2, 4, 6, 2, 5, 1, 5, 6, 5, 4, 0, 4, 2, 3, 6, 3,
1, 6, 6, 8, 0, 9, 0, 8, 2, 0, 3, 1, 2, 5, 5, 5, 5, 1, 1, 1, 5, 1, 2,
3, 1, 2, 5, 7, 8, 2, 7, 0, 2, 1, 1, 8, 1, 5, 8, 3, 4, 0, 4, 5, 4, 1,
0, 1, 5, 6, 2, 5, 2, 7, 7, 5, 5, 5, 7, 5, 6, 1, 5, 6, 2, 8, 9, 1, 3,
5, 1, 0, 5, 9, 0, 7, 9, 1, 7, 0, 2, 2, 7, 0, 5, 0, 7, 8, 1, 2, 5, 1,
3, 8, 7, 7, 7, 8, 7, 8, 0, 7, 8, 1, 4, 4, 5, 6, 7, 5, 5, 2, 9, 5, 3,
9, 5, 8, 5, 1, 1, 3, 5, 2, 5, 3, 9, 0, 6, 2, 5, 6, 9, 3, 8, 8, 9, 3,
9, 0, 3, 9, 0, 7, 2, 2, 8, 3, 7, 7, 6, 4, 7, 6, 9, 7, 9, 2, 5, 5, 6,
7, 6, 2, 6, 9, 5, 3, 1, 2, 5, 3, 4, 6, 9, 4, 4, 6, 9, 5, 1, 9, 5, 3,
6, 1, 4, 1, 8, 8, 8, 2, 3, 8, 4, 8, 9, 6, 2, 7, 8, 3, 8, 1, 3, 4, 7,
6, 5, 6, 2, 5, 1, 7, 3, 4, 7, 2, 3, 4, 7, 5, 9, 7, 6, 8, 0, 7, 0, 9,
4, 4, 1, 1, 9, 2, 4, 4, 8, 1, 3, 9, 1, 9, 0, 6, 7, 3, 8, 2, 8, 1, 2,
5, 8, 6, 7, 3, 6, 1, 7, 3, 7, 9, 8, 8, 4, 0, 3, 5, 4, 7, 2, 0, 5, 9,
6, 2, 2, 4, 0, 6, 9, 5, 9, 5, 3, 3, 6, 9, 1, 4, 0, 6, 2, 5,
};
const uint8_t *pow5 =
&number_of_digits_decimal_left_shift_table_powers_of_5[pow5_a];
uint32_t i = 0;
uint32_t n = pow5_b - pow5_a;
for (; i < n; i++) {
if (i >= h.num_digits) {
return num_new_digits - 1;
} else if (h.digits[i] == pow5[i]) {
continue;
} else if (h.digits[i] < pow5[i]) {
return num_new_digits - 1;
} else {
return num_new_digits;
}
}
return num_new_digits;
}
} // end of anonymous namespace
uint64_t round(decimal &h) {
if ((h.num_digits == 0) || (h.decimal_point < 0)) {
return 0;
} else if (h.decimal_point > 18) {
return UINT64_MAX;
}
// at this point, we know that h.decimal_point >= 0
uint32_t dp = uint32_t(h.decimal_point);
uint64_t n = 0;
for (uint32_t i = 0; i < dp; i++) {
n = (10 * n) + ((i < h.num_digits) ? h.digits[i] : 0);
}
bool round_up = false;
if (dp < h.num_digits) {
round_up = h.digits[dp] >= 5; // normally, we round up
// but we may need to round to even!
if ((h.digits[dp] == 5) && (dp + 1 == h.num_digits)) {
round_up = h.truncated || ((dp > 0) && (1 & h.digits[dp - 1]));
}
}
if (round_up) {
n++;
}
return n;
}
// computes h * 2^-shift
void decimal_left_shift(decimal &h, uint32_t shift) {
if (h.num_digits == 0) {
return;
}
uint32_t num_new_digits = number_of_digits_decimal_left_shift(h, shift);
int32_t read_index = int32_t(h.num_digits - 1);
uint32_t write_index = h.num_digits - 1 + num_new_digits;
uint64_t n = 0;
while (read_index >= 0) {
n += uint64_t(h.digits[read_index]) << shift;
uint64_t quotient = n / 10;
uint64_t remainder = n - (10 * quotient);
if (write_index < max_digits) {
h.digits[write_index] = uint8_t(remainder);
} else if (remainder > 0) {
h.truncated = true;
}
n = quotient;
write_index--;
read_index--;
}
while (n > 0) {
uint64_t quotient = n / 10;
uint64_t remainder = n - (10 * quotient);
if (write_index < max_digits) {
h.digits[write_index] = uint8_t(remainder);
} else if (remainder > 0) {
h.truncated = true;
}
n = quotient;
write_index--;
}
h.num_digits += num_new_digits;
if (h.num_digits > max_digits) {
h.num_digits = max_digits;
}
h.decimal_point += int32_t(num_new_digits);
trim(h);
}
// computes h * 2^shift
void decimal_right_shift(decimal &h, uint32_t shift) {
uint32_t read_index = 0;
uint32_t write_index = 0;
uint64_t n = 0;
while ((n >> shift) == 0) {
if (read_index < h.num_digits) {
n = (10 * n) + h.digits[read_index++];
} else if (n == 0) {
return;
} else {
while ((n >> shift) == 0) {
n = 10 * n;
read_index++;
}
break;
}
}
h.decimal_point -= int32_t(read_index - 1);
if (h.decimal_point < -decimal_point_range) { // it is zero
h.num_digits = 0;
h.decimal_point = 0;
h.negative = false;
h.truncated = false;
return;
}
uint64_t mask = (uint64_t(1) << shift) - 1;
while (read_index < h.num_digits) {
uint8_t new_digit = uint8_t(n >> shift);
n = (10 * (n & mask)) + h.digits[read_index++];
h.digits[write_index++] = new_digit;
}
while (n > 0) {
uint8_t new_digit = uint8_t(n >> shift);
n = 10 * (n & mask);
if (write_index < max_digits) {
h.digits[write_index++] = new_digit;
} else if (new_digit > 0) {
h.truncated = true;
}
}
h.num_digits = write_index;
trim(h);
}
template <typename binary> adjusted_mantissa compute_float(decimal &d) {
adjusted_mantissa answer;
if (d.num_digits == 0) {
// should be zero
answer.power2 = 0;
answer.mantissa = 0;
return answer;
}
// At this point, going further, we can assume that d.num_digits > 0.
// We want to guard against excessive decimal point values because
// they can result in long running times. Indeed, we do
// shifts by at most 60 bits. We have that log(10**400)/log(2**60) ~= 22
// which is fine, but log(10**299995)/log(2**60) ~= 16609 which is not
// fine (runs for a long time).
//
if(d.decimal_point < -324) {
// We have something smaller than 1e-324 which is always zero
// in binary64 and binary32.
// It should be zero.
answer.power2 = 0;
answer.mantissa = 0;
return answer;
} else if(d.decimal_point >= 310) {
// We have something at least as large as 0.1e310 which is
// always infinite.
answer.power2 = binary::infinite_power();
answer.mantissa = 0;
return answer;
}
static const uint32_t max_shift = 60;
static const uint32_t num_powers = 19;
static const uint8_t powers[19] = {
0, 3, 6, 9, 13, 16, 19, 23, 26, 29, //
33, 36, 39, 43, 46, 49, 53, 56, 59, //
};
int32_t exp2 = 0;
while (d.decimal_point > 0) {
uint32_t n = uint32_t(d.decimal_point);
uint32_t shift = (n < num_powers) ? powers[n] : max_shift;
decimal_right_shift(d, shift);
if (d.decimal_point < -decimal_point_range) {
// should be zero
answer.power2 = 0;
answer.mantissa = 0;
return answer;
}
exp2 += int32_t(shift);
}
// We shift left toward [1/2 ... 1].
while (d.decimal_point <= 0) {
uint32_t shift;
if (d.decimal_point == 0) {
if (d.digits[0] >= 5) {
break;
}
shift = (d.digits[0] < 2) ? 2 : 1;
} else {
uint32_t n = uint32_t(-d.decimal_point);
shift = (n < num_powers) ? powers[n] : max_shift;
}
decimal_left_shift(d, shift);
if (d.decimal_point > decimal_point_range) {
// we want to get infinity:
answer.power2 = 0xFF;
answer.mantissa = 0;
return answer;
}
exp2 -= int32_t(shift);
}
// We are now in the range [1/2 ... 1] but the binary format uses [1 ... 2].
exp2--;
constexpr int32_t minimum_exponent = binary::minimum_exponent();
while ((minimum_exponent + 1) > exp2) {
uint32_t n = uint32_t((minimum_exponent + 1) - exp2);
if (n > max_shift) {
n = max_shift;
}
decimal_right_shift(d, n);
exp2 += int32_t(n);
}
if ((exp2 - minimum_exponent) >= binary::infinite_power()) {
answer.power2 = binary::infinite_power();
answer.mantissa = 0;
return answer;
}
const int mantissa_size_in_bits = binary::mantissa_explicit_bits() + 1;
decimal_left_shift(d, mantissa_size_in_bits);
uint64_t mantissa = round(d);
// It is possible that we have an overflow, in which case we need
// to shift back.
if (mantissa >= (uint64_t(1) << mantissa_size_in_bits)) {
decimal_right_shift(d, 1);
exp2 += 1;
mantissa = round(d);
if ((exp2 - minimum_exponent) >= binary::infinite_power()) {
answer.power2 = binary::infinite_power();
answer.mantissa = 0;
return answer;
}
}
answer.power2 = exp2 - binary::minimum_exponent();
if (mantissa < (uint64_t(1) << binary::mantissa_explicit_bits())) {
answer.power2--;
}
answer.mantissa =
mantissa & ((uint64_t(1) << binary::mantissa_explicit_bits()) - 1);
return answer;
}
template <typename binary>
adjusted_mantissa parse_long_mantissa(const char *first) {
decimal d = parse_decimal(first);
return compute_float<binary>(d);
}
double from_chars(const char *first) noexcept {
bool negative = first[0] == '-';
if (negative) {
first++;
}
adjusted_mantissa am = parse_long_mantissa<binary_format<double>>(first);
uint64_t word = am.mantissa;
word |= uint64_t(am.power2)
<< binary_format<double>::mantissa_explicit_bits();
word = negative ? word | (uint64_t(1) << binary_format<double>::sign_index())
: word;
double value;
std::memcpy(&value, &word, sizeof(double));
return value;
}
} // internal
} // simdjson
/* end file src/from_chars.cpp */
/* begin file src/internal/error_tables.cpp */
namespace simdjson {
namespace internal {
SIMDJSON_DLLIMPORTEXPORT const error_code_info error_codes[] {
{ SUCCESS, "No error" },
{ CAPACITY, "This parser can't support a document that big" },
{ MEMALLOC, "Error allocating memory, we're most likely out of memory" },
{ TAPE_ERROR, "The JSON document has an improper structure: missing or superfluous commas, braces, missing keys, etc." },
{ DEPTH_ERROR, "The JSON document was too deep (too many nested objects and arrays)" },
{ STRING_ERROR, "Problem while parsing a string" },
{ T_ATOM_ERROR, "Problem while parsing an atom starting with the letter 't'" },
{ F_ATOM_ERROR, "Problem while parsing an atom starting with the letter 'f'" },
{ N_ATOM_ERROR, "Problem while parsing an atom starting with the letter 'n'" },
{ NUMBER_ERROR, "Problem while parsing a number" },
{ UTF8_ERROR, "The input is not valid UTF-8" },
{ UNINITIALIZED, "Uninitialized" },
{ EMPTY, "Empty: no JSON found" },
{ UNESCAPED_CHARS, "Within strings, some characters must be escaped, we found unescaped characters" },
{ UNCLOSED_STRING, "A string is opened, but never closed." },
{ UNSUPPORTED_ARCHITECTURE, "simdjson does not have an implementation supported by this CPU architecture (perhaps it's a non-SIMD CPU?)." },
{ INCORRECT_TYPE, "The JSON element does not have the requested type." },
{ NUMBER_OUT_OF_RANGE, "The JSON number is too large or too small to fit within the requested type." },
{ INDEX_OUT_OF_BOUNDS, "Attempted to access an element of a JSON array that is beyond its length." },
{ NO_SUCH_FIELD, "The JSON field referenced does not exist in this object." },
{ IO_ERROR, "Error reading the file." },
{ INVALID_JSON_POINTER, "Invalid JSON pointer syntax." },
{ INVALID_URI_FRAGMENT, "Invalid URI fragment syntax." },
{ UNEXPECTED_ERROR, "Unexpected error, consider reporting this problem as you may have found a bug in simdjson" },
{ PARSER_IN_USE, "Cannot parse a new document while a document is still in use." }
}; // error_messages[]
} // namespace internal
} // namespace simdjson
/* end file src/internal/error_tables.cpp */
/* begin file src/internal/jsoncharutils_tables.cpp */
namespace simdjson {
namespace internal {
// structural chars here are
// they are { 0x7b } 0x7d : 0x3a [ 0x5b ] 0x5d , 0x2c (and NULL)
// we are also interested in the four whitespace characters
// space 0x20, linefeed 0x0a, horizontal tab 0x09 and carriage return 0x0d
SIMDJSON_DLLIMPORTEXPORT const bool structural_or_whitespace_negated[256] = {
1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 0, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 0, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1};
SIMDJSON_DLLIMPORTEXPORT const bool structural_or_whitespace[256] = {
0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 1, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 1, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
SIMDJSON_DLLIMPORTEXPORT const uint32_t digit_to_val32[886] = {
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0x0, 0x1, 0x2, 0x3, 0x4, 0x5,
0x6, 0x7, 0x8, 0x9, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xa,
0xb, 0xc, 0xd, 0xe, 0xf, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xa, 0xb, 0xc, 0xd, 0xe,
0xf, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0x0, 0x10, 0x20, 0x30, 0x40, 0x50,
0x60, 0x70, 0x80, 0x90, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xa0,
0xb0, 0xc0, 0xd0, 0xe0, 0xf0, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xa0, 0xb0, 0xc0, 0xd0, 0xe0,
0xf0, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0x0, 0x100, 0x200, 0x300, 0x400, 0x500,
0x600, 0x700, 0x800, 0x900, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xa00,
0xb00, 0xc00, 0xd00, 0xe00, 0xf00, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xa00, 0xb00, 0xc00, 0xd00, 0xe00,
0xf00, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0x0, 0x1000, 0x2000, 0x3000, 0x4000, 0x5000,
0x6000, 0x7000, 0x8000, 0x9000, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xa000,
0xb000, 0xc000, 0xd000, 0xe000, 0xf000, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xa000, 0xb000, 0xc000, 0xd000, 0xe000,
0xf000, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF,
0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF};
} // namespace internal
} // namespace simdjson
/* end file src/internal/jsoncharutils_tables.cpp */
/* begin file src/internal/numberparsing_tables.cpp */
namespace simdjson {
namespace internal {
// Precomputed powers of ten from 10^0 to 10^22. These
// can be represented exactly using the double type.
SIMDJSON_DLLIMPORTEXPORT const double power_of_ten[] = {
1e0, 1e1, 1e2, 1e3, 1e4, 1e5, 1e6, 1e7, 1e8, 1e9, 1e10, 1e11,
1e12, 1e13, 1e14, 1e15, 1e16, 1e17, 1e18, 1e19, 1e20, 1e21, 1e22};
/**
* When mapping numbers from decimal to binary,
* we go from w * 10^q to m * 2^p but we have
* 10^q = 5^q * 2^q, so effectively
* we are trying to match
* w * 2^q * 5^q to m * 2^p. Thus the powers of two
* are not a concern since they can be represented
* exactly using the binary notation, only the powers of five
* affect the binary significand.
*/
// The truncated powers of five from 5^-342 all the way to 5^308
// The mantissa is truncated to 128 bits, and
// never rounded up. Uses about 10KB.
SIMDJSON_DLLIMPORTEXPORT const uint64_t power_of_five_128[]= {
0xeef453d6923bd65a,0x113faa2906a13b3f,
0x9558b4661b6565f8,0x4ac7ca59a424c507,
0xbaaee17fa23ebf76,0x5d79bcf00d2df649,
0xe95a99df8ace6f53,0xf4d82c2c107973dc,
0x91d8a02bb6c10594,0x79071b9b8a4be869,
0xb64ec836a47146f9,0x9748e2826cdee284,
0xe3e27a444d8d98b7,0xfd1b1b2308169b25,
0x8e6d8c6ab0787f72,0xfe30f0f5e50e20f7,
0xb208ef855c969f4f,0xbdbd2d335e51a935,
0xde8b2b66b3bc4723,0xad2c788035e61382,
0x8b16fb203055ac76,0x4c3bcb5021afcc31,
0xaddcb9e83c6b1793,0xdf4abe242a1bbf3d,
0xd953e8624b85dd78,0xd71d6dad34a2af0d,
0x87d4713d6f33aa6b,0x8672648c40e5ad68,
0xa9c98d8ccb009506,0x680efdaf511f18c2,
0xd43bf0effdc0ba48,0x212bd1b2566def2,
0x84a57695fe98746d,0x14bb630f7604b57,
0xa5ced43b7e3e9188,0x419ea3bd35385e2d,
0xcf42894a5dce35ea,0x52064cac828675b9,
0x818995ce7aa0e1b2,0x7343efebd1940993,
0xa1ebfb4219491a1f,0x1014ebe6c5f90bf8,
0xca66fa129f9b60a6,0xd41a26e077774ef6,
0xfd00b897478238d0,0x8920b098955522b4,
0x9e20735e8cb16382,0x55b46e5f5d5535b0,
0xc5a890362fddbc62,0xeb2189f734aa831d,
0xf712b443bbd52b7b,0xa5e9ec7501d523e4,
0x9a6bb0aa55653b2d,0x47b233c92125366e,
0xc1069cd4eabe89f8,0x999ec0bb696e840a,
0xf148440a256e2c76,0xc00670ea43ca250d,
0x96cd2a865764dbca,0x380406926a5e5728,
0xbc807527ed3e12bc,0xc605083704f5ecf2,
0xeba09271e88d976b,0xf7864a44c633682e,
0x93445b8731587ea3,0x7ab3ee6afbe0211d,
0xb8157268fdae9e4c,0x5960ea05bad82964,
0xe61acf033d1a45df,0x6fb92487298e33bd,
0x8fd0c16206306bab,0xa5d3b6d479f8e056,
0xb3c4f1ba87bc8696,0x8f48a4899877186c,
0xe0b62e2929aba83c,0x331acdabfe94de87,
0x8c71dcd9ba0b4925,0x9ff0c08b7f1d0b14,
0xaf8e5410288e1b6f,0x7ecf0ae5ee44dd9,
0xdb71e91432b1a24a,0xc9e82cd9f69d6150,
0x892731ac9faf056e,0xbe311c083a225cd2,
0xab70fe17c79ac6ca,0x6dbd630a48aaf406,
0xd64d3d9db981787d,0x92cbbccdad5b108,
0x85f0468293f0eb4e,0x25bbf56008c58ea5,
0xa76c582338ed2621,0xaf2af2b80af6f24e,
0xd1476e2c07286faa,0x1af5af660db4aee1,
0x82cca4db847945ca,0x50d98d9fc890ed4d,
0xa37fce126597973c,0xe50ff107bab528a0,
0xcc5fc196fefd7d0c,0x1e53ed49a96272c8,
0xff77b1fcbebcdc4f,0x25e8e89c13bb0f7a,
0x9faacf3df73609b1,0x77b191618c54e9ac,
0xc795830d75038c1d,0xd59df5b9ef6a2417,
0xf97ae3d0d2446f25,0x4b0573286b44ad1d,
0x9becce62836ac577,0x4ee367f9430aec32,
0xc2e801fb244576d5,0x229c41f793cda73f,
0xf3a20279ed56d48a,0x6b43527578c1110f,
0x9845418c345644d6,0x830a13896b78aaa9,
0xbe5691ef416bd60c,0x23cc986bc656d553,
0xedec366b11c6cb8f,0x2cbfbe86b7ec8aa8,
0x94b3a202eb1c3f39,0x7bf7d71432f3d6a9,
0xb9e08a83a5e34f07,0xdaf5ccd93fb0cc53,
0xe858ad248f5c22c9,0xd1b3400f8f9cff68,
0x91376c36d99995be,0x23100809b9c21fa1,
0xb58547448ffffb2d,0xabd40a0c2832a78a,
0xe2e69915b3fff9f9,0x16c90c8f323f516c,
0x8dd01fad907ffc3b,0xae3da7d97f6792e3,
0xb1442798f49ffb4a,0x99cd11cfdf41779c,
0xdd95317f31c7fa1d,0x40405643d711d583,
0x8a7d3eef7f1cfc52,0x482835ea666b2572,
0xad1c8eab5ee43b66,0xda3243650005eecf,
0xd863b256369d4a40,0x90bed43e40076a82,
0x873e4f75e2224e68,0x5a7744a6e804a291,
0xa90de3535aaae202,0x711515d0a205cb36,
0xd3515c2831559a83,0xd5a5b44ca873e03,
0x8412d9991ed58091,0xe858790afe9486c2,
0xa5178fff668ae0b6,0x626e974dbe39a872,
0xce5d73ff402d98e3,0xfb0a3d212dc8128f,
0x80fa687f881c7f8e,0x7ce66634bc9d0b99,
0xa139029f6a239f72,0x1c1fffc1ebc44e80,
0xc987434744ac874e,0xa327ffb266b56220,
0xfbe9141915d7a922,0x4bf1ff9f0062baa8,
0x9d71ac8fada6c9b5,0x6f773fc3603db4a9,
0xc4ce17b399107c22,0xcb550fb4384d21d3,
0xf6019da07f549b2b,0x7e2a53a146606a48,
0x99c102844f94e0fb,0x2eda7444cbfc426d,
0xc0314325637a1939,0xfa911155fefb5308,
0xf03d93eebc589f88,0x793555ab7eba27ca,
0x96267c7535b763b5,0x4bc1558b2f3458de,
0xbbb01b9283253ca2,0x9eb1aaedfb016f16,
0xea9c227723ee8bcb,0x465e15a979c1cadc,
0x92a1958a7675175f,0xbfacd89ec191ec9,
0xb749faed14125d36,0xcef980ec671f667b,
0xe51c79a85916f484,0x82b7e12780e7401a,
0x8f31cc0937ae58d2,0xd1b2ecb8b0908810,
0xb2fe3f0b8599ef07,0x861fa7e6dcb4aa15,
0xdfbdcece67006ac9,0x67a791e093e1d49a,
0x8bd6a141006042bd,0xe0c8bb2c5c6d24e0,
0xaecc49914078536d,0x58fae9f773886e18,
0xda7f5bf590966848,0xaf39a475506a899e,
0x888f99797a5e012d,0x6d8406c952429603,
0xaab37fd7d8f58178,0xc8e5087ba6d33b83,
0xd5605fcdcf32e1d6,0xfb1e4a9a90880a64,
0x855c3be0a17fcd26,0x5cf2eea09a55067f,
0xa6b34ad8c9dfc06f,0xf42faa48c0ea481e,
0xd0601d8efc57b08b,0xf13b94daf124da26,
0x823c12795db6ce57,0x76c53d08d6b70858,
0xa2cb1717b52481ed,0x54768c4b0c64ca6e,
0xcb7ddcdda26da268,0xa9942f5dcf7dfd09,
0xfe5d54150b090b02,0xd3f93b35435d7c4c,
0x9efa548d26e5a6e1,0xc47bc5014a1a6daf,
0xc6b8e9b0709f109a,0x359ab6419ca1091b,
0xf867241c8cc6d4c0,0xc30163d203c94b62,
0x9b407691d7fc44f8,0x79e0de63425dcf1d,
0xc21094364dfb5636,0x985915fc12f542e4,
0xf294b943e17a2bc4,0x3e6f5b7b17b2939d,
0x979cf3ca6cec5b5a,0xa705992ceecf9c42,
0xbd8430bd08277231,0x50c6ff782a838353,
0xece53cec4a314ebd,0xa4f8bf5635246428,
0x940f4613ae5ed136,0x871b7795e136be99,
0xb913179899f68584,0x28e2557b59846e3f,
0xe757dd7ec07426e5,0x331aeada2fe589cf,
0x9096ea6f3848984f,0x3ff0d2c85def7621,
0xb4bca50b065abe63,0xfed077a756b53a9,
0xe1ebce4dc7f16dfb,0xd3e8495912c62894,
0x8d3360f09cf6e4bd,0x64712dd7abbbd95c,
0xb080392cc4349dec,0xbd8d794d96aacfb3,
0xdca04777f541c567,0xecf0d7a0fc5583a0,
0x89e42caaf9491b60,0xf41686c49db57244,
0xac5d37d5b79b6239,0x311c2875c522ced5,
0xd77485cb25823ac7,0x7d633293366b828b,
0x86a8d39ef77164bc,0xae5dff9c02033197,
0xa8530886b54dbdeb,0xd9f57f830283fdfc,
0xd267caa862a12d66,0xd072df63c324fd7b,
0x8380dea93da4bc60,0x4247cb9e59f71e6d,
0xa46116538d0deb78,0x52d9be85f074e608,
0xcd795be870516656,0x67902e276c921f8b,
0x806bd9714632dff6,0xba1cd8a3db53b6,
0xa086cfcd97bf97f3,0x80e8a40eccd228a4,
0xc8a883c0fdaf7df0,0x6122cd128006b2cd,
0xfad2a4b13d1b5d6c,0x796b805720085f81,
0x9cc3a6eec6311a63,0xcbe3303674053bb0,
0xc3f490aa77bd60fc,0xbedbfc4411068a9c,
0xf4f1b4d515acb93b,0xee92fb5515482d44,
0x991711052d8bf3c5,0x751bdd152d4d1c4a,
0xbf5cd54678eef0b6,0xd262d45a78a0635d,
0xef340a98172aace4,0x86fb897116c87c34,
0x9580869f0e7aac0e,0xd45d35e6ae3d4da0,
0xbae0a846d2195712,0x8974836059cca109,
0xe998d258869facd7,0x2bd1a438703fc94b,
0x91ff83775423cc06,0x7b6306a34627ddcf,
0xb67f6455292cbf08,0x1a3bc84c17b1d542,
0xe41f3d6a7377eeca,0x20caba5f1d9e4a93,
0x8e938662882af53e,0x547eb47b7282ee9c,
0xb23867fb2a35b28d,0xe99e619a4f23aa43,
0xdec681f9f4c31f31,0x6405fa00e2ec94d4,
0x8b3c113c38f9f37e,0xde83bc408dd3dd04,
0xae0b158b4738705e,0x9624ab50b148d445,
0xd98ddaee19068c76,0x3badd624dd9b0957,
0x87f8a8d4cfa417c9,0xe54ca5d70a80e5d6,
0xa9f6d30a038d1dbc,0x5e9fcf4ccd211f4c,
0xd47487cc8470652b,0x7647c3200069671f,
0x84c8d4dfd2c63f3b,0x29ecd9f40041e073,
0xa5fb0a17c777cf09,0xf468107100525890,
0xcf79cc9db955c2cc,0x7182148d4066eeb4,
0x81ac1fe293d599bf,0xc6f14cd848405530,
0xa21727db38cb002f,0xb8ada00e5a506a7c,
0xca9cf1d206fdc03b,0xa6d90811f0e4851c,
0xfd442e4688bd304a,0x908f4a166d1da663,
0x9e4a9cec15763e2e,0x9a598e4e043287fe,
0xc5dd44271ad3cdba,0x40eff1e1853f29fd,
0xf7549530e188c128,0xd12bee59e68ef47c,
0x9a94dd3e8cf578b9,0x82bb74f8301958ce,
0xc13a148e3032d6e7,0xe36a52363c1faf01,
0xf18899b1bc3f8ca1,0xdc44e6c3cb279ac1,
0x96f5600f15a7b7e5,0x29ab103a5ef8c0b9,
0xbcb2b812db11a5de,0x7415d448f6b6f0e7,
0xebdf661791d60f56,0x111b495b3464ad21,
0x936b9fcebb25c995,0xcab10dd900beec34,
0xb84687c269ef3bfb,0x3d5d514f40eea742,
0xe65829b3046b0afa,0xcb4a5a3112a5112,
0x8ff71a0fe2c2e6dc,0x47f0e785eaba72ab,
0xb3f4e093db73a093,0x59ed216765690f56,
0xe0f218b8d25088b8,0x306869c13ec3532c,
0x8c974f7383725573,0x1e414218c73a13fb,
0xafbd2350644eeacf,0xe5d1929ef90898fa,
0xdbac6c247d62a583,0xdf45f746b74abf39,
0x894bc396ce5da772,0x6b8bba8c328eb783,
0xab9eb47c81f5114f,0x66ea92f3f326564,
0xd686619ba27255a2,0xc80a537b0efefebd,
0x8613fd0145877585,0xbd06742ce95f5f36,
0xa798fc4196e952e7,0x2c48113823b73704,
0xd17f3b51fca3a7a0,0xf75a15862ca504c5,
0x82ef85133de648c4,0x9a984d73dbe722fb,
0xa3ab66580d5fdaf5,0xc13e60d0d2e0ebba,
0xcc963fee10b7d1b3,0x318df905079926a8,
0xffbbcfe994e5c61f,0xfdf17746497f7052,
0x9fd561f1fd0f9bd3,0xfeb6ea8bedefa633,
0xc7caba6e7c5382c8,0xfe64a52ee96b8fc0,
0xf9bd690a1b68637b,0x3dfdce7aa3c673b0,
0x9c1661a651213e2d,0x6bea10ca65c084e,
0xc31bfa0fe5698db8,0x486e494fcff30a62,
0xf3e2f893dec3f126,0x5a89dba3c3efccfa,
0x986ddb5c6b3a76b7,0xf89629465a75e01c,
0xbe89523386091465,0xf6bbb397f1135823,
0xee2ba6c0678b597f,0x746aa07ded582e2c,
0x94db483840b717ef,0xa8c2a44eb4571cdc,
0xba121a4650e4ddeb,0x92f34d62616ce413,
0xe896a0d7e51e1566,0x77b020baf9c81d17,
0x915e2486ef32cd60,0xace1474dc1d122e,
0xb5b5ada8aaff80b8,0xd819992132456ba,
0xe3231912d5bf60e6,0x10e1fff697ed6c69,
0x8df5efabc5979c8f,0xca8d3ffa1ef463c1,
0xb1736b96b6fd83b3,0xbd308ff8a6b17cb2,
0xddd0467c64bce4a0,0xac7cb3f6d05ddbde,
0x8aa22c0dbef60ee4,0x6bcdf07a423aa96b,
0xad4ab7112eb3929d,0x86c16c98d2c953c6,
0xd89d64d57a607744,0xe871c7bf077ba8b7,
0x87625f056c7c4a8b,0x11471cd764ad4972,
0xa93af6c6c79b5d2d,0xd598e40d3dd89bcf,
0xd389b47879823479,0x4aff1d108d4ec2c3,
0x843610cb4bf160cb,0xcedf722a585139ba,
0xa54394fe1eedb8fe,0xc2974eb4ee658828,
0xce947a3da6a9273e,0x733d226229feea32,
0x811ccc668829b887,0x806357d5a3f525f,
0xa163ff802a3426a8,0xca07c2dcb0cf26f7,
0xc9bcff6034c13052,0xfc89b393dd02f0b5,
0xfc2c3f3841f17c67,0xbbac2078d443ace2,
0x9d9ba7832936edc0,0xd54b944b84aa4c0d,
0xc5029163f384a931,0xa9e795e65d4df11,
0xf64335bcf065d37d,0x4d4617b5ff4a16d5,
0x99ea0196163fa42e,0x504bced1bf8e4e45,
0xc06481fb9bcf8d39,0xe45ec2862f71e1d6,
0xf07da27a82c37088,0x5d767327bb4e5a4c,
0x964e858c91ba2655,0x3a6a07f8d510f86f,
0xbbe226efb628afea,0x890489f70a55368b,
0xeadab0aba3b2dbe5,0x2b45ac74ccea842e,
0x92c8ae6b464fc96f,0x3b0b8bc90012929d,
0xb77ada0617e3bbcb,0x9ce6ebb40173744,
0xe55990879ddcaabd,0xcc420a6a101d0515,
0x8f57fa54c2a9eab6,0x9fa946824a12232d,
0xb32df8e9f3546564,0x47939822dc96abf9,
0xdff9772470297ebd,0x59787e2b93bc56f7,
0x8bfbea76c619ef36,0x57eb4edb3c55b65a,
0xaefae51477a06b03,0xede622920b6b23f1,
0xdab99e59958885c4,0xe95fab368e45eced,
0x88b402f7fd75539b,0x11dbcb0218ebb414,
0xaae103b5fcd2a881,0xd652bdc29f26a119,
0xd59944a37c0752a2,0x4be76d3346f0495f,
0x857fcae62d8493a5,0x6f70a4400c562ddb,
0xa6dfbd9fb8e5b88e,0xcb4ccd500f6bb952,
0xd097ad07a71f26b2,0x7e2000a41346a7a7,
0x825ecc24c873782f,0x8ed400668c0c28c8,
0xa2f67f2dfa90563b,0x728900802f0f32fa,
0xcbb41ef979346bca,0x4f2b40a03ad2ffb9,
0xfea126b7d78186bc,0xe2f610c84987bfa8,
0x9f24b832e6b0f436,0xdd9ca7d2df4d7c9,
0xc6ede63fa05d3143,0x91503d1c79720dbb,
0xf8a95fcf88747d94,0x75a44c6397ce912a,
0x9b69dbe1b548ce7c,0xc986afbe3ee11aba,
0xc24452da229b021b,0xfbe85badce996168,
0xf2d56790ab41c2a2,0xfae27299423fb9c3,
0x97c560ba6b0919a5,0xdccd879fc967d41a,
0xbdb6b8e905cb600f,0x5400e987bbc1c920,
0xed246723473e3813,0x290123e9aab23b68,
0x9436c0760c86e30b,0xf9a0b6720aaf6521,
0xb94470938fa89bce,0xf808e40e8d5b3e69,
0xe7958cb87392c2c2,0xb60b1d1230b20e04,
0x90bd77f3483bb9b9,0xb1c6f22b5e6f48c2,
0xb4ecd5f01a4aa828,0x1e38aeb6360b1af3,
0xe2280b6c20dd5232,0x25c6da63c38de1b0,
0x8d590723948a535f,0x579c487e5a38ad0e,
0xb0af48ec79ace837,0x2d835a9df0c6d851,
0xdcdb1b2798182244,0xf8e431456cf88e65,
0x8a08f0f8bf0f156b,0x1b8e9ecb641b58ff,
0xac8b2d36eed2dac5,0xe272467e3d222f3f,
0xd7adf884aa879177,0x5b0ed81dcc6abb0f,
0x86ccbb52ea94baea,0x98e947129fc2b4e9,
0xa87fea27a539e9a5,0x3f2398d747b36224,
0xd29fe4b18e88640e,0x8eec7f0d19a03aad,
0x83a3eeeef9153e89,0x1953cf68300424ac,
0xa48ceaaab75a8e2b,0x5fa8c3423c052dd7,
0xcdb02555653131b6,0x3792f412cb06794d,
0x808e17555f3ebf11,0xe2bbd88bbee40bd0,
0xa0b19d2ab70e6ed6,0x5b6aceaeae9d0ec4,
0xc8de047564d20a8b,0xf245825a5a445275,
0xfb158592be068d2e,0xeed6e2f0f0d56712,
0x9ced737bb6c4183d,0x55464dd69685606b,
0xc428d05aa4751e4c,0xaa97e14c3c26b886,
0xf53304714d9265df,0xd53dd99f4b3066a8,
0x993fe2c6d07b7fab,0xe546a8038efe4029,
0xbf8fdb78849a5f96,0xde98520472bdd033,
0xef73d256a5c0f77c,0x963e66858f6d4440,
0x95a8637627989aad,0xdde7001379a44aa8,
0xbb127c53b17ec159,0x5560c018580d5d52,
0xe9d71b689dde71af,0xaab8f01e6e10b4a6,
0x9226712162ab070d,0xcab3961304ca70e8,
0xb6b00d69bb55c8d1,0x3d607b97c5fd0d22,
0xe45c10c42a2b3b05,0x8cb89a7db77c506a,
0x8eb98a7a9a5b04e3,0x77f3608e92adb242,
0xb267ed1940f1c61c,0x55f038b237591ed3,
0xdf01e85f912e37a3,0x6b6c46dec52f6688,
0x8b61313bbabce2c6,0x2323ac4b3b3da015,
0xae397d8aa96c1b77,0xabec975e0a0d081a,
0xd9c7dced53c72255,0x96e7bd358c904a21,
0x881cea14545c7575,0x7e50d64177da2e54,
0xaa242499697392d2,0xdde50bd1d5d0b9e9,
0xd4ad2dbfc3d07787,0x955e4ec64b44e864,
0x84ec3c97da624ab4,0xbd5af13bef0b113e,
0xa6274bbdd0fadd61,0xecb1ad8aeacdd58e,
0xcfb11ead453994ba,0x67de18eda5814af2,
0x81ceb32c4b43fcf4,0x80eacf948770ced7,
0xa2425ff75e14fc31,0xa1258379a94d028d,
0xcad2f7f5359a3b3e,0x96ee45813a04330,
0xfd87b5f28300ca0d,0x8bca9d6e188853fc,
0x9e74d1b791e07e48,0x775ea264cf55347e,
0xc612062576589dda,0x95364afe032a81a0,
0xf79687aed3eec551,0x3a83ddbd83f52210,
0x9abe14cd44753b52,0xc4926a9672793580,
0xc16d9a0095928a27,0x75b7053c0f178400,
0xf1c90080baf72cb1,0x5324c68b12dd6800,
0x971da05074da7bee,0xd3f6fc16ebca8000,
0xbce5086492111aea,0x88f4bb1ca6bd0000,
0xec1e4a7db69561a5,0x2b31e9e3d0700000,
0x9392ee8e921d5d07,0x3aff322e62600000,
0xb877aa3236a4b449,0x9befeb9fad487c3,
0xe69594bec44de15b,0x4c2ebe687989a9b4,
0x901d7cf73ab0acd9,0xf9d37014bf60a11,
0xb424dc35095cd80f,0x538484c19ef38c95,
0xe12e13424bb40e13,0x2865a5f206b06fba,
0x8cbccc096f5088cb,0xf93f87b7442e45d4,
0xafebff0bcb24aafe,0xf78f69a51539d749,
0xdbe6fecebdedd5be,0xb573440e5a884d1c,
0x89705f4136b4a597,0x31680a88f8953031,
0xabcc77118461cefc,0xfdc20d2b36ba7c3e,
0xd6bf94d5e57a42bc,0x3d32907604691b4d,
0x8637bd05af6c69b5,0xa63f9a49c2c1b110,
0xa7c5ac471b478423,0xfcf80dc33721d54,
0xd1b71758e219652b,0xd3c36113404ea4a9,
0x83126e978d4fdf3b,0x645a1cac083126ea,
0xa3d70a3d70a3d70a,0x3d70a3d70a3d70a4,
0xcccccccccccccccc,0xcccccccccccccccd,
0x8000000000000000,0x0,
0xa000000000000000,0x0,
0xc800000000000000,0x0,
0xfa00000000000000,0x0,
0x9c40000000000000,0x0,
0xc350000000000000,0x0,
0xf424000000000000,0x0,
0x9896800000000000,0x0,
0xbebc200000000000,0x0,
0xee6b280000000000,0x0,
0x9502f90000000000,0x0,
0xba43b74000000000,0x0,
0xe8d4a51000000000,0x0,
0x9184e72a00000000,0x0,
0xb5e620f480000000,0x0,
0xe35fa931a0000000,0x0,
0x8e1bc9bf04000000,0x0,
0xb1a2bc2ec5000000,0x0,
0xde0b6b3a76400000,0x0,
0x8ac7230489e80000,0x0,
0xad78ebc5ac620000,0x0,
0xd8d726b7177a8000,0x0,
0x878678326eac9000,0x0,
0xa968163f0a57b400,0x0,
0xd3c21bcecceda100,0x0,
0x84595161401484a0,0x0,
0xa56fa5b99019a5c8,0x0,
0xcecb8f27f4200f3a,0x0,
0x813f3978f8940984,0x4000000000000000,
0xa18f07d736b90be5,0x5000000000000000,
0xc9f2c9cd04674ede,0xa400000000000000,
0xfc6f7c4045812296,0x4d00000000000000,
0x9dc5ada82b70b59d,0xf020000000000000,
0xc5371912364ce305,0x6c28000000000000,
0xf684df56c3e01bc6,0xc732000000000000,
0x9a130b963a6c115c,0x3c7f400000000000,
0xc097ce7bc90715b3,0x4b9f100000000000,
0xf0bdc21abb48db20,0x1e86d40000000000,
0x96769950b50d88f4,0x1314448000000000,
0xbc143fa4e250eb31,0x17d955a000000000,
0xeb194f8e1ae525fd,0x5dcfab0800000000,
0x92efd1b8d0cf37be,0x5aa1cae500000000,
0xb7abc627050305ad,0xf14a3d9e40000000,
0xe596b7b0c643c719,0x6d9ccd05d0000000,
0x8f7e32ce7bea5c6f,0xe4820023a2000000,
0xb35dbf821ae4f38b,0xdda2802c8a800000,
0xe0352f62a19e306e,0xd50b2037ad200000,
0x8c213d9da502de45,0x4526f422cc340000,
0xaf298d050e4395d6,0x9670b12b7f410000,
0xdaf3f04651d47b4c,0x3c0cdd765f114000,
0x88d8762bf324cd0f,0xa5880a69fb6ac800,
0xab0e93b6efee0053,0x8eea0d047a457a00,
0xd5d238a4abe98068,0x72a4904598d6d880,
0x85a36366eb71f041,0x47a6da2b7f864750,
0xa70c3c40a64e6c51,0x999090b65f67d924,
0xd0cf4b50cfe20765,0xfff4b4e3f741cf6d,
0x82818f1281ed449f,0xbff8f10e7a8921a4,
0xa321f2d7226895c7,0xaff72d52192b6a0d,
0xcbea6f8ceb02bb39,0x9bf4f8a69f764490,
0xfee50b7025c36a08,0x2f236d04753d5b4,
0x9f4f2726179a2245,0x1d762422c946590,
0xc722f0ef9d80aad6,0x424d3ad2b7b97ef5,
0xf8ebad2b84e0d58b,0xd2e0898765a7deb2,
0x9b934c3b330c8577,0x63cc55f49f88eb2f,
0xc2781f49ffcfa6d5,0x3cbf6b71c76b25fb,
0xf316271c7fc3908a,0x8bef464e3945ef7a,
0x97edd871cfda3a56,0x97758bf0e3cbb5ac,
0xbde94e8e43d0c8ec,0x3d52eeed1cbea317,
0xed63a231d4c4fb27,0x4ca7aaa863ee4bdd,
0x945e455f24fb1cf8,0x8fe8caa93e74ef6a,
0xb975d6b6ee39e436,0xb3e2fd538e122b44,
0xe7d34c64a9c85d44,0x60dbbca87196b616,
0x90e40fbeea1d3a4a,0xbc8955e946fe31cd,
0xb51d13aea4a488dd,0x6babab6398bdbe41,
0xe264589a4dcdab14,0xc696963c7eed2dd1,
0x8d7eb76070a08aec,0xfc1e1de5cf543ca2,
0xb0de65388cc8ada8,0x3b25a55f43294bcb,
0xdd15fe86affad912,0x49ef0eb713f39ebe,
0x8a2dbf142dfcc7ab,0x6e3569326c784337,
0xacb92ed9397bf996,0x49c2c37f07965404,
0xd7e77a8f87daf7fb,0xdc33745ec97be906,
0x86f0ac99b4e8dafd,0x69a028bb3ded71a3,
0xa8acd7c0222311bc,0xc40832ea0d68ce0c,
0xd2d80db02aabd62b,0xf50a3fa490c30190,
0x83c7088e1aab65db,0x792667c6da79e0fa,
0xa4b8cab1a1563f52,0x577001b891185938,
0xcde6fd5e09abcf26,0xed4c0226b55e6f86,
0x80b05e5ac60b6178,0x544f8158315b05b4,
0xa0dc75f1778e39d6,0x696361ae3db1c721,
0xc913936dd571c84c,0x3bc3a19cd1e38e9,
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0x9d174b2dcec0e47b,0x62eb0d64283f9c76,
0xc45d1df942711d9a,0x3ba5d0bd324f8394,
0xf5746577930d6500,0xca8f44ec7ee36479,
0x9968bf6abbe85f20,0x7e998b13cf4e1ecb,
0xbfc2ef456ae276e8,0x9e3fedd8c321a67e,
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0x95d04aee3b80ece5,0xbba1f1d158724a12,
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0x924d692ca61be758,0x593c2626705f9c56,
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0xb2977ee300c50fe7,0x58edec91ec2cb657,
0xdf3d5e9bc0f653e1,0x2f2967b66737e3ed,
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0xae67f1e9aec07187,0xecd8590680a3aa11,
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0x884134fe908658b2,0x3109058d147fdcdd,
0xaa51823e34a7eede,0xbd4b46f0599fd415,
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0x850fadc09923329e,0x3e2cf6bc604ddb0,
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0x81f14fae158c5f6e,0x4fcb7e8f3f60c07e,
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0xc646d63501a1511d,0xb281e1fd541501b8,
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0xc1a12d2fc3978937,0x52d6b1641c83ae,
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0x93ba47c980e98cdf,0xc66f336c36b10137,
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0xe6d3102ad96cec1d,0xa60dc059157491e5,
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0xb454e4a179dd1877,0x29babe4598c311fb,
0xe16a1dc9d8545e94,0xf4296dd6fef3d67a,
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0xdc21a1171d42645d,0x76707543f4fa1f73,
0x899504ae72497eba,0x6a06494a791c53a8,
0xabfa45da0edbde69,0x487db9d17636892,
0xd6f8d7509292d603,0x45a9d2845d3c42b6,
0x865b86925b9bc5c2,0xb8a2392ba45a9b2,
0xa7f26836f282b732,0x8e6cac7768d7141e,
0xd1ef0244af2364ff,0x3207d795430cd926,
0x8335616aed761f1f,0x7f44e6bd49e807b8,
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0x802221226be55a64,0xc2494954da2c9789,
0xa02aa96b06deb0fd,0xf2db9baa10b7bd6c,
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0xfa42a8b73abbf48c,0xcb772339ba1f17f9,
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0x952ab45cfa97a0b2,0xdd945a747bf26183,
0xba756174393d88df,0x94f971119aeef9e4,
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0xb616a12b7fe617aa,0x577b986b314d6009,
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0xb1d219647ae6b31c,0x596eb2d8ae258fc8,
0xde469fbd99a05fe3,0x6fca5f8ed9aef3bb,
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0xada72ccc20054ae9,0xaf561aa79a10ae6a,
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0xd3fa922f2d1675f2,0x42889b8997915ce8,
0x847c9b5d7c2e09b7,0x69956135febada11,
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0xca28a291859bbf93,0x7d7b8f7503cfdcfe,
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0x9a3c2087a63f6399,0x36ac54e2f678864b,
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0x9316ff75dd87cbd8,0x9a7f12442d588f2,
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0xe5d3ef282a242e81,0x8f1668c8a86da5fa,
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0xb38d92d760ec4455,0x37c981dcc395a9ac,
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0x88fcf317f22241e2,0x441fece3bdf81f03,
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0x85c7056562757456,0xf6872d5667844e49,
0xa738c6bebb12d16c,0xb428f8ac016561db,
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0x82a45b450226b39c,0xecc0024661173473,
0xa34d721642b06084,0x27f002d7f95d0190,
0xcc20ce9bd35c78a5,0x31ec038df7b441f4,
0xff290242c83396ce,0x7e67047175a15271,
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0xc75809c42c684dd1,0x52c07b78a3e60868,
0xf92e0c3537826145,0xa7709a56ccdf8a82,
0x9bbcc7a142b17ccb,0x88a66076400bb691,
0xc2abf989935ddbfe,0x6acff893d00ea435,
0xf356f7ebf83552fe,0x583f6b8c4124d43,
0x98165af37b2153de,0xc3727a337a8b704a,
0xbe1bf1b059e9a8d6,0x744f18c0592e4c5c,
0xeda2ee1c7064130c,0x1162def06f79df73,
0x9485d4d1c63e8be7,0x8addcb5645ac2ba8,
0xb9a74a0637ce2ee1,0x6d953e2bd7173692,
0xe8111c87c5c1ba99,0xc8fa8db6ccdd0437,
0x910ab1d4db9914a0,0x1d9c9892400a22a2,
0xb54d5e4a127f59c8,0x2503beb6d00cab4b,
0xe2a0b5dc971f303a,0x2e44ae64840fd61d,
0x8da471a9de737e24,0x5ceaecfed289e5d2,
0xb10d8e1456105dad,0x7425a83e872c5f47,
0xdd50f1996b947518,0xd12f124e28f77719,
0x8a5296ffe33cc92f,0x82bd6b70d99aaa6f,
0xace73cbfdc0bfb7b,0x636cc64d1001550b,
0xd8210befd30efa5a,0x3c47f7e05401aa4e,
0x8714a775e3e95c78,0x65acfaec34810a71,
0xa8d9d1535ce3b396,0x7f1839a741a14d0d,
0xd31045a8341ca07c,0x1ede48111209a050,
0x83ea2b892091e44d,0x934aed0aab460432,
0xa4e4b66b68b65d60,0xf81da84d5617853f,
0xce1de40642e3f4b9,0x36251260ab9d668e,
0x80d2ae83e9ce78f3,0xc1d72b7c6b426019,
0xa1075a24e4421730,0xb24cf65b8612f81f,
0xc94930ae1d529cfc,0xdee033f26797b627,
0xfb9b7cd9a4a7443c,0x169840ef017da3b1,
0x9d412e0806e88aa5,0x8e1f289560ee864e,
0xc491798a08a2ad4e,0xf1a6f2bab92a27e2,
0xf5b5d7ec8acb58a2,0xae10af696774b1db,
0x9991a6f3d6bf1765,0xacca6da1e0a8ef29,
0xbff610b0cc6edd3f,0x17fd090a58d32af3,
0xeff394dcff8a948e,0xddfc4b4cef07f5b0,
0x95f83d0a1fb69cd9,0x4abdaf101564f98e,
0xbb764c4ca7a4440f,0x9d6d1ad41abe37f1,
0xea53df5fd18d5513,0x84c86189216dc5ed,
0x92746b9be2f8552c,0x32fd3cf5b4e49bb4,
0xb7118682dbb66a77,0x3fbc8c33221dc2a1,
0xe4d5e82392a40515,0xfabaf3feaa5334a,
0x8f05b1163ba6832d,0x29cb4d87f2a7400e,
0xb2c71d5bca9023f8,0x743e20e9ef511012,
0xdf78e4b2bd342cf6,0x914da9246b255416,
0x8bab8eefb6409c1a,0x1ad089b6c2f7548e,
0xae9672aba3d0c320,0xa184ac2473b529b1,
0xda3c0f568cc4f3e8,0xc9e5d72d90a2741e,
0x8865899617fb1871,0x7e2fa67c7a658892,
0xaa7eebfb9df9de8d,0xddbb901b98feeab7,
0xd51ea6fa85785631,0x552a74227f3ea565,
0x8533285c936b35de,0xd53a88958f87275f,
0xa67ff273b8460356,0x8a892abaf368f137,
0xd01fef10a657842c,0x2d2b7569b0432d85,
0x8213f56a67f6b29b,0x9c3b29620e29fc73,
0xa298f2c501f45f42,0x8349f3ba91b47b8f,
0xcb3f2f7642717713,0x241c70a936219a73,
0xfe0efb53d30dd4d7,0xed238cd383aa0110,
0x9ec95d1463e8a506,0xf4363804324a40aa,
0xc67bb4597ce2ce48,0xb143c6053edcd0d5,
0xf81aa16fdc1b81da,0xdd94b7868e94050a,
0x9b10a4e5e9913128,0xca7cf2b4191c8326,
0xc1d4ce1f63f57d72,0xfd1c2f611f63a3f0,
0xf24a01a73cf2dccf,0xbc633b39673c8cec,
0x976e41088617ca01,0xd5be0503e085d813,
0xbd49d14aa79dbc82,0x4b2d8644d8a74e18,
0xec9c459d51852ba2,0xddf8e7d60ed1219e,
0x93e1ab8252f33b45,0xcabb90e5c942b503,
0xb8da1662e7b00a17,0x3d6a751f3b936243,
0xe7109bfba19c0c9d,0xcc512670a783ad4,
0x906a617d450187e2,0x27fb2b80668b24c5,
0xb484f9dc9641e9da,0xb1f9f660802dedf6,
0xe1a63853bbd26451,0x5e7873f8a0396973,
0x8d07e33455637eb2,0xdb0b487b6423e1e8,
0xb049dc016abc5e5f,0x91ce1a9a3d2cda62,
0xdc5c5301c56b75f7,0x7641a140cc7810fb,
0x89b9b3e11b6329ba,0xa9e904c87fcb0a9d,
0xac2820d9623bf429,0x546345fa9fbdcd44,
0xd732290fbacaf133,0xa97c177947ad4095,
0x867f59a9d4bed6c0,0x49ed8eabcccc485d,
0xa81f301449ee8c70,0x5c68f256bfff5a74,
0xd226fc195c6a2f8c,0x73832eec6fff3111,
0x83585d8fd9c25db7,0xc831fd53c5ff7eab,
0xa42e74f3d032f525,0xba3e7ca8b77f5e55,
0xcd3a1230c43fb26f,0x28ce1bd2e55f35eb,
0x80444b5e7aa7cf85,0x7980d163cf5b81b3,
0xa0555e361951c366,0xd7e105bcc332621f,
0xc86ab5c39fa63440,0x8dd9472bf3fefaa7,
0xfa856334878fc150,0xb14f98f6f0feb951,
0x9c935e00d4b9d8d2,0x6ed1bf9a569f33d3,
0xc3b8358109e84f07,0xa862f80ec4700c8,
0xf4a642e14c6262c8,0xcd27bb612758c0fa,
0x98e7e9cccfbd7dbd,0x8038d51cb897789c,
0xbf21e44003acdd2c,0xe0470a63e6bd56c3,
0xeeea5d5004981478,0x1858ccfce06cac74,
0x95527a5202df0ccb,0xf37801e0c43ebc8,
0xbaa718e68396cffd,0xd30560258f54e6ba,
0xe950df20247c83fd,0x47c6b82ef32a2069,
0x91d28b7416cdd27e,0x4cdc331d57fa5441,
0xb6472e511c81471d,0xe0133fe4adf8e952,
0xe3d8f9e563a198e5,0x58180fddd97723a6,
0x8e679c2f5e44ff8f,0x570f09eaa7ea7648,};
} // namespace internal
} // namespace simdjson
/* end file src/internal/numberparsing_tables.cpp */
/* begin file src/internal/simdprune_tables.cpp */
#if SIMDJSON_IMPLEMENTATION_ARM64 || SIMDJSON_IMPLEMENTATION_HASWELL || SIMDJSON_IMPLEMENTATION_WESTMERE || SIMDJSON_IMPLEMENTATION_PPC64
#include <cstdint>
namespace simdjson { // table modified and copied from
namespace internal { // http://graphics.stanford.edu/~seander/bithacks.html#CountBitsSetTable
SIMDJSON_DLLIMPORTEXPORT const unsigned char BitsSetTable256mul2[256] = {
0, 2, 2, 4, 2, 4, 4, 6, 2, 4, 4, 6, 4, 6, 6, 8, 2, 4, 4,
6, 4, 6, 6, 8, 4, 6, 6, 8, 6, 8, 8, 10, 2, 4, 4, 6, 4, 6,
6, 8, 4, 6, 6, 8, 6, 8, 8, 10, 4, 6, 6, 8, 6, 8, 8, 10, 6,
8, 8, 10, 8, 10, 10, 12, 2, 4, 4, 6, 4, 6, 6, 8, 4, 6, 6, 8,
6, 8, 8, 10, 4, 6, 6, 8, 6, 8, 8, 10, 6, 8, 8, 10, 8, 10, 10,
12, 4, 6, 6, 8, 6, 8, 8, 10, 6, 8, 8, 10, 8, 10, 10, 12, 6, 8,
8, 10, 8, 10, 10, 12, 8, 10, 10, 12, 10, 12, 12, 14, 2, 4, 4, 6, 4,
6, 6, 8, 4, 6, 6, 8, 6, 8, 8, 10, 4, 6, 6, 8, 6, 8, 8, 10,
6, 8, 8, 10, 8, 10, 10, 12, 4, 6, 6, 8, 6, 8, 8, 10, 6, 8, 8,
10, 8, 10, 10, 12, 6, 8, 8, 10, 8, 10, 10, 12, 8, 10, 10, 12, 10, 12,
12, 14, 4, 6, 6, 8, 6, 8, 8, 10, 6, 8, 8, 10, 8, 10, 10, 12, 6,
8, 8, 10, 8, 10, 10, 12, 8, 10, 10, 12, 10, 12, 12, 14, 6, 8, 8, 10,
8, 10, 10, 12, 8, 10, 10, 12, 10, 12, 12, 14, 8, 10, 10, 12, 10, 12, 12,
14, 10, 12, 12, 14, 12, 14, 14, 16};
SIMDJSON_DLLIMPORTEXPORT const uint8_t pshufb_combine_table[272] = {
0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b,
0x0c, 0x0d, 0x0e, 0x0f, 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x08,
0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0xff, 0x00, 0x01, 0x02, 0x03,
0x04, 0x05, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0xff, 0xff,
0x00, 0x01, 0x02, 0x03, 0x04, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e,
0x0f, 0xff, 0xff, 0xff, 0x00, 0x01, 0x02, 0x03, 0x08, 0x09, 0x0a, 0x0b,
0x0c, 0x0d, 0x0e, 0x0f, 0xff, 0xff, 0xff, 0xff, 0x00, 0x01, 0x02, 0x08,
0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0xff, 0xff, 0xff, 0xff, 0xff,
0x00, 0x01, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0xff, 0xff,
0xff, 0xff, 0xff, 0xff, 0x00, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e,
0x0f, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0x08, 0x09, 0x0a, 0x0b,
0x0c, 0x0d, 0x0e, 0x0f, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
};
// 256 * 8 bytes = 2kB, easily fits in cache.
SIMDJSON_DLLIMPORTEXPORT const uint64_t thintable_epi8[256] = {
0x0706050403020100, 0x0007060504030201, 0x0007060504030200,
0x0000070605040302, 0x0007060504030100, 0x0000070605040301,
0x0000070605040300, 0x0000000706050403, 0x0007060504020100,
0x0000070605040201, 0x0000070605040200, 0x0000000706050402,
0x0000070605040100, 0x0000000706050401, 0x0000000706050400,
0x0000000007060504, 0x0007060503020100, 0x0000070605030201,
0x0000070605030200, 0x0000000706050302, 0x0000070605030100,
0x0000000706050301, 0x0000000706050300, 0x0000000007060503,
0x0000070605020100, 0x0000000706050201, 0x0000000706050200,
0x0000000007060502, 0x0000000706050100, 0x0000000007060501,
0x0000000007060500, 0x0000000000070605, 0x0007060403020100,
0x0000070604030201, 0x0000070604030200, 0x0000000706040302,
0x0000070604030100, 0x0000000706040301, 0x0000000706040300,
0x0000000007060403, 0x0000070604020100, 0x0000000706040201,
0x0000000706040200, 0x0000000007060402, 0x0000000706040100,
0x0000000007060401, 0x0000000007060400, 0x0000000000070604,
0x0000070603020100, 0x0000000706030201, 0x0000000706030200,
0x0000000007060302, 0x0000000706030100, 0x0000000007060301,
0x0000000007060300, 0x0000000000070603, 0x0000000706020100,
0x0000000007060201, 0x0000000007060200, 0x0000000000070602,
0x0000000007060100, 0x0000000000070601, 0x0000000000070600,
0x0000000000000706, 0x0007050403020100, 0x0000070504030201,
0x0000070504030200, 0x0000000705040302, 0x0000070504030100,
0x0000000705040301, 0x0000000705040300, 0x0000000007050403,
0x0000070504020100, 0x0000000705040201, 0x0000000705040200,
0x0000000007050402, 0x0000000705040100, 0x0000000007050401,
0x0000000007050400, 0x0000000000070504, 0x0000070503020100,
0x0000000705030201, 0x0000000705030200, 0x0000000007050302,
0x0000000705030100, 0x0000000007050301, 0x0000000007050300,
0x0000000000070503, 0x0000000705020100, 0x0000000007050201,
0x0000000007050200, 0x0000000000070502, 0x0000000007050100,
0x0000000000070501, 0x0000000000070500, 0x0000000000000705,
0x0000070403020100, 0x0000000704030201, 0x0000000704030200,
0x0000000007040302, 0x0000000704030100, 0x0000000007040301,
0x0000000007040300, 0x0000000000070403, 0x0000000704020100,
0x0000000007040201, 0x0000000007040200, 0x0000000000070402,
0x0000000007040100, 0x0000000000070401, 0x0000000000070400,
0x0000000000000704, 0x0000000703020100, 0x0000000007030201,
0x0000000007030200, 0x0000000000070302, 0x0000000007030100,
0x0000000000070301, 0x0000000000070300, 0x0000000000000703,
0x0000000007020100, 0x0000000000070201, 0x0000000000070200,
0x0000000000000702, 0x0000000000070100, 0x0000000000000701,
0x0000000000000700, 0x0000000000000007, 0x0006050403020100,
0x0000060504030201, 0x0000060504030200, 0x0000000605040302,
0x0000060504030100, 0x0000000605040301, 0x0000000605040300,
0x0000000006050403, 0x0000060504020100, 0x0000000605040201,
0x0000000605040200, 0x0000000006050402, 0x0000000605040100,
0x0000000006050401, 0x0000000006050400, 0x0000000000060504,
0x0000060503020100, 0x0000000605030201, 0x0000000605030200,
0x0000000006050302, 0x0000000605030100, 0x0000000006050301,
0x0000000006050300, 0x0000000000060503, 0x0000000605020100,
0x0000000006050201, 0x0000000006050200, 0x0000000000060502,
0x0000000006050100, 0x0000000000060501, 0x0000000000060500,
0x0000000000000605, 0x0000060403020100, 0x0000000604030201,
0x0000000604030200, 0x0000000006040302, 0x0000000604030100,
0x0000000006040301, 0x0000000006040300, 0x0000000000060403,
0x0000000604020100, 0x0000000006040201, 0x0000000006040200,
0x0000000000060402, 0x0000000006040100, 0x0000000000060401,
0x0000000000060400, 0x0000000000000604, 0x0000000603020100,
0x0000000006030201, 0x0000000006030200, 0x0000000000060302,
0x0000000006030100, 0x0000000000060301, 0x0000000000060300,
0x0000000000000603, 0x0000000006020100, 0x0000000000060201,
0x0000000000060200, 0x0000000000000602, 0x0000000000060100,
0x0000000000000601, 0x0000000000000600, 0x0000000000000006,
0x0000050403020100, 0x0000000504030201, 0x0000000504030200,
0x0000000005040302, 0x0000000504030100, 0x0000000005040301,
0x0000000005040300, 0x0000000000050403, 0x0000000504020100,
0x0000000005040201, 0x0000000005040200, 0x0000000000050402,
0x0000000005040100, 0x0000000000050401, 0x0000000000050400,
0x0000000000000504, 0x0000000503020100, 0x0000000005030201,
0x0000000005030200, 0x0000000000050302, 0x0000000005030100,
0x0000000000050301, 0x0000000000050300, 0x0000000000000503,
0x0000000005020100, 0x0000000000050201, 0x0000000000050200,
0x0000000000000502, 0x0000000000050100, 0x0000000000000501,
0x0000000000000500, 0x0000000000000005, 0x0000000403020100,
0x0000000004030201, 0x0000000004030200, 0x0000000000040302,
0x0000000004030100, 0x0000000000040301, 0x0000000000040300,
0x0000000000000403, 0x0000000004020100, 0x0000000000040201,
0x0000000000040200, 0x0000000000000402, 0x0000000000040100,
0x0000000000000401, 0x0000000000000400, 0x0000000000000004,
0x0000000003020100, 0x0000000000030201, 0x0000000000030200,
0x0000000000000302, 0x0000000000030100, 0x0000000000000301,
0x0000000000000300, 0x0000000000000003, 0x0000000000020100,
0x0000000000000201, 0x0000000000000200, 0x0000000000000002,
0x0000000000000100, 0x0000000000000001, 0x0000000000000000,
0x0000000000000000,
}; //static uint64_t thintable_epi8[256]
} // namespace internal
} // namespace simdjson
#endif // SIMDJSON_IMPLEMENTATION_ARM64 || SIMDJSON_IMPLEMENTATION_HASWELL || SIMDJSON_IMPLEMENTATION_WESTMERE || SIMDJSON_IMPLEMENTATION_PPC64
/* end file src/internal/simdprune_tables.cpp */
/* begin file src/implementation.cpp */
#include <initializer_list>
namespace simdjson {
bool implementation::supported_by_runtime_system() const {
uint32_t required_instruction_sets = this->required_instruction_sets();
uint32_t supported_instruction_sets = internal::detect_supported_architectures();
return ((supported_instruction_sets & required_instruction_sets) == required_instruction_sets);
}
namespace internal {
// Static array of known implementations. We're hoping these get baked into the executable
// without requiring a static initializer.
#if SIMDJSON_IMPLEMENTATION_HASWELL
const haswell::implementation haswell_singleton{};
#endif
#if SIMDJSON_IMPLEMENTATION_WESTMERE
const westmere::implementation westmere_singleton{};
#endif // SIMDJSON_IMPLEMENTATION_WESTMERE
#if SIMDJSON_IMPLEMENTATION_ARM64
const arm64::implementation arm64_singleton{};
#endif // SIMDJSON_IMPLEMENTATION_ARM64
#if SIMDJSON_IMPLEMENTATION_PPC64
const ppc64::implementation ppc64_singleton{};
#endif // SIMDJSON_IMPLEMENTATION_PPC64
#if SIMDJSON_IMPLEMENTATION_FALLBACK
const fallback::implementation fallback_singleton{};
#endif // SIMDJSON_IMPLEMENTATION_FALLBACK
/**
* @private Detects best supported implementation on first use, and sets it
*/
class detect_best_supported_implementation_on_first_use final : public implementation {
public:
const std::string &name() const noexcept final { return set_best()->name(); }
const std::string &description() const noexcept final { return set_best()->description(); }
uint32_t required_instruction_sets() const noexcept final { return set_best()->required_instruction_sets(); }
simdjson_warn_unused error_code create_dom_parser_implementation(
size_t capacity,
size_t max_length,
std::unique_ptr<internal::dom_parser_implementation>& dst
) const noexcept final {
return set_best()->create_dom_parser_implementation(capacity, max_length, dst);
}
simdjson_warn_unused error_code minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) const noexcept final {
return set_best()->minify(buf, len, dst, dst_len);
}
simdjson_warn_unused bool validate_utf8(const char * buf, size_t len) const noexcept final override {
return set_best()->validate_utf8(buf, len);
}
simdjson_really_inline detect_best_supported_implementation_on_first_use() noexcept : implementation("best_supported_detector", "Detects the best supported implementation and sets it", 0) {}
private:
const implementation *set_best() const noexcept;
};
const detect_best_supported_implementation_on_first_use detect_best_supported_implementation_on_first_use_singleton;
const std::initializer_list<const implementation *> available_implementation_pointers {
#if SIMDJSON_IMPLEMENTATION_HASWELL
&haswell_singleton,
#endif
#if SIMDJSON_IMPLEMENTATION_WESTMERE
&westmere_singleton,
#endif
#if SIMDJSON_IMPLEMENTATION_ARM64
&arm64_singleton,
#endif
#if SIMDJSON_IMPLEMENTATION_PPC64
&ppc64_singleton,
#endif
#if SIMDJSON_IMPLEMENTATION_FALLBACK
&fallback_singleton,
#endif
}; // available_implementation_pointers
// So we can return UNSUPPORTED_ARCHITECTURE from the parser when there is no support
class unsupported_implementation final : public implementation {
public:
simdjson_warn_unused error_code create_dom_parser_implementation(
size_t,
size_t,
std::unique_ptr<internal::dom_parser_implementation>&
) const noexcept final {
return UNSUPPORTED_ARCHITECTURE;
}
simdjson_warn_unused error_code minify(const uint8_t *, size_t, uint8_t *, size_t &) const noexcept final override {
return UNSUPPORTED_ARCHITECTURE;
}
simdjson_warn_unused bool validate_utf8(const char *, size_t) const noexcept final override {
return false; // Just refuse to validate. Given that we have a fallback implementation
// it seems unlikely that unsupported_implementation will ever be used. If it is used,
// then it will flag all strings as invalid. The alternative is to return an error_code
// from which the user has to figure out whether the string is valid UTF-8... which seems
// like a lot of work just to handle the very unlikely case that we have an unsupported
// implementation. And, when it does happen (that we have an unsupported implementation),
// what are the chances that the programmer has a fallback? Given that *we* provide the
// fallback, it implies that the programmer would need a fallback for our fallback.
}
unsupported_implementation() : implementation("unsupported", "Unsupported CPU (no detected SIMD instructions)", 0) {}
};
const unsupported_implementation unsupported_singleton{};
size_t available_implementation_list::size() const noexcept {
return internal::available_implementation_pointers.size();
}
const implementation * const *available_implementation_list::begin() const noexcept {
return internal::available_implementation_pointers.begin();
}
const implementation * const *available_implementation_list::end() const noexcept {
return internal::available_implementation_pointers.end();
}
const implementation *available_implementation_list::detect_best_supported() const noexcept {
// They are prelisted in priority order, so we just go down the list
uint32_t supported_instruction_sets = internal::detect_supported_architectures();
for (const implementation *impl : internal::available_implementation_pointers) {
uint32_t required_instruction_sets = impl->required_instruction_sets();
if ((supported_instruction_sets & required_instruction_sets) == required_instruction_sets) { return impl; }
}
return &unsupported_singleton; // this should never happen?
}
const implementation *detect_best_supported_implementation_on_first_use::set_best() const noexcept {
SIMDJSON_PUSH_DISABLE_WARNINGS
SIMDJSON_DISABLE_DEPRECATED_WARNING // Disable CRT_SECURE warning on MSVC: manually verified this is safe
char *force_implementation_name = getenv("SIMDJSON_FORCE_IMPLEMENTATION");
SIMDJSON_POP_DISABLE_WARNINGS
if (force_implementation_name) {
auto force_implementation = available_implementations[force_implementation_name];
if (force_implementation) {
return active_implementation = force_implementation;
} else {
// Note: abort() and stderr usage within the library is forbidden.
return active_implementation = &unsupported_singleton;
}
}
return active_implementation = available_implementations.detect_best_supported();
}
} // namespace internal
SIMDJSON_DLLIMPORTEXPORT const internal::available_implementation_list available_implementations{};
SIMDJSON_DLLIMPORTEXPORT internal::atomic_ptr<const implementation> active_implementation{&internal::detect_best_supported_implementation_on_first_use_singleton};
simdjson_warn_unused error_code minify(const char *buf, size_t len, char *dst, size_t &dst_len) noexcept {
return active_implementation->minify((const uint8_t *)buf, len, (uint8_t *)dst, dst_len);
}
simdjson_warn_unused bool validate_utf8(const char *buf, size_t len) noexcept {
return active_implementation->validate_utf8(buf, len);
}
const implementation * builtin_implementation() {
static const implementation * builtin_impl = available_implementations[STRINGIFY(SIMDJSON_BUILTIN_IMPLEMENTATION)];
return builtin_impl;
}
} // namespace simdjson
/* end file src/implementation.cpp */
#if SIMDJSON_IMPLEMENTATION_ARM64
/* begin file src/arm64/implementation.cpp */
/* begin file include/simdjson/arm64/begin.h */
// redefining SIMDJSON_IMPLEMENTATION to "arm64"
// #define SIMDJSON_IMPLEMENTATION arm64
/* end file include/simdjson/arm64/begin.h */
namespace simdjson {
namespace arm64 {
simdjson_warn_unused error_code implementation::create_dom_parser_implementation(
size_t capacity,
size_t max_depth,
std::unique_ptr<internal::dom_parser_implementation>& dst
) const noexcept {
dst.reset( new (std::nothrow) dom_parser_implementation() );
if (!dst) { return MEMALLOC; }
dst->set_capacity(capacity);
dst->set_max_depth(max_depth);
return SUCCESS;
}
} // namespace arm64
} // namespace simdjson
/* begin file include/simdjson/arm64/end.h */
#undef arm64
/* end file include/simdjson/arm64/end.h */
/* end file src/arm64/implementation.cpp */
/* begin file src/arm64/dom_parser_implementation.cpp */
/* begin file include/simdjson/arm64/begin.h */
// redefining SIMDJSON_IMPLEMENTATION to "arm64"
// #define SIMDJSON_IMPLEMENTATION arm64
/* end file include/simdjson/arm64/begin.h */
//
// Stage 1
//
namespace simdjson {
namespace arm64 {
namespace {
using namespace simd;
struct json_character_block {
static simdjson_really_inline json_character_block classify(const simd::simd8x64<uint8_t>& in);
simdjson_really_inline uint64_t whitespace() const { return _whitespace; }
simdjson_really_inline uint64_t op() const { return _op; }
simdjson_really_inline uint64_t scalar() { return ~(op() | whitespace()); }
uint64_t _whitespace;
uint64_t _op;
};
simdjson_really_inline json_character_block json_character_block::classify(const simd::simd8x64<uint8_t>& in) {
// Functional programming causes trouble with Visual Studio.
// Keeping this version in comments since it is much nicer:
// auto v = in.map<uint8_t>([&](simd8<uint8_t> chunk) {
// auto nib_lo = chunk & 0xf;
// auto nib_hi = chunk.shr<4>();
// auto shuf_lo = nib_lo.lookup_16<uint8_t>(16, 0, 0, 0, 0, 0, 0, 0, 0, 8, 12, 1, 2, 9, 0, 0);
// auto shuf_hi = nib_hi.lookup_16<uint8_t>(8, 0, 18, 4, 0, 1, 0, 1, 0, 0, 0, 3, 2, 1, 0, 0);
// return shuf_lo & shuf_hi;
// });
const simd8<uint8_t> table1(16, 0, 0, 0, 0, 0, 0, 0, 0, 8, 12, 1, 2, 9, 0, 0);
const simd8<uint8_t> table2(8, 0, 18, 4, 0, 1, 0, 1, 0, 0, 0, 3, 2, 1, 0, 0);
simd8x64<uint8_t> v(
(in.chunks[0] & 0xf).lookup_16(table1) & (in.chunks[0].shr<4>()).lookup_16(table2),
(in.chunks[1] & 0xf).lookup_16(table1) & (in.chunks[1].shr<4>()).lookup_16(table2),
(in.chunks[2] & 0xf).lookup_16(table1) & (in.chunks[2].shr<4>()).lookup_16(table2),
(in.chunks[3] & 0xf).lookup_16(table1) & (in.chunks[3].shr<4>()).lookup_16(table2)
);
// We compute whitespace and op separately. If the code later only use one or the
// other, given the fact that all functions are aggressively inlined, we can
// hope that useless computations will be omitted. This is namely case when
// minifying (we only need whitespace). *However* if we only need spaces,
// it is likely that we will still compute 'v' above with two lookup_16: one
// could do it a bit cheaper. This is in contrast with the x64 implementations
// where we can, efficiently, do the white space and structural matching
// separately. One reason for this difference is that on ARM NEON, the table
// lookups either zero or leave unchanged the characters exceeding 0xF whereas
// on x64, the equivalent instruction (pshufb) automatically applies a mask,
// ignoring the 4 most significant bits. Thus the x64 implementation is
// optimized differently. This being said, if you use this code strictly
// just for minification (or just to identify the structural characters),
// there is a small untaken optimization opportunity here. We deliberately
// do not pick it up.
uint64_t op = simd8x64<bool>(
v.chunks[0].any_bits_set(0x7),
v.chunks[1].any_bits_set(0x7),
v.chunks[2].any_bits_set(0x7),
v.chunks[3].any_bits_set(0x7)
).to_bitmask();
uint64_t whitespace = simd8x64<bool>(
v.chunks[0].any_bits_set(0x18),
v.chunks[1].any_bits_set(0x18),
v.chunks[2].any_bits_set(0x18),
v.chunks[3].any_bits_set(0x18)
).to_bitmask();
return { whitespace, op };
}
simdjson_really_inline bool is_ascii(const simd8x64<uint8_t>& input) {
simd8<uint8_t> bits = input.reduce_or();
return bits.max_val() < 0b10000000u;
}
simdjson_unused simdjson_really_inline simd8<bool> must_be_continuation(const simd8<uint8_t> prev1, const simd8<uint8_t> prev2, const simd8<uint8_t> prev3) {
simd8<bool> is_second_byte = prev1 >= uint8_t(0b11000000u);
simd8<bool> is_third_byte = prev2 >= uint8_t(0b11100000u);
simd8<bool> is_fourth_byte = prev3 >= uint8_t(0b11110000u);
// Use ^ instead of | for is_*_byte, because ^ is commutative, and the caller is using ^ as well.
// This will work fine because we only have to report errors for cases with 0-1 lead bytes.
// Multiple lead bytes implies 2 overlapping multibyte characters, and if that happens, there is
// guaranteed to be at least *one* lead byte that is part of only 1 other multibyte character.
// The error will be detected there.
return is_second_byte ^ is_third_byte ^ is_fourth_byte;
}
simdjson_really_inline simd8<bool> must_be_2_3_continuation(const simd8<uint8_t> prev2, const simd8<uint8_t> prev3) {
simd8<bool> is_third_byte = prev2 >= uint8_t(0b11100000u);
simd8<bool> is_fourth_byte = prev3 >= uint8_t(0b11110000u);
return is_third_byte ^ is_fourth_byte;
}
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* begin file src/generic/stage1/utf8_lookup4_algorithm.h */
namespace simdjson {
namespace arm64 {
namespace {
namespace utf8_validation {
using namespace simd;
simdjson_really_inline simd8<uint8_t> check_special_cases(const simd8<uint8_t> input, const simd8<uint8_t> prev1) {
// Bit 0 = Too Short (lead byte/ASCII followed by lead byte/ASCII)
// Bit 1 = Too Long (ASCII followed by continuation)
// Bit 2 = Overlong 3-byte
// Bit 4 = Surrogate
// Bit 5 = Overlong 2-byte
// Bit 7 = Two Continuations
constexpr const uint8_t TOO_SHORT = 1<<0; // 11______ 0_______
// 11______ 11______
constexpr const uint8_t TOO_LONG = 1<<1; // 0_______ 10______
constexpr const uint8_t OVERLONG_3 = 1<<2; // 11100000 100_____
constexpr const uint8_t SURROGATE = 1<<4; // 11101101 101_____
constexpr const uint8_t OVERLONG_2 = 1<<5; // 1100000_ 10______
constexpr const uint8_t TWO_CONTS = 1<<7; // 10______ 10______
constexpr const uint8_t TOO_LARGE = 1<<3; // 11110100 1001____
// 11110100 101_____
// 11110101 1001____
// 11110101 101_____
// 1111011_ 1001____
// 1111011_ 101_____
// 11111___ 1001____
// 11111___ 101_____
constexpr const uint8_t TOO_LARGE_1000 = 1<<6;
// 11110101 1000____
// 1111011_ 1000____
// 11111___ 1000____
constexpr const uint8_t OVERLONG_4 = 1<<6; // 11110000 1000____
const simd8<uint8_t> byte_1_high = prev1.shr<4>().lookup_16<uint8_t>(
// 0_______ ________ <ASCII in byte 1>
TOO_LONG, TOO_LONG, TOO_LONG, TOO_LONG,
TOO_LONG, TOO_LONG, TOO_LONG, TOO_LONG,
// 10______ ________ <continuation in byte 1>
TWO_CONTS, TWO_CONTS, TWO_CONTS, TWO_CONTS,
// 1100____ ________ <two byte lead in byte 1>
TOO_SHORT | OVERLONG_2,
// 1101____ ________ <two byte lead in byte 1>
TOO_SHORT,
// 1110____ ________ <three byte lead in byte 1>
TOO_SHORT | OVERLONG_3 | SURROGATE,
// 1111____ ________ <four+ byte lead in byte 1>
TOO_SHORT | TOO_LARGE | TOO_LARGE_1000 | OVERLONG_4
);
constexpr const uint8_t CARRY = TOO_SHORT | TOO_LONG | TWO_CONTS; // These all have ____ in byte 1 .
const simd8<uint8_t> byte_1_low = (prev1 & 0x0F).lookup_16<uint8_t>(
// ____0000 ________
CARRY | OVERLONG_3 | OVERLONG_2 | OVERLONG_4,
// ____0001 ________
CARRY | OVERLONG_2,
// ____001_ ________
CARRY,
CARRY,
// ____0100 ________
CARRY | TOO_LARGE,
// ____0101 ________
CARRY | TOO_LARGE | TOO_LARGE_1000,
// ____011_ ________
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
// ____1___ ________
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
// ____1101 ________
CARRY | TOO_LARGE | TOO_LARGE_1000 | SURROGATE,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000
);
const simd8<uint8_t> byte_2_high = input.shr<4>().lookup_16<uint8_t>(
// ________ 0_______ <ASCII in byte 2>
TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT,
TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT,
// ________ 1000____
TOO_LONG | OVERLONG_2 | TWO_CONTS | OVERLONG_3 | TOO_LARGE_1000 | OVERLONG_4,
// ________ 1001____
TOO_LONG | OVERLONG_2 | TWO_CONTS | OVERLONG_3 | TOO_LARGE,
// ________ 101_____
TOO_LONG | OVERLONG_2 | TWO_CONTS | SURROGATE | TOO_LARGE,
TOO_LONG | OVERLONG_2 | TWO_CONTS | SURROGATE | TOO_LARGE,
// ________ 11______
TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT
);
return (byte_1_high & byte_1_low & byte_2_high);
}
simdjson_really_inline simd8<uint8_t> check_multibyte_lengths(const simd8<uint8_t> input,
const simd8<uint8_t> prev_input, const simd8<uint8_t> sc) {
simd8<uint8_t> prev2 = input.prev<2>(prev_input);
simd8<uint8_t> prev3 = input.prev<3>(prev_input);
simd8<uint8_t> must23 = simd8<uint8_t>(must_be_2_3_continuation(prev2, prev3));
simd8<uint8_t> must23_80 = must23 & uint8_t(0x80);
return must23_80 ^ sc;
}
//
// Return nonzero if there are incomplete multibyte characters at the end of the block:
// e.g. if there is a 4-byte character, but it's 3 bytes from the end.
//
simdjson_really_inline simd8<uint8_t> is_incomplete(const simd8<uint8_t> input) {
// If the previous input's last 3 bytes match this, they're too short (they ended at EOF):
// ... 1111____ 111_____ 11______
static const uint8_t max_array[32] = {
255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 0b11110000u-1, 0b11100000u-1, 0b11000000u-1
};
const simd8<uint8_t> max_value(&max_array[sizeof(max_array)-sizeof(simd8<uint8_t>)]);
return input.gt_bits(max_value);
}
struct utf8_checker {
// If this is nonzero, there has been a UTF-8 error.
simd8<uint8_t> error;
// The last input we received
simd8<uint8_t> prev_input_block;
// Whether the last input we received was incomplete (used for ASCII fast path)
simd8<uint8_t> prev_incomplete;
//
// Check whether the current bytes are valid UTF-8.
//
simdjson_really_inline void check_utf8_bytes(const simd8<uint8_t> input, const simd8<uint8_t> prev_input) {
// Flip prev1...prev3 so we can easily determine if they are 2+, 3+ or 4+ lead bytes
// (2, 3, 4-byte leads become large positive numbers instead of small negative numbers)
simd8<uint8_t> prev1 = input.prev<1>(prev_input);
simd8<uint8_t> sc = check_special_cases(input, prev1);
this->error |= check_multibyte_lengths(input, prev_input, sc);
}
// The only problem that can happen at EOF is that a multibyte character is too short
// or a byte value too large in the last bytes: check_special_cases only checks for bytes
// too large in the first of two bytes.
simdjson_really_inline void check_eof() {
// If the previous block had incomplete UTF-8 characters at the end, an ASCII block can't
// possibly finish them.
this->error |= this->prev_incomplete;
}
simdjson_really_inline void check_next_input(const simd8x64<uint8_t>& input) {
if(simdjson_likely(is_ascii(input))) {
this->error |= this->prev_incomplete;
} else {
// you might think that a for-loop would work, but under Visual Studio, it is not good enough.
static_assert((simd8x64<uint8_t>::NUM_CHUNKS == 2) || (simd8x64<uint8_t>::NUM_CHUNKS == 4),
"We support either two or four chunks per 64-byte block.");
if(simd8x64<uint8_t>::NUM_CHUNKS == 2) {
this->check_utf8_bytes(input.chunks[0], this->prev_input_block);
this->check_utf8_bytes(input.chunks[1], input.chunks[0]);
} else if(simd8x64<uint8_t>::NUM_CHUNKS == 4) {
this->check_utf8_bytes(input.chunks[0], this->prev_input_block);
this->check_utf8_bytes(input.chunks[1], input.chunks[0]);
this->check_utf8_bytes(input.chunks[2], input.chunks[1]);
this->check_utf8_bytes(input.chunks[3], input.chunks[2]);
}
this->prev_incomplete = is_incomplete(input.chunks[simd8x64<uint8_t>::NUM_CHUNKS-1]);
this->prev_input_block = input.chunks[simd8x64<uint8_t>::NUM_CHUNKS-1];
}
}
// do not forget to call check_eof!
simdjson_really_inline error_code errors() {
return this->error.any_bits_set_anywhere() ? error_code::UTF8_ERROR : error_code::SUCCESS;
}
}; // struct utf8_checker
} // namespace utf8_validation
using utf8_validation::utf8_checker;
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* end file src/generic/stage1/utf8_lookup4_algorithm.h */
/* begin file src/generic/stage1/json_structural_indexer.h */
// This file contains the common code every implementation uses in stage1
// It is intended to be included multiple times and compiled multiple times
// We assume the file in which it is included already includes
// "simdjson/stage1.h" (this simplifies amalgation)
/* begin file src/generic/stage1/buf_block_reader.h */
namespace simdjson {
namespace arm64 {
namespace {
// Walks through a buffer in block-sized increments, loading the last part with spaces
template<size_t STEP_SIZE>
struct buf_block_reader {
public:
simdjson_really_inline buf_block_reader(const uint8_t *_buf, size_t _len);
simdjson_really_inline size_t block_index();
simdjson_really_inline bool has_full_block() const;
simdjson_really_inline const uint8_t *full_block() const;
/**
* Get the last block, padded with spaces.
*
* There will always be a last block, with at least 1 byte, unless len == 0 (in which case this
* function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there
* will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding.
*
* @return the number of effective characters in the last block.
*/
simdjson_really_inline size_t get_remainder(uint8_t *dst) const;
simdjson_really_inline void advance();
private:
const uint8_t *buf;
const size_t len;
const size_t lenminusstep;
size_t idx;
};
// Routines to print masks and text for debugging bitmask operations
simdjson_unused static char * format_input_text_64(const uint8_t *text) {
static char *buf = (char*)malloc(sizeof(simd8x64<uint8_t>) + 1);
for (size_t i=0; i<sizeof(simd8x64<uint8_t>); i++) {
buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]);
}
buf[sizeof(simd8x64<uint8_t>)] = '\0';
return buf;
}
// Routines to print masks and text for debugging bitmask operations
simdjson_unused static char * format_input_text(const simd8x64<uint8_t>& in) {
static char *buf = (char*)malloc(sizeof(simd8x64<uint8_t>) + 1);
in.store((uint8_t*)buf);
for (size_t i=0; i<sizeof(simd8x64<uint8_t>); i++) {
if (buf[i] < ' ') { buf[i] = '_'; }
}
buf[sizeof(simd8x64<uint8_t>)] = '\0';
return buf;
}
simdjson_unused static char * format_mask(uint64_t mask) {
static char *buf = (char*)malloc(64 + 1);
for (size_t i=0; i<64; i++) {
buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' ';
}
buf[64] = '\0';
return buf;
}
template<size_t STEP_SIZE>
simdjson_really_inline buf_block_reader<STEP_SIZE>::buf_block_reader(const uint8_t *_buf, size_t _len) : buf{_buf}, len{_len}, lenminusstep{len < STEP_SIZE ? 0 : len - STEP_SIZE}, idx{0} {}
template<size_t STEP_SIZE>
simdjson_really_inline size_t buf_block_reader<STEP_SIZE>::block_index() { return idx; }
template<size_t STEP_SIZE>
simdjson_really_inline bool buf_block_reader<STEP_SIZE>::has_full_block() const {
return idx < lenminusstep;
}
template<size_t STEP_SIZE>
simdjson_really_inline const uint8_t *buf_block_reader<STEP_SIZE>::full_block() const {
return &buf[idx];
}
template<size_t STEP_SIZE>
simdjson_really_inline size_t buf_block_reader<STEP_SIZE>::get_remainder(uint8_t *dst) const {
if(len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers
std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once.
std::memcpy(dst, buf + idx, len - idx);
return len - idx;
}
template<size_t STEP_SIZE>
simdjson_really_inline void buf_block_reader<STEP_SIZE>::advance() {
idx += STEP_SIZE;
}
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* end file src/generic/stage1/buf_block_reader.h */
/* begin file src/generic/stage1/json_string_scanner.h */
namespace simdjson {
namespace arm64 {
namespace {
namespace stage1 {
struct json_string_block {
// Escaped characters (characters following an escape() character)
simdjson_really_inline uint64_t escaped() const { return _escaped; }
// Escape characters (backslashes that are not escaped--i.e. in \\, includes only the first \)
simdjson_really_inline uint64_t escape() const { return _backslash & ~_escaped; }
// Real (non-backslashed) quotes
simdjson_really_inline uint64_t quote() const { return _quote; }
// Start quotes of strings
simdjson_really_inline uint64_t string_start() const { return _quote & _in_string; }
// End quotes of strings
simdjson_really_inline uint64_t string_end() const { return _quote & ~_in_string; }
// Only characters inside the string (not including the quotes)
simdjson_really_inline uint64_t string_content() const { return _in_string & ~_quote; }
// Return a mask of whether the given characters are inside a string (only works on non-quotes)
simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; }
// Return a mask of whether the given characters are inside a string (only works on non-quotes)
simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; }
// Tail of string (everything except the start quote)
simdjson_really_inline uint64_t string_tail() const { return _in_string ^ _quote; }
// backslash characters
uint64_t _backslash;
// escaped characters (backslashed--does not include the hex characters after \u)
uint64_t _escaped;
// real quotes (non-backslashed ones)
uint64_t _quote;
// string characters (includes start quote but not end quote)
uint64_t _in_string;
};
// Scans blocks for string characters, storing the state necessary to do so
class json_string_scanner {
public:
simdjson_really_inline json_string_block next(const simd::simd8x64<uint8_t>& in);
// Returns either UNCLOSED_STRING or SUCCESS
simdjson_really_inline error_code finish();
private:
// Intended to be defined by the implementation
simdjson_really_inline uint64_t find_escaped(uint64_t escape);
simdjson_really_inline uint64_t find_escaped_branchless(uint64_t escape);
// Whether the last iteration was still inside a string (all 1's = true, all 0's = false).
uint64_t prev_in_string = 0ULL;
// Whether the first character of the next iteration is escaped.
uint64_t prev_escaped = 0ULL;
};
//
// Finds escaped characters (characters following \).
//
// Handles runs of backslashes like \\\" and \\\\" correctly (yielding 0101 and 01010, respectively).
//
// Does this by:
// - Shift the escape mask to get potentially escaped characters (characters after backslashes).
// - Mask escaped sequences that start on *even* bits with 1010101010 (odd bits are escaped, even bits are not)
// - Mask escaped sequences that start on *odd* bits with 0101010101 (even bits are escaped, odd bits are not)
//
// To distinguish between escaped sequences starting on even/odd bits, it finds the start of all
// escape sequences, filters out the ones that start on even bits, and adds that to the mask of
// escape sequences. This causes the addition to clear out the sequences starting on odd bits (since
// the start bit causes a carry), and leaves even-bit sequences alone.
//
// Example:
//
// text | \\\ | \\\"\\\" \\\" \\"\\" |
// escape | xxx | xx xxx xxx xx xx | Removed overflow backslash; will | it into follows_escape
// odd_starts | x | x x x | escape & ~even_bits & ~follows_escape
// even_seq | c| cxxx c xx c | c = carry bit -- will be masked out later
// invert_mask | | cxxx c xx c| even_seq << 1
// follows_escape | xx | x xx xxx xxx xx xx | Includes overflow bit
// escaped | x | x x x x x x x x |
// desired | x | x x x x x x x x |
// text | \\\ | \\\"\\\" \\\" \\"\\" |
//
simdjson_really_inline uint64_t json_string_scanner::find_escaped_branchless(uint64_t backslash) {
// If there was overflow, pretend the first character isn't a backslash
backslash &= ~prev_escaped;
uint64_t follows_escape = backslash << 1 | prev_escaped;
// Get sequences starting on even bits by clearing out the odd series using +
const uint64_t even_bits = 0x5555555555555555ULL;
uint64_t odd_sequence_starts = backslash & ~even_bits & ~follows_escape;
uint64_t sequences_starting_on_even_bits;
prev_escaped = add_overflow(odd_sequence_starts, backslash, &sequences_starting_on_even_bits);
uint64_t invert_mask = sequences_starting_on_even_bits << 1; // The mask we want to return is the *escaped* bits, not escapes.
// Mask every other backslashed character as an escaped character
// Flip the mask for sequences that start on even bits, to correct them
return (even_bits ^ invert_mask) & follows_escape;
}
//
// Return a mask of all string characters plus end quotes.
//
// prev_escaped is overflow saying whether the next character is escaped.
// prev_in_string is overflow saying whether we're still in a string.
//
// Backslash sequences outside of quotes will be detected in stage 2.
//
simdjson_really_inline json_string_block json_string_scanner::next(const simd::simd8x64<uint8_t>& in) {
const uint64_t backslash = in.eq('\\');
const uint64_t escaped = find_escaped(backslash);
const uint64_t quote = in.eq('"') & ~escaped;
//
// prefix_xor flips on bits inside the string (and flips off the end quote).
//
// Then we xor with prev_in_string: if we were in a string already, its effect is flipped
// (characters inside strings are outside, and characters outside strings are inside).
//
const uint64_t in_string = prefix_xor(quote) ^ prev_in_string;
//
// Check if we're still in a string at the end of the box so the next block will know
//
// right shift of a signed value expected to be well-defined and standard
// compliant as of C++20, John Regher from Utah U. says this is fine code
//
prev_in_string = uint64_t(static_cast<int64_t>(in_string) >> 63);
// Use ^ to turn the beginning quote off, and the end quote on.
return {
backslash,
escaped,
quote,
in_string
};
}
simdjson_really_inline error_code json_string_scanner::finish() {
if (prev_in_string) {
return UNCLOSED_STRING;
}
return SUCCESS;
}
} // namespace stage1
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* end file src/generic/stage1/json_string_scanner.h */
/* begin file src/generic/stage1/json_scanner.h */
namespace simdjson {
namespace arm64 {
namespace {
namespace stage1 {
/**
* A block of scanned json, with information on operators and scalars.
*
* We seek to identify pseudo-structural characters. Anything that is inside
* a string must be omitted (hence & ~_string.string_tail()).
* Otherwise, pseudo-structural characters come in two forms.
* 1. We have the structural characters ([,],{,},:, comma). The
* term 'structural character' is from the JSON RFC.
* 2. We have the 'scalar pseudo-structural characters'.
* Scalars are quotes, and any character except structural characters and white space.
*
* To identify the scalar pseudo-structural characters, we must look at what comes
* before them: it must be a space, a quote or a structural characters.
* Starting with simdjson v0.3, we identify them by
* negation: we identify everything that is followed by a non-quote scalar,
* and we negate that. Whatever remains must be a 'scalar pseudo-structural character'.
*/
struct json_block {
public:
/**
* The start of structurals.
* In simdjson prior to v0.3, these were called the pseudo-structural characters.
**/
simdjson_really_inline uint64_t structural_start() { return potential_structural_start() & ~_string.string_tail(); }
/** All JSON whitespace (i.e. not in a string) */
simdjson_really_inline uint64_t whitespace() { return non_quote_outside_string(_characters.whitespace()); }
// Helpers
/** Whether the given characters are inside a string (only works on non-quotes) */
simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) { return _string.non_quote_inside_string(mask); }
/** Whether the given characters are outside a string (only works on non-quotes) */
simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) { return _string.non_quote_outside_string(mask); }
// string and escape characters
json_string_block _string;
// whitespace, structural characters ('operators'), scalars
json_character_block _characters;
// whether the previous character was a scalar
uint64_t _follows_potential_nonquote_scalar;
private:
// Potential structurals (i.e. disregarding strings)
/**
* structural elements ([,],{,},:, comma) plus scalar starts like 123, true and "abc".
* They may reside inside a string.
**/
simdjson_really_inline uint64_t potential_structural_start() { return _characters.op() | potential_scalar_start(); }
/**
* The start of non-operator runs, like 123, true and "abc".
* It main reside inside a string.
**/
simdjson_really_inline uint64_t potential_scalar_start() {
// The term "scalar" refers to anything except structural characters and white space
// (so letters, numbers, quotes).
// Whenever it is preceded by something that is not a structural element ({,},[,],:, ") nor a white-space
// then we know that it is irrelevant structurally.
return _characters.scalar() & ~follows_potential_scalar();
}
/**
* Whether the given character is immediately after a non-operator like 123, true.
* The characters following a quote are not included.
*/
simdjson_really_inline uint64_t follows_potential_scalar() {
// _follows_potential_nonquote_scalar: is defined as marking any character that follows a character
// that is not a structural element ({,},[,],:, comma) nor a quote (") and that is not a
// white space.
// It is understood that within quoted region, anything at all could be marked (irrelevant).
return _follows_potential_nonquote_scalar;
}
};
/**
* Scans JSON for important bits: structural characters or 'operators', strings, and scalars.
*
* The scanner starts by calculating two distinct things:
* - string characters (taking \" into account)
* - structural characters or 'operators' ([]{},:, comma)
* and scalars (runs of non-operators like 123, true and "abc")
*
* To minimize data dependency (a key component of the scanner's speed), it finds these in parallel:
* in particular, the operator/scalar bit will find plenty of things that are actually part of
* strings. When we're done, json_block will fuse the two together by masking out tokens that are
* part of a string.
*/
class json_scanner {
public:
json_scanner() {}
simdjson_really_inline json_block next(const simd::simd8x64<uint8_t>& in);
// Returns either UNCLOSED_STRING or SUCCESS
simdjson_really_inline error_code finish();
private:
// Whether the last character of the previous iteration is part of a scalar token
// (anything except whitespace or a structural character/'operator').
uint64_t prev_scalar = 0ULL;
json_string_scanner string_scanner{};
};
//
// Check if the current character immediately follows a matching character.
//
// For example, this checks for quotes with backslashes in front of them:
//
// const uint64_t backslashed_quote = in.eq('"') & immediately_follows(in.eq('\'), prev_backslash);
//
simdjson_really_inline uint64_t follows(const uint64_t match, uint64_t &overflow) {
const uint64_t result = match << 1 | overflow;
overflow = match >> 63;
return result;
}
simdjson_really_inline json_block json_scanner::next(const simd::simd8x64<uint8_t>& in) {
json_string_block strings = string_scanner.next(in);
// identifies the white-space and the structurat characters
json_character_block characters = json_character_block::classify(in);
// The term "scalar" refers to anything except structural characters and white space
// (so letters, numbers, quotes).
// We want follows_scalar to mark anything that follows a non-quote scalar (so letters and numbers).
//
// A terminal quote should either be followed by a structural character (comma, brace, bracket, colon)
// or nothing. However, we still want ' "a string"true ' to mark the 't' of 'true' as a potential
// pseudo-structural character just like we would if we had ' "a string" true '; otherwise we
// may need to add an extra check when parsing strings.
//
// Performance: there are many ways to skin this cat.
const uint64_t nonquote_scalar = characters.scalar() & ~strings.quote();
uint64_t follows_nonquote_scalar = follows(nonquote_scalar, prev_scalar);
return {
strings,
characters,
follows_nonquote_scalar
};
}
simdjson_really_inline error_code json_scanner::finish() {
return string_scanner.finish();
}
} // namespace stage1
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* end file src/generic/stage1/json_scanner.h */
/* begin file src/generic/stage1/json_minifier.h */
// This file contains the common code every implementation uses in stage1
// It is intended to be included multiple times and compiled multiple times
// We assume the file in which it is included already includes
// "simdjson/stage1.h" (this simplifies amalgation)
namespace simdjson {
namespace arm64 {
namespace {
namespace stage1 {
class json_minifier {
public:
template<size_t STEP_SIZE>
static error_code minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) noexcept;
private:
simdjson_really_inline json_minifier(uint8_t *_dst)
: dst{_dst}
{}
template<size_t STEP_SIZE>
simdjson_really_inline void step(const uint8_t *block_buf, buf_block_reader<STEP_SIZE> &reader) noexcept;
simdjson_really_inline void next(const simd::simd8x64<uint8_t>& in, json_block block);
simdjson_really_inline error_code finish(uint8_t *dst_start, size_t &dst_len);
json_scanner scanner{};
uint8_t *dst;
};
simdjson_really_inline void json_minifier::next(const simd::simd8x64<uint8_t>& in, json_block block) {
uint64_t mask = block.whitespace();
in.compress(mask, dst);
dst += 64 - count_ones(mask);
}
simdjson_really_inline error_code json_minifier::finish(uint8_t *dst_start, size_t &dst_len) {
error_code error = scanner.finish();
if (error) { dst_len = 0; return error; }
dst_len = dst - dst_start;
return SUCCESS;
}
template<>
simdjson_really_inline void json_minifier::step<128>(const uint8_t *block_buf, buf_block_reader<128> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block_buf);
simd::simd8x64<uint8_t> in_2(block_buf+64);
json_block block_1 = scanner.next(in_1);
json_block block_2 = scanner.next(in_2);
this->next(in_1, block_1);
this->next(in_2, block_2);
reader.advance();
}
template<>
simdjson_really_inline void json_minifier::step<64>(const uint8_t *block_buf, buf_block_reader<64> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block_buf);
json_block block_1 = scanner.next(in_1);
this->next(block_buf, block_1);
reader.advance();
}
template<size_t STEP_SIZE>
error_code json_minifier::minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) noexcept {
buf_block_reader<STEP_SIZE> reader(buf, len);
json_minifier minifier(dst);
// Index the first n-1 blocks
while (reader.has_full_block()) {
minifier.step<STEP_SIZE>(reader.full_block(), reader);
}
// Index the last (remainder) block, padded with spaces
uint8_t block[STEP_SIZE];
size_t remaining_bytes = reader.get_remainder(block);
if (remaining_bytes > 0) {
// We do not want to write directly to the output stream. Rather, we write
// to a local buffer (for safety).
uint8_t out_block[STEP_SIZE];
uint8_t * const guarded_dst{minifier.dst};
minifier.dst = out_block;
minifier.step<STEP_SIZE>(block, reader);
size_t to_write = minifier.dst - out_block;
// In some cases, we could be enticed to consider the padded spaces
// as part of the string. This is fine as long as we do not write more
// than we consumed.
if(to_write > remaining_bytes) { to_write = remaining_bytes; }
memcpy(guarded_dst, out_block, to_write);
minifier.dst = guarded_dst + to_write;
}
return minifier.finish(dst, dst_len);
}
} // namespace stage1
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* end file src/generic/stage1/json_minifier.h */
/* begin file src/generic/stage1/find_next_document_index.h */
namespace simdjson {
namespace arm64 {
namespace {
/**
* This algorithm is used to quickly identify the last structural position that
* makes up a complete document.
*
* It does this by going backwards and finding the last *document boundary* (a
* place where one value follows another without a comma between them). If the
* last document (the characters after the boundary) has an equal number of
* start and end brackets, it is considered complete.
*
* Simply put, we iterate over the structural characters, starting from
* the end. We consider that we found the end of a JSON document when the
* first element of the pair is NOT one of these characters: '{' '[' ';' ','
* and when the second element is NOT one of these characters: '}' '}' ';' ','.
*
* This simple comparison works most of the time, but it does not cover cases
* where the batch's structural indexes contain a perfect amount of documents.
* In such a case, we do not have access to the structural index which follows
* the last document, therefore, we do not have access to the second element in
* the pair, and that means we cannot identify the last document. To fix this
* issue, we keep a count of the open and closed curly/square braces we found
* while searching for the pair. When we find a pair AND the count of open and
* closed curly/square braces is the same, we know that we just passed a
* complete document, therefore the last json buffer location is the end of the
* batch.
*/
simdjson_really_inline uint32_t find_next_document_index(dom_parser_implementation &parser) {
// TODO don't count separately, just figure out depth
auto arr_cnt = 0;
auto obj_cnt = 0;
for (auto i = parser.n_structural_indexes - 1; i > 0; i--) {
auto idxb = parser.structural_indexes[i];
switch (parser.buf[idxb]) {
case ':':
case ',':
continue;
case '}':
obj_cnt--;
continue;
case ']':
arr_cnt--;
continue;
case '{':
obj_cnt++;
break;
case '[':
arr_cnt++;
break;
}
auto idxa = parser.structural_indexes[i - 1];
switch (parser.buf[idxa]) {
case '{':
case '[':
case ':':
case ',':
continue;
}
// Last document is complete, so the next document will appear after!
if (!arr_cnt && !obj_cnt) {
return parser.n_structural_indexes;
}
// Last document is incomplete; mark the document at i + 1 as the next one
return i;
}
return 0;
}
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* end file src/generic/stage1/find_next_document_index.h */
namespace simdjson {
namespace arm64 {
namespace {
namespace stage1 {
class bit_indexer {
public:
uint32_t *tail;
simdjson_really_inline bit_indexer(uint32_t *index_buf) : tail(index_buf) {}
// flatten out values in 'bits' assuming that they are are to have values of idx
// plus their position in the bitvector, and store these indexes at
// base_ptr[base] incrementing base as we go
// will potentially store extra values beyond end of valid bits, so base_ptr
// needs to be large enough to handle this
simdjson_really_inline void write(uint32_t idx, uint64_t bits) {
// In some instances, the next branch is expensive because it is mispredicted.
// Unfortunately, in other cases,
// it helps tremendously.
if (bits == 0)
return;
int cnt = static_cast<int>(count_ones(bits));
// Do the first 8 all together
for (int i=0; i<8; i++) {
this->tail[i] = idx + trailing_zeroes(bits);
bits = clear_lowest_bit(bits);
}
// Do the next 8 all together (we hope in most cases it won't happen at all
// and the branch is easily predicted).
if (simdjson_unlikely(cnt > 8)) {
for (int i=8; i<16; i++) {
this->tail[i] = idx + trailing_zeroes(bits);
bits = clear_lowest_bit(bits);
}
// Most files don't have 16+ structurals per block, so we take several basically guaranteed
// branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :)
// or the start of a value ("abc" true 123) every four characters.
if (simdjson_unlikely(cnt > 16)) {
int i = 16;
do {
this->tail[i] = idx + trailing_zeroes(bits);
bits = clear_lowest_bit(bits);
i++;
} while (i < cnt);
}
}
this->tail += cnt;
}
};
class json_structural_indexer {
public:
/**
* Find the important bits of JSON in a 128-byte chunk, and add them to structural_indexes.
*
* @param partial Setting the partial parameter to true allows the find_structural_bits to
* tolerate unclosed strings. The caller should still ensure that the input is valid UTF-8. If
* you are processing substrings, you may want to call on a function like trimmed_length_safe_utf8.
*/
template<size_t STEP_SIZE>
static error_code index(const uint8_t *buf, size_t len, dom_parser_implementation &parser, bool partial) noexcept;
private:
simdjson_really_inline json_structural_indexer(uint32_t *structural_indexes);
template<size_t STEP_SIZE>
simdjson_really_inline void step(const uint8_t *block, buf_block_reader<STEP_SIZE> &reader) noexcept;
simdjson_really_inline void next(const simd::simd8x64<uint8_t>& in, json_block block, size_t idx);
simdjson_really_inline error_code finish(dom_parser_implementation &parser, size_t idx, size_t len, bool partial);
json_scanner scanner{};
utf8_checker checker{};
bit_indexer indexer;
uint64_t prev_structurals = 0;
uint64_t unescaped_chars_error = 0;
};
simdjson_really_inline json_structural_indexer::json_structural_indexer(uint32_t *structural_indexes) : indexer{structural_indexes} {}
// Skip the last character if it is partial
simdjson_really_inline size_t trim_partial_utf8(const uint8_t *buf, size_t len) {
if (simdjson_unlikely(len < 3)) {
switch (len) {
case 2:
if (buf[len-1] >= 0b11000000) { return len-1; } // 2-, 3- and 4-byte characters with only 1 byte left
if (buf[len-2] >= 0b11100000) { return len-2; } // 3- and 4-byte characters with only 2 bytes left
return len;
case 1:
if (buf[len-1] >= 0b11000000) { return len-1; } // 2-, 3- and 4-byte characters with only 1 byte left
return len;
case 0:
return len;
}
}
if (buf[len-1] >= 0b11000000) { return len-1; } // 2-, 3- and 4-byte characters with only 1 byte left
if (buf[len-2] >= 0b11100000) { return len-2; } // 3- and 4-byte characters with only 1 byte left
if (buf[len-3] >= 0b11110000) { return len-3; } // 4-byte characters with only 3 bytes left
return len;
}
//
// PERF NOTES:
// We pipe 2 inputs through these stages:
// 1. Load JSON into registers. This takes a long time and is highly parallelizable, so we load
// 2 inputs' worth at once so that by the time step 2 is looking for them input, it's available.
// 2. Scan the JSON for critical data: strings, scalars and operators. This is the critical path.
// The output of step 1 depends entirely on this information. These functions don't quite use
// up enough CPU: the second half of the functions is highly serial, only using 1 execution core
// at a time. The second input's scans has some dependency on the first ones finishing it, but
// they can make a lot of progress before they need that information.
// 3. Step 1 doesn't use enough capacity, so we run some extra stuff while we're waiting for that
// to finish: utf-8 checks and generating the output from the last iteration.
//
// The reason we run 2 inputs at a time, is steps 2 and 3 are *still* not enough to soak up all
// available capacity with just one input. Running 2 at a time seems to give the CPU a good enough
// workout.
//
template<size_t STEP_SIZE>
error_code json_structural_indexer::index(const uint8_t *buf, size_t len, dom_parser_implementation &parser, bool partial) noexcept {
if (simdjson_unlikely(len > parser.capacity())) { return CAPACITY; }
if (partial) { len = trim_partial_utf8(buf, len); }
buf_block_reader<STEP_SIZE> reader(buf, len);
json_structural_indexer indexer(parser.structural_indexes.get());
// Read all but the last block
while (reader.has_full_block()) {
indexer.step<STEP_SIZE>(reader.full_block(), reader);
}
// Take care of the last block (will always be there unless file is empty)
uint8_t block[STEP_SIZE];
if (simdjson_unlikely(reader.get_remainder(block) == 0)) { return EMPTY; }
indexer.step<STEP_SIZE>(block, reader);
return indexer.finish(parser, reader.block_index(), len, partial);
}
template<>
simdjson_really_inline void json_structural_indexer::step<128>(const uint8_t *block, buf_block_reader<128> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block);
simd::simd8x64<uint8_t> in_2(block+64);
json_block block_1 = scanner.next(in_1);
json_block block_2 = scanner.next(in_2);
this->next(in_1, block_1, reader.block_index());
this->next(in_2, block_2, reader.block_index()+64);
reader.advance();
}
template<>
simdjson_really_inline void json_structural_indexer::step<64>(const uint8_t *block, buf_block_reader<64> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block);
json_block block_1 = scanner.next(in_1);
this->next(in_1, block_1, reader.block_index());
reader.advance();
}
simdjson_really_inline void json_structural_indexer::next(const simd::simd8x64<uint8_t>& in, json_block block, size_t idx) {
uint64_t unescaped = in.lteq(0x1F);
checker.check_next_input(in);
indexer.write(uint32_t(idx-64), prev_structurals); // Output *last* iteration's structurals to the parser
prev_structurals = block.structural_start();
unescaped_chars_error |= block.non_quote_inside_string(unescaped);
}
simdjson_really_inline error_code json_structural_indexer::finish(dom_parser_implementation &parser, size_t idx, size_t len, bool partial) {
// Write out the final iteration's structurals
indexer.write(uint32_t(idx-64), prev_structurals);
error_code error = scanner.finish();
// We deliberately break down the next expression so that it is
// human readable.
const bool should_we_exit = partial ?
((error != SUCCESS) && (error != UNCLOSED_STRING)) // when partial we tolerate UNCLOSED_STRING
: (error != SUCCESS); // if partial is false, we must have SUCCESS
const bool have_unclosed_string = (error == UNCLOSED_STRING);
if (simdjson_unlikely(should_we_exit)) { return error; }
if (unescaped_chars_error) {
return UNESCAPED_CHARS;
}
parser.n_structural_indexes = uint32_t(indexer.tail - parser.structural_indexes.get());
/***
* This is related to https://github.com/simdjson/simdjson/issues/906
* Basically, we want to make sure that if the parsing continues beyond the last (valid)
* structural character, it quickly stops.
* Only three structural characters can be repeated without triggering an error in JSON: [,] and }.
* We repeat the padding character (at 'len'). We don't know what it is, but if the parsing
* continues, then it must be [,] or }.
* Suppose it is ] or }. We backtrack to the first character, what could it be that would
* not trigger an error? It could be ] or } but no, because you can't start a document that way.
* It can't be a comma, a colon or any simple value. So the only way we could continue is
* if the repeated character is [. But if so, the document must start with [. But if the document
* starts with [, it should end with ]. If we enforce that rule, then we would get
* ][[ which is invalid.
**/
parser.structural_indexes[parser.n_structural_indexes] = uint32_t(len);
parser.structural_indexes[parser.n_structural_indexes + 1] = uint32_t(len);
parser.structural_indexes[parser.n_structural_indexes + 2] = 0;
parser.next_structural_index = 0;
// a valid JSON file cannot have zero structural indexes - we should have found something
if (simdjson_unlikely(parser.n_structural_indexes == 0u)) {
return EMPTY;
}
if (simdjson_unlikely(parser.structural_indexes[parser.n_structural_indexes - 1] > len)) {
return UNEXPECTED_ERROR;
}
if (partial) {
// If we have an unclosed string, then the last structural
// will be the quote and we want to make sure to omit it.
if(have_unclosed_string) {
parser.n_structural_indexes--;
// a valid JSON file cannot have zero structural indexes - we should have found something
if (simdjson_unlikely(parser.n_structural_indexes == 0u)) { return CAPACITY; }
}
auto new_structural_indexes = find_next_document_index(parser);
if (new_structural_indexes == 0 && parser.n_structural_indexes > 0) {
return CAPACITY; // If the buffer is partial but the document is incomplete, it's too big to parse.
}
parser.n_structural_indexes = new_structural_indexes;
}
checker.check_eof();
return checker.errors();
}
} // namespace stage1
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* end file src/generic/stage1/json_structural_indexer.h */
/* begin file src/generic/stage1/utf8_validator.h */
namespace simdjson {
namespace arm64 {
namespace {
namespace stage1 {
/**
* Validates that the string is actual UTF-8.
*/
template<class checker>
bool generic_validate_utf8(const uint8_t * input, size_t length) {
checker c{};
buf_block_reader<64> reader(input, length);
while (reader.has_full_block()) {
simd::simd8x64<uint8_t> in(reader.full_block());
c.check_next_input(in);
reader.advance();
}
uint8_t block[64]{};
reader.get_remainder(block);
simd::simd8x64<uint8_t> in(block);
c.check_next_input(in);
reader.advance();
c.check_eof();
return c.errors() == error_code::SUCCESS;
}
bool generic_validate_utf8(const char * input, size_t length) {
return generic_validate_utf8<utf8_checker>((const uint8_t *)input,length);
}
} // namespace stage1
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* end file src/generic/stage1/utf8_validator.h */
//
// Stage 2
//
/* begin file src/generic/stage2/tape_builder.h */
/* begin file src/generic/stage2/json_iterator.h */
/* begin file src/generic/stage2/logger.h */
// This is for an internal-only stage 2 specific logger.
// Set LOG_ENABLED = true to log what stage 2 is doing!
namespace simdjson {
namespace arm64 {
namespace {
namespace logger {
static constexpr const char * DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------";
#if SIMDJSON_VERBOSE_LOGGING
static constexpr const bool LOG_ENABLED = true;
#else
static constexpr const bool LOG_ENABLED = false;
#endif
static constexpr const int LOG_EVENT_LEN = 20;
static constexpr const int LOG_BUFFER_LEN = 30;
static constexpr const int LOG_SMALL_BUFFER_LEN = 10;
static constexpr const int LOG_INDEX_LEN = 5;
static int log_depth; // Not threadsafe. Log only.
// Helper to turn unprintable or newline characters into spaces
static simdjson_really_inline char printable_char(char c) {
if (c >= 0x20) {
return c;
} else {
return ' ';
}
}
// Print the header and set up log_start
static simdjson_really_inline void log_start() {
if (LOG_ENABLED) {
log_depth = 0;
printf("\n");
printf("| %-*s | %-*s | %-*s | %-*s | Detail |\n", LOG_EVENT_LEN, "Event", LOG_BUFFER_LEN, "Buffer", LOG_SMALL_BUFFER_LEN, "Next", 5, "Next#");
printf("|%.*s|%.*s|%.*s|%.*s|--------|\n", LOG_EVENT_LEN+2, DASHES, LOG_BUFFER_LEN+2, DASHES, LOG_SMALL_BUFFER_LEN+2, DASHES, 5+2, DASHES);
}
}
simdjson_unused static simdjson_really_inline void log_string(const char *message) {
if (LOG_ENABLED) {
printf("%s\n", message);
}
}
// Logs a single line from the stage 2 DOM parser
template<typename S>
static simdjson_really_inline void log_line(S &structurals, const char *title_prefix, const char *title, const char *detail) {
if (LOG_ENABLED) {
printf("| %*s%s%-*s ", log_depth*2, "", title_prefix, LOG_EVENT_LEN - log_depth*2 - int(strlen(title_prefix)), title);
auto current_index = structurals.at_beginning() ? nullptr : structurals.next_structural-1;
auto next_index = structurals.next_structural;
auto current = current_index ? &structurals.buf[*current_index] : (const uint8_t*)" ";
auto next = &structurals.buf[*next_index];
{
// Print the next N characters in the buffer.
printf("| ");
// Otherwise, print the characters starting from the buffer position.
// Print spaces for unprintable or newline characters.
for (int i=0;i<LOG_BUFFER_LEN;i++) {
printf("%c", printable_char(current[i]));
}
printf(" ");
// Print the next N characters in the buffer.
printf("| ");
// Otherwise, print the characters starting from the buffer position.
// Print spaces for unprintable or newline characters.
for (int i=0;i<LOG_SMALL_BUFFER_LEN;i++) {
printf("%c", printable_char(next[i]));
}
printf(" ");
}
if (current_index) {
printf("| %*u ", LOG_INDEX_LEN, *current_index);
} else {
printf("| %-*s ", LOG_INDEX_LEN, "");
}
// printf("| %*u ", LOG_INDEX_LEN, structurals.next_tape_index());
printf("| %-s ", detail);
printf("|\n");
}
}
} // namespace logger
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* end file src/generic/stage2/logger.h */
namespace simdjson {
namespace arm64 {
namespace {
namespace stage2 {
class json_iterator {
public:
const uint8_t* const buf;
uint32_t *next_structural;
dom_parser_implementation &dom_parser;
uint32_t depth{0};
/**
* Walk the JSON document.
*
* The visitor receives callbacks when values are encountered. All callbacks pass the iterator as
* the first parameter; some callbacks have other parameters as well:
*
* - visit_document_start() - at the beginning.
* - visit_document_end() - at the end (if things were successful).
*
* - visit_array_start() - at the start `[` of a non-empty array.
* - visit_array_end() - at the end `]` of a non-empty array.
* - visit_empty_array() - when an empty array is encountered.
*
* - visit_object_end() - at the start `]` of a non-empty object.
* - visit_object_start() - at the end `]` of a non-empty object.
* - visit_empty_object() - when an empty object is encountered.
* - visit_key(const uint8_t *key) - when a key in an object field is encountered. key is
* guaranteed to point at the first quote of the string (`"key"`).
* - visit_primitive(const uint8_t *value) - when a value is a string, number, boolean or null.
* - visit_root_primitive(iter, uint8_t *value) - when the top-level value is a string, number, boolean or null.
*
* - increment_count(iter) - each time a value is found in an array or object.
*/
template<bool STREAMING, typename V>
simdjson_warn_unused simdjson_really_inline error_code walk_document(V &visitor) noexcept;
/**
* Create an iterator capable of walking a JSON document.
*
* The document must have already passed through stage 1.
*/
simdjson_really_inline json_iterator(dom_parser_implementation &_dom_parser, size_t start_structural_index);
/**
* Look at the next token.
*
* Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)).
*
* They may include invalid JSON as well (such as `1.2.3` or `ture`).
*/
simdjson_really_inline const uint8_t *peek() const noexcept;
/**
* Advance to the next token.
*
* Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)).
*
* They may include invalid JSON as well (such as `1.2.3` or `ture`).
*/
simdjson_really_inline const uint8_t *advance() noexcept;
/**
* Get the remaining length of the document, from the start of the current token.
*/
simdjson_really_inline size_t remaining_len() const noexcept;
/**
* Check if we are at the end of the document.
*
* If this is true, there are no more tokens.
*/
simdjson_really_inline bool at_eof() const noexcept;
/**
* Check if we are at the beginning of the document.
*/
simdjson_really_inline bool at_beginning() const noexcept;
simdjson_really_inline uint8_t last_structural() const noexcept;
/**
* Log that a value has been found.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_value(const char *type) const noexcept;
/**
* Log the start of a multipart value.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_start_value(const char *type) const noexcept;
/**
* Log the end of a multipart value.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_end_value(const char *type) const noexcept;
/**
* Log an error.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_error(const char *error) const noexcept;
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code visit_root_primitive(V &visitor, const uint8_t *value) noexcept;
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code visit_primitive(V &visitor, const uint8_t *value) noexcept;
};
template<bool STREAMING, typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::walk_document(V &visitor) noexcept {
logger::log_start();
//
// Start the document
//
if (at_eof()) { return EMPTY; }
log_start_value("document");
SIMDJSON_TRY( visitor.visit_document_start(*this) );
//
// Read first value
//
{
auto value = advance();
// Make sure the outer hash or array is closed before continuing; otherwise, there are ways we
// could get into memory corruption. See https://github.com/simdjson/simdjson/issues/906
if (!STREAMING) {
switch (*value) {
case '{': if (last_structural() != '}') { return TAPE_ERROR; }; break;
case '[': if (last_structural() != ']') { return TAPE_ERROR; }; break;
}
}
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_root_primitive(*this, value) ); break;
}
}
goto document_end;
//
// Object parser states
//
object_begin:
log_start_value("object");
depth++;
if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; }
dom_parser.is_array[depth] = false;
SIMDJSON_TRY( visitor.visit_object_start(*this) );
{
auto key = advance();
if (*key != '"') { log_error("Object does not start with a key"); return TAPE_ERROR; }
SIMDJSON_TRY( visitor.increment_count(*this) );
SIMDJSON_TRY( visitor.visit_key(*this, key) );
}
object_field:
if (simdjson_unlikely( *advance() != ':' )) { log_error("Missing colon after key in object"); return TAPE_ERROR; }
{
auto value = advance();
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_primitive(*this, value) ); break;
}
}
object_continue:
switch (*advance()) {
case ',':
SIMDJSON_TRY( visitor.increment_count(*this) );
{
auto key = advance();
if (simdjson_unlikely( *key != '"' )) { log_error("Key string missing at beginning of field in object"); return TAPE_ERROR; }
SIMDJSON_TRY( visitor.visit_key(*this, key) );
}
goto object_field;
case '}': log_end_value("object"); SIMDJSON_TRY( visitor.visit_object_end(*this) ); goto scope_end;
default: log_error("No comma between object fields"); return TAPE_ERROR;
}
scope_end:
depth--;
if (depth == 0) { goto document_end; }
if (dom_parser.is_array[depth]) { goto array_continue; }
goto object_continue;
//
// Array parser states
//
array_begin:
log_start_value("array");
depth++;
if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; }
dom_parser.is_array[depth] = true;
SIMDJSON_TRY( visitor.visit_array_start(*this) );
SIMDJSON_TRY( visitor.increment_count(*this) );
array_value:
{
auto value = advance();
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_primitive(*this, value) ); break;
}
}
array_continue:
switch (*advance()) {
case ',': SIMDJSON_TRY( visitor.increment_count(*this) ); goto array_value;
case ']': log_end_value("array"); SIMDJSON_TRY( visitor.visit_array_end(*this) ); goto scope_end;
default: log_error("Missing comma between array values"); return TAPE_ERROR;
}
document_end:
log_end_value("document");
SIMDJSON_TRY( visitor.visit_document_end(*this) );
dom_parser.next_structural_index = uint32_t(next_structural - &dom_parser.structural_indexes[0]);
// If we didn't make it to the end, it's an error
if ( !STREAMING && dom_parser.next_structural_index != dom_parser.n_structural_indexes ) {
log_error("More than one JSON value at the root of the document, or extra characters at the end of the JSON!");
return TAPE_ERROR;
}
return SUCCESS;
} // walk_document()
simdjson_really_inline json_iterator::json_iterator(dom_parser_implementation &_dom_parser, size_t start_structural_index)
: buf{_dom_parser.buf},
next_structural{&_dom_parser.structural_indexes[start_structural_index]},
dom_parser{_dom_parser} {
}
simdjson_really_inline const uint8_t *json_iterator::peek() const noexcept {
return &buf[*(next_structural)];
}
simdjson_really_inline const uint8_t *json_iterator::advance() noexcept {
return &buf[*(next_structural++)];
}
simdjson_really_inline size_t json_iterator::remaining_len() const noexcept {
return dom_parser.len - *(next_structural-1);
}
simdjson_really_inline bool json_iterator::at_eof() const noexcept {
return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes];
}
simdjson_really_inline bool json_iterator::at_beginning() const noexcept {
return next_structural == dom_parser.structural_indexes.get();
}
simdjson_really_inline uint8_t json_iterator::last_structural() const noexcept {
return buf[dom_parser.structural_indexes[dom_parser.n_structural_indexes - 1]];
}
simdjson_really_inline void json_iterator::log_value(const char *type) const noexcept {
logger::log_line(*this, "", type, "");
}
simdjson_really_inline void json_iterator::log_start_value(const char *type) const noexcept {
logger::log_line(*this, "+", type, "");
if (logger::LOG_ENABLED) { logger::log_depth++; }
}
simdjson_really_inline void json_iterator::log_end_value(const char *type) const noexcept {
if (logger::LOG_ENABLED) { logger::log_depth--; }
logger::log_line(*this, "-", type, "");
}
simdjson_really_inline void json_iterator::log_error(const char *error) const noexcept {
logger::log_line(*this, "", "ERROR", error);
}
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::visit_root_primitive(V &visitor, const uint8_t *value) noexcept {
switch (*value) {
case '"': return visitor.visit_root_string(*this, value);
case 't': return visitor.visit_root_true_atom(*this, value);
case 'f': return visitor.visit_root_false_atom(*this, value);
case 'n': return visitor.visit_root_null_atom(*this, value);
case '-':
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
return visitor.visit_root_number(*this, value);
default:
log_error("Document starts with a non-value character");
return TAPE_ERROR;
}
}
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::visit_primitive(V &visitor, const uint8_t *value) noexcept {
switch (*value) {
case '"': return visitor.visit_string(*this, value);
case 't': return visitor.visit_true_atom(*this, value);
case 'f': return visitor.visit_false_atom(*this, value);
case 'n': return visitor.visit_null_atom(*this, value);
case '-':
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
return visitor.visit_number(*this, value);
default:
log_error("Non-value found when value was expected!");
return TAPE_ERROR;
}
}
} // namespace stage2
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* end file src/generic/stage2/json_iterator.h */
/* begin file src/generic/stage2/tape_writer.h */
namespace simdjson {
namespace arm64 {
namespace {
namespace stage2 {
struct tape_writer {
/** The next place to write to tape */
uint64_t *next_tape_loc;
/** Write a signed 64-bit value to tape. */
simdjson_really_inline void append_s64(int64_t value) noexcept;
/** Write an unsigned 64-bit value to tape. */
simdjson_really_inline void append_u64(uint64_t value) noexcept;
/** Write a double value to tape. */
simdjson_really_inline void append_double(double value) noexcept;
/**
* Append a tape entry (an 8-bit type,and 56 bits worth of value).
*/
simdjson_really_inline void append(uint64_t val, internal::tape_type t) noexcept;
/**
* Skip the current tape entry without writing.
*
* Used to skip the start of the container, since we'll come back later to fill it in when the
* container ends.
*/
simdjson_really_inline void skip() noexcept;
/**
* Skip the number of tape entries necessary to write a large u64 or i64.
*/
simdjson_really_inline void skip_large_integer() noexcept;
/**
* Skip the number of tape entries necessary to write a double.
*/
simdjson_really_inline void skip_double() noexcept;
/**
* Write a value to a known location on tape.
*
* Used to go back and write out the start of a container after the container ends.
*/
simdjson_really_inline static void write(uint64_t &tape_loc, uint64_t val, internal::tape_type t) noexcept;
private:
/**
* Append both the tape entry, and a supplementary value following it. Used for types that need
* all 64 bits, such as double and uint64_t.
*/
template<typename T>
simdjson_really_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept;
}; // struct number_writer
simdjson_really_inline void tape_writer::append_s64(int64_t value) noexcept {
append2(0, value, internal::tape_type::INT64);
}
simdjson_really_inline void tape_writer::append_u64(uint64_t value) noexcept {
append(0, internal::tape_type::UINT64);
*next_tape_loc = value;
next_tape_loc++;
}
/** Write a double value to tape. */
simdjson_really_inline void tape_writer::append_double(double value) noexcept {
append2(0, value, internal::tape_type::DOUBLE);
}
simdjson_really_inline void tape_writer::skip() noexcept {
next_tape_loc++;
}
simdjson_really_inline void tape_writer::skip_large_integer() noexcept {
next_tape_loc += 2;
}
simdjson_really_inline void tape_writer::skip_double() noexcept {
next_tape_loc += 2;
}
simdjson_really_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept {
*next_tape_loc = val | ((uint64_t(char(t))) << 56);
next_tape_loc++;
}
template<typename T>
simdjson_really_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept {
append(val, t);
static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!");
memcpy(next_tape_loc, &val2, sizeof(val2));
next_tape_loc++;
}
simdjson_really_inline void tape_writer::write(uint64_t &tape_loc, uint64_t val, internal::tape_type t) noexcept {
tape_loc = val | ((uint64_t(char(t))) << 56);
}
} // namespace stage2
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* end file src/generic/stage2/tape_writer.h */
namespace simdjson {
namespace arm64 {
namespace {
namespace stage2 {
struct tape_builder {
template<bool STREAMING>
simdjson_warn_unused static simdjson_really_inline error_code parse_document(
dom_parser_implementation &dom_parser,
dom::document &doc) noexcept;
/** Called when a non-empty document starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_document_start(json_iterator &iter) noexcept;
/** Called when a non-empty document ends without error. */
simdjson_warn_unused simdjson_really_inline error_code visit_document_end(json_iterator &iter) noexcept;
/** Called when a non-empty array starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_array_start(json_iterator &iter) noexcept;
/** Called when a non-empty array ends. */
simdjson_warn_unused simdjson_really_inline error_code visit_array_end(json_iterator &iter) noexcept;
/** Called when an empty array is found. */
simdjson_warn_unused simdjson_really_inline error_code visit_empty_array(json_iterator &iter) noexcept;
/** Called when a non-empty object starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_object_start(json_iterator &iter) noexcept;
/**
* Called when a key in a field is encountered.
*
* primitive, visit_object_start, visit_empty_object, visit_array_start, or visit_empty_array
* will be called after this with the field value.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_key(json_iterator &iter, const uint8_t *key) noexcept;
/** Called when a non-empty object ends. */
simdjson_warn_unused simdjson_really_inline error_code visit_object_end(json_iterator &iter) noexcept;
/** Called when an empty object is found. */
simdjson_warn_unused simdjson_really_inline error_code visit_empty_object(json_iterator &iter) noexcept;
/**
* Called when a string, number, boolean or null is found.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_primitive(json_iterator &iter, const uint8_t *value) noexcept;
/**
* Called when a string, number, boolean or null is found at the top level of a document (i.e.
* when there is no array or object and the entire document is a single string, number, boolean or
* null.
*
* This is separate from primitive() because simdjson's normal primitive parsing routines assume
* there is at least one more token after the value, which is only true in an array or object.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_root_primitive(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_string(json_iterator &iter, const uint8_t *value, bool key = false) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_number(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_true_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_false_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_null_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_string(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_number(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_true_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_false_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_null_atom(json_iterator &iter, const uint8_t *value) noexcept;
/** Called each time a new field or element in an array or object is found. */
simdjson_warn_unused simdjson_really_inline error_code increment_count(json_iterator &iter) noexcept;
/** Next location to write to tape */
tape_writer tape;
private:
/** Next write location in the string buf for stage 2 parsing */
uint8_t *current_string_buf_loc;
simdjson_really_inline tape_builder(dom::document &doc) noexcept;
simdjson_really_inline uint32_t next_tape_index(json_iterator &iter) const noexcept;
simdjson_really_inline void start_container(json_iterator &iter) noexcept;
simdjson_warn_unused simdjson_really_inline error_code end_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept;
simdjson_warn_unused simdjson_really_inline error_code empty_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept;
simdjson_really_inline uint8_t *on_start_string(json_iterator &iter) noexcept;
simdjson_really_inline void on_end_string(uint8_t *dst) noexcept;
}; // class tape_builder
template<bool STREAMING>
simdjson_warn_unused simdjson_really_inline error_code tape_builder::parse_document(
dom_parser_implementation &dom_parser,
dom::document &doc) noexcept {
dom_parser.doc = &doc;
json_iterator iter(dom_parser, STREAMING ? dom_parser.next_structural_index : 0);
tape_builder builder(doc);
return iter.walk_document<STREAMING>(builder);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_primitive(json_iterator &iter, const uint8_t *value) noexcept {
return iter.visit_root_primitive(*this, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_primitive(json_iterator &iter, const uint8_t *value) noexcept {
return iter.visit_primitive(*this, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_empty_object(json_iterator &iter) noexcept {
return empty_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_empty_array(json_iterator &iter) noexcept {
return empty_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_document_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_object_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_array_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_object_end(json_iterator &iter) noexcept {
return end_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_array_end(json_iterator &iter) noexcept {
return end_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_document_end(json_iterator &iter) noexcept {
constexpr uint32_t start_tape_index = 0;
tape.append(start_tape_index, internal::tape_type::ROOT);
tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter), internal::tape_type::ROOT);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_key(json_iterator &iter, const uint8_t *key) noexcept {
return visit_string(iter, key, true);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::increment_count(json_iterator &iter) noexcept {
iter.dom_parser.open_containers[iter.depth].count++; // we have a key value pair in the object at parser.dom_parser.depth - 1
return SUCCESS;
}
simdjson_really_inline tape_builder::tape_builder(dom::document &doc) noexcept : tape{doc.tape.get()}, current_string_buf_loc{doc.string_buf.get()} {}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_string(json_iterator &iter, const uint8_t *value, bool key) noexcept {
iter.log_value(key ? "key" : "string");
uint8_t *dst = on_start_string(iter);
dst = stringparsing::parse_string(value+1, dst);
if (dst == nullptr) {
iter.log_error("Invalid escape in string");
return STRING_ERROR;
}
on_end_string(dst);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_string(json_iterator &iter, const uint8_t *value) noexcept {
return visit_string(iter, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_number(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("number");
return numberparsing::parse_number(value, tape);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_number(json_iterator &iter, const uint8_t *value) noexcept {
//
// We need to make a copy to make sure that the string is space terminated.
// This is not about padding the input, which should already padded up
// to len + SIMDJSON_PADDING. However, we have no control at this stage
// on how the padding was done. What if the input string was padded with nulls?
// It is quite common for an input string to have an extra null character (C string).
// We do not want to allow 9\0 (where \0 is the null character) inside a JSON
// document, but the string "9\0" by itself is fine. So we make a copy and
// pad the input with spaces when we know that there is just one input element.
// This copy is relatively expensive, but it will almost never be called in
// practice unless you are in the strange scenario where you have many JSON
// documents made of single atoms.
//
uint8_t *copy = static_cast<uint8_t *>(malloc(iter.remaining_len() + SIMDJSON_PADDING));
if (copy == nullptr) { return MEMALLOC; }
std::memcpy(copy, value, iter.remaining_len());
std::memset(copy + iter.remaining_len(), ' ', SIMDJSON_PADDING);
error_code error = visit_number(iter, copy);
free(copy);
return error;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_true_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("true");
if (!atomparsing::is_valid_true_atom(value)) { return T_ATOM_ERROR; }
tape.append(0, internal::tape_type::TRUE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_true_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("true");
if (!atomparsing::is_valid_true_atom(value, iter.remaining_len())) { return T_ATOM_ERROR; }
tape.append(0, internal::tape_type::TRUE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_false_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("false");
if (!atomparsing::is_valid_false_atom(value)) { return F_ATOM_ERROR; }
tape.append(0, internal::tape_type::FALSE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_false_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("false");
if (!atomparsing::is_valid_false_atom(value, iter.remaining_len())) { return F_ATOM_ERROR; }
tape.append(0, internal::tape_type::FALSE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_null_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("null");
if (!atomparsing::is_valid_null_atom(value)) { return N_ATOM_ERROR; }
tape.append(0, internal::tape_type::NULL_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_null_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("null");
if (!atomparsing::is_valid_null_atom(value, iter.remaining_len())) { return N_ATOM_ERROR; }
tape.append(0, internal::tape_type::NULL_VALUE);
return SUCCESS;
}
// private:
simdjson_really_inline uint32_t tape_builder::next_tape_index(json_iterator &iter) const noexcept {
return uint32_t(tape.next_tape_loc - iter.dom_parser.doc->tape.get());
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::empty_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept {
auto start_index = next_tape_index(iter);
tape.append(start_index+2, start);
tape.append(start_index, end);
return SUCCESS;
}
simdjson_really_inline void tape_builder::start_container(json_iterator &iter) noexcept {
iter.dom_parser.open_containers[iter.depth].tape_index = next_tape_index(iter);
iter.dom_parser.open_containers[iter.depth].count = 0;
tape.skip(); // We don't actually *write* the start element until the end.
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::end_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept {
// Write the ending tape element, pointing at the start location
const uint32_t start_tape_index = iter.dom_parser.open_containers[iter.depth].tape_index;
tape.append(start_tape_index, end);
// Write the start tape element, pointing at the end location (and including count)
// count can overflow if it exceeds 24 bits... so we saturate
// the convention being that a cnt of 0xffffff or more is undetermined in value (>= 0xffffff).
const uint32_t count = iter.dom_parser.open_containers[iter.depth].count;
const uint32_t cntsat = count > 0xFFFFFF ? 0xFFFFFF : count;
tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter) | (uint64_t(cntsat) << 32), start);
return SUCCESS;
}
simdjson_really_inline uint8_t *tape_builder::on_start_string(json_iterator &iter) noexcept {
// we advance the point, accounting for the fact that we have a NULL termination
tape.append(current_string_buf_loc - iter.dom_parser.doc->string_buf.get(), internal::tape_type::STRING);
return current_string_buf_loc + sizeof(uint32_t);
}
simdjson_really_inline void tape_builder::on_end_string(uint8_t *dst) noexcept {
uint32_t str_length = uint32_t(dst - (current_string_buf_loc + sizeof(uint32_t)));
// TODO check for overflow in case someone has a crazy string (>=4GB?)
// But only add the overflow check when the document itself exceeds 4GB
// Currently unneeded because we refuse to parse docs larger or equal to 4GB.
memcpy(current_string_buf_loc, &str_length, sizeof(uint32_t));
// NULL termination is still handy if you expect all your strings to
// be NULL terminated? It comes at a small cost
*dst = 0;
current_string_buf_loc = dst + 1;
}
} // namespace stage2
} // unnamed namespace
} // namespace arm64
} // namespace simdjson
/* end file src/generic/stage2/tape_builder.h */
//
// Implementation-specific overrides
//
namespace simdjson {
namespace arm64 {
namespace {
namespace stage1 {
simdjson_really_inline uint64_t json_string_scanner::find_escaped(uint64_t backslash) {
// On ARM, we don't short-circuit this if there are no backslashes, because the branch gives us no
// benefit and therefore makes things worse.
// if (!backslash) { uint64_t escaped = prev_escaped; prev_escaped = 0; return escaped; }
return find_escaped_branchless(backslash);
}
} // namespace stage1
} // unnamed namespace
simdjson_warn_unused error_code implementation::minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) const noexcept {
return arm64::stage1::json_minifier::minify<64>(buf, len, dst, dst_len);
}
simdjson_warn_unused error_code dom_parser_implementation::stage1(const uint8_t *_buf, size_t _len, bool streaming) noexcept {
this->buf = _buf;
this->len = _len;
return arm64::stage1::json_structural_indexer::index<64>(buf, len, *this, streaming);
}
simdjson_warn_unused bool implementation::validate_utf8(const char *buf, size_t len) const noexcept {
return arm64::stage1::generic_validate_utf8(buf,len);
}
simdjson_warn_unused error_code dom_parser_implementation::stage2(dom::document &_doc) noexcept {
return stage2::tape_builder::parse_document<false>(*this, _doc);
}
simdjson_warn_unused error_code dom_parser_implementation::stage2_next(dom::document &_doc) noexcept {
return stage2::tape_builder::parse_document<true>(*this, _doc);
}
simdjson_warn_unused error_code dom_parser_implementation::parse(const uint8_t *_buf, size_t _len, dom::document &_doc) noexcept {
auto error = stage1(_buf, _len, false);
if (error) { return error; }
return stage2(_doc);
}
} // namespace arm64
} // namespace simdjson
/* begin file include/simdjson/arm64/end.h */
#undef arm64
/* end file include/simdjson/arm64/end.h */
/* end file src/arm64/dom_parser_implementation.cpp */
#endif
#if SIMDJSON_IMPLEMENTATION_FALLBACK
/* begin file src/fallback/implementation.cpp */
/* begin file include/simdjson/fallback/begin.h */
// redefining SIMDJSON_IMPLEMENTATION to "fallback"
// #define SIMDJSON_IMPLEMENTATION fallback
/* end file include/simdjson/fallback/begin.h */
namespace simdjson {
namespace fallback {
simdjson_warn_unused error_code implementation::create_dom_parser_implementation(
size_t capacity,
size_t max_depth,
std::unique_ptr<internal::dom_parser_implementation>& dst
) const noexcept {
dst.reset( new (std::nothrow) dom_parser_implementation() );
if (!dst) { return MEMALLOC; }
dst->set_capacity(capacity);
dst->set_max_depth(max_depth);
return SUCCESS;
}
} // namespace fallback
} // namespace simdjson
/* begin file include/simdjson/fallback/end.h */
#undef fallback
/* end file include/simdjson/fallback/end.h */
/* end file src/fallback/implementation.cpp */
/* begin file src/fallback/dom_parser_implementation.cpp */
/* begin file include/simdjson/fallback/begin.h */
// redefining SIMDJSON_IMPLEMENTATION to "fallback"
// #define SIMDJSON_IMPLEMENTATION fallback
/* end file include/simdjson/fallback/begin.h */
//
// Stage 1
//
/* begin file src/generic/stage1/find_next_document_index.h */
namespace simdjson {
namespace fallback {
namespace {
/**
* This algorithm is used to quickly identify the last structural position that
* makes up a complete document.
*
* It does this by going backwards and finding the last *document boundary* (a
* place where one value follows another without a comma between them). If the
* last document (the characters after the boundary) has an equal number of
* start and end brackets, it is considered complete.
*
* Simply put, we iterate over the structural characters, starting from
* the end. We consider that we found the end of a JSON document when the
* first element of the pair is NOT one of these characters: '{' '[' ';' ','
* and when the second element is NOT one of these characters: '}' '}' ';' ','.
*
* This simple comparison works most of the time, but it does not cover cases
* where the batch's structural indexes contain a perfect amount of documents.
* In such a case, we do not have access to the structural index which follows
* the last document, therefore, we do not have access to the second element in
* the pair, and that means we cannot identify the last document. To fix this
* issue, we keep a count of the open and closed curly/square braces we found
* while searching for the pair. When we find a pair AND the count of open and
* closed curly/square braces is the same, we know that we just passed a
* complete document, therefore the last json buffer location is the end of the
* batch.
*/
simdjson_really_inline uint32_t find_next_document_index(dom_parser_implementation &parser) {
// TODO don't count separately, just figure out depth
auto arr_cnt = 0;
auto obj_cnt = 0;
for (auto i = parser.n_structural_indexes - 1; i > 0; i--) {
auto idxb = parser.structural_indexes[i];
switch (parser.buf[idxb]) {
case ':':
case ',':
continue;
case '}':
obj_cnt--;
continue;
case ']':
arr_cnt--;
continue;
case '{':
obj_cnt++;
break;
case '[':
arr_cnt++;
break;
}
auto idxa = parser.structural_indexes[i - 1];
switch (parser.buf[idxa]) {
case '{':
case '[':
case ':':
case ',':
continue;
}
// Last document is complete, so the next document will appear after!
if (!arr_cnt && !obj_cnt) {
return parser.n_structural_indexes;
}
// Last document is incomplete; mark the document at i + 1 as the next one
return i;
}
return 0;
}
} // unnamed namespace
} // namespace fallback
} // namespace simdjson
/* end file src/generic/stage1/find_next_document_index.h */
namespace simdjson {
namespace fallback {
namespace {
namespace stage1 {
class structural_scanner {
public:
simdjson_really_inline structural_scanner(dom_parser_implementation &_parser, bool _partial)
: buf{_parser.buf},
next_structural_index{_parser.structural_indexes.get()},
parser{_parser},
len{static_cast<uint32_t>(_parser.len)},
partial{_partial} {
}
simdjson_really_inline void add_structural() {
*next_structural_index = idx;
next_structural_index++;
}
simdjson_really_inline bool is_continuation(uint8_t c) {
return (c & 0b11000000) == 0b10000000;
}
simdjson_really_inline void validate_utf8_character() {
// Continuation
if (simdjson_unlikely((buf[idx] & 0b01000000) == 0)) {
// extra continuation
error = UTF8_ERROR;
idx++;
return;
}
// 2-byte
if ((buf[idx] & 0b00100000) == 0) {
// missing continuation
if (simdjson_unlikely(idx+1 > len || !is_continuation(buf[idx+1]))) {
if (idx+1 > len && partial) { idx = len; return; }
error = UTF8_ERROR;
idx++;
return;
}
// overlong: 1100000_ 10______
if (buf[idx] <= 0b11000001) { error = UTF8_ERROR; }
idx += 2;
return;
}
// 3-byte
if ((buf[idx] & 0b00010000) == 0) {
// missing continuation
if (simdjson_unlikely(idx+2 > len || !is_continuation(buf[idx+1]) || !is_continuation(buf[idx+2]))) {
if (idx+2 > len && partial) { idx = len; return; }
error = UTF8_ERROR;
idx++;
return;
}
// overlong: 11100000 100_____ ________
if (buf[idx] == 0b11100000 && buf[idx+1] <= 0b10011111) { error = UTF8_ERROR; }
// surrogates: U+D800-U+DFFF 11101101 101_____
if (buf[idx] == 0b11101101 && buf[idx+1] >= 0b10100000) { error = UTF8_ERROR; }
idx += 3;
return;
}
// 4-byte
// missing continuation
if (simdjson_unlikely(idx+3 > len || !is_continuation(buf[idx+1]) || !is_continuation(buf[idx+2]) || !is_continuation(buf[idx+3]))) {
if (idx+2 > len && partial) { idx = len; return; }
error = UTF8_ERROR;
idx++;
return;
}
// overlong: 11110000 1000____ ________ ________
if (buf[idx] == 0b11110000 && buf[idx+1] <= 0b10001111) { error = UTF8_ERROR; }
// too large: > U+10FFFF:
// 11110100 (1001|101_)____
// 1111(1___|011_|0101) 10______
// also includes 5, 6, 7 and 8 byte characters:
// 11111___
if (buf[idx] == 0b11110100 && buf[idx+1] >= 0b10010000) { error = UTF8_ERROR; }
if (buf[idx] >= 0b11110101) { error = UTF8_ERROR; }
idx += 4;
}
// Returns true if the string is unclosed.
simdjson_really_inline bool validate_string() {
idx++; // skip first quote
while (idx < len && buf[idx] != '"') {
if (buf[idx] == '\\') {
idx += 2;
} else if (simdjson_unlikely(buf[idx] & 0b10000000)) {
validate_utf8_character();
} else {
if (buf[idx] < 0x20) { error = UNESCAPED_CHARS; }
idx++;
}
}
if (idx >= len) { return true; }
return false;
}
simdjson_really_inline bool is_whitespace_or_operator(uint8_t c) {
switch (c) {
case '{': case '}': case '[': case ']': case ',': case ':':
case ' ': case '\r': case '\n': case '\t':
return true;
default:
return false;
}
}
//
// Parse the entire input in STEP_SIZE-byte chunks.
//
simdjson_really_inline error_code scan() {
bool unclosed_string = false;
for (;idx<len;idx++) {
switch (buf[idx]) {
// String
case '"':
add_structural();
unclosed_string |= validate_string();
break;
// Operator
case '{': case '}': case '[': case ']': case ',': case ':':
add_structural();
break;
// Whitespace
case ' ': case '\r': case '\n': case '\t':
break;
// Primitive or invalid character (invalid characters will be checked in stage 2)
default:
// Anything else, add the structural and go until we find the next one
add_structural();
while (idx+1<len && !is_whitespace_or_operator(buf[idx+1])) {
idx++;
};
break;
}
}
*next_structural_index = len;
// We pad beyond.
// https://github.com/simdjson/simdjson/issues/906
next_structural_index[1] = len;
next_structural_index[2] = 0;
parser.n_structural_indexes = uint32_t(next_structural_index - parser.structural_indexes.get());
if (simdjson_unlikely(parser.n_structural_indexes == 0)) { return EMPTY; }
parser.next_structural_index = 0;
if (partial) {
if(unclosed_string) {
parser.n_structural_indexes--;
if (simdjson_unlikely(parser.n_structural_indexes == 0)) { return CAPACITY; }
}
auto new_structural_indexes = find_next_document_index(parser);
if (new_structural_indexes == 0 && parser.n_structural_indexes > 0) {
return CAPACITY; // If the buffer is partial but the document is incomplete, it's too big to parse.
}
parser.n_structural_indexes = new_structural_indexes;
} else if(unclosed_string) { error = UNCLOSED_STRING; }
return error;
}
private:
const uint8_t *buf;
uint32_t *next_structural_index;
dom_parser_implementation &parser;
uint32_t len;
uint32_t idx{0};
error_code error{SUCCESS};
bool partial;
}; // structural_scanner
} // namespace stage1
} // unnamed namespace
simdjson_warn_unused error_code dom_parser_implementation::stage1(const uint8_t *_buf, size_t _len, bool partial) noexcept {
this->buf = _buf;
this->len = _len;
stage1::structural_scanner scanner(*this, partial);
return scanner.scan();
}
// big table for the minifier
static uint8_t jump_table[256 * 3] = {
0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0,
1, 1, 0, 1, 0, 0, 1, 0, 0, 1, 1, 0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 1, 1, 0, 1,
1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1,
0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 0, 0,
1, 1, 1, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1,
1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1,
0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0,
1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1,
1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1,
0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0,
1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1,
1, 0, 0, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1,
0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0,
1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1,
1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1,
0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0,
1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1,
1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1,
0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0,
1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1,
1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1,
0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0,
1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1,
1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1,
0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0,
1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1,
1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1,
0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0,
1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1,
1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1,
0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 1, 1,
};
simdjson_warn_unused error_code implementation::minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) const noexcept {
size_t i = 0, pos = 0;
uint8_t quote = 0;
uint8_t nonescape = 1;
while (i < len) {
unsigned char c = buf[i];
uint8_t *meta = jump_table + 3 * c;
quote = quote ^ (meta[0] & nonescape);
dst[pos] = c;
pos += meta[2] | quote;
i += 1;
nonescape = uint8_t(~nonescape) | (meta[1]);
}
dst_len = pos; // we intentionally do not work with a reference
// for fear of aliasing
return quote ? UNCLOSED_STRING : SUCCESS;
}
// credit: based on code from Google Fuchsia (Apache Licensed)
simdjson_warn_unused bool implementation::validate_utf8(const char *buf, size_t len) const noexcept {
const uint8_t *data = (const uint8_t *)buf;
uint64_t pos = 0;
uint32_t code_point = 0;
while (pos < len) {
// check of the next 8 bytes are ascii.
uint64_t next_pos = pos + 16;
if (next_pos <= len) { // if it is safe to read 8 more bytes, check that they are ascii
uint64_t v1;
memcpy(&v1, data + pos, sizeof(uint64_t));
uint64_t v2;
memcpy(&v2, data + pos + sizeof(uint64_t), sizeof(uint64_t));
uint64_t v{v1 | v2};
if ((v & 0x8080808080808080) == 0) {
pos = next_pos;
continue;
}
}
unsigned char byte = data[pos];
if (byte < 0b10000000) {
pos++;
continue;
} else if ((byte & 0b11100000) == 0b11000000) {
next_pos = pos + 2;
if (next_pos > len) { return false; }
if ((data[pos + 1] & 0b11000000) != 0b10000000) { return false; }
// range check
code_point = (byte & 0b00011111) << 6 | (data[pos + 1] & 0b00111111);
if (code_point < 0x80 || 0x7ff < code_point) { return false; }
} else if ((byte & 0b11110000) == 0b11100000) {
next_pos = pos + 3;
if (next_pos > len) { return false; }
if ((data[pos + 1] & 0b11000000) != 0b10000000) { return false; }
if ((data[pos + 2] & 0b11000000) != 0b10000000) { return false; }
// range check
code_point = (byte & 0b00001111) << 12 |
(data[pos + 1] & 0b00111111) << 6 |
(data[pos + 2] & 0b00111111);
if (code_point < 0x800 || 0xffff < code_point ||
(0xd7ff < code_point && code_point < 0xe000)) {
return false;
}
} else if ((byte & 0b11111000) == 0b11110000) { // 0b11110000
next_pos = pos + 4;
if (next_pos > len) { return false; }
if ((data[pos + 1] & 0b11000000) != 0b10000000) { return false; }
if ((data[pos + 2] & 0b11000000) != 0b10000000) { return false; }
if ((data[pos + 3] & 0b11000000) != 0b10000000) { return false; }
// range check
code_point =
(byte & 0b00000111) << 18 | (data[pos + 1] & 0b00111111) << 12 |
(data[pos + 2] & 0b00111111) << 6 | (data[pos + 3] & 0b00111111);
if (code_point <= 0xffff || 0x10ffff < code_point) { return false; }
} else {
// we may have a continuation
return false;
}
pos = next_pos;
}
return true;
}
} // namespace fallback
} // namespace simdjson
//
// Stage 2
//
/* begin file src/generic/stage2/tape_builder.h */
/* begin file src/generic/stage2/json_iterator.h */
/* begin file src/generic/stage2/logger.h */
// This is for an internal-only stage 2 specific logger.
// Set LOG_ENABLED = true to log what stage 2 is doing!
namespace simdjson {
namespace fallback {
namespace {
namespace logger {
static constexpr const char * DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------";
#if SIMDJSON_VERBOSE_LOGGING
static constexpr const bool LOG_ENABLED = true;
#else
static constexpr const bool LOG_ENABLED = false;
#endif
static constexpr const int LOG_EVENT_LEN = 20;
static constexpr const int LOG_BUFFER_LEN = 30;
static constexpr const int LOG_SMALL_BUFFER_LEN = 10;
static constexpr const int LOG_INDEX_LEN = 5;
static int log_depth; // Not threadsafe. Log only.
// Helper to turn unprintable or newline characters into spaces
static simdjson_really_inline char printable_char(char c) {
if (c >= 0x20) {
return c;
} else {
return ' ';
}
}
// Print the header and set up log_start
static simdjson_really_inline void log_start() {
if (LOG_ENABLED) {
log_depth = 0;
printf("\n");
printf("| %-*s | %-*s | %-*s | %-*s | Detail |\n", LOG_EVENT_LEN, "Event", LOG_BUFFER_LEN, "Buffer", LOG_SMALL_BUFFER_LEN, "Next", 5, "Next#");
printf("|%.*s|%.*s|%.*s|%.*s|--------|\n", LOG_EVENT_LEN+2, DASHES, LOG_BUFFER_LEN+2, DASHES, LOG_SMALL_BUFFER_LEN+2, DASHES, 5+2, DASHES);
}
}
simdjson_unused static simdjson_really_inline void log_string(const char *message) {
if (LOG_ENABLED) {
printf("%s\n", message);
}
}
// Logs a single line from the stage 2 DOM parser
template<typename S>
static simdjson_really_inline void log_line(S &structurals, const char *title_prefix, const char *title, const char *detail) {
if (LOG_ENABLED) {
printf("| %*s%s%-*s ", log_depth*2, "", title_prefix, LOG_EVENT_LEN - log_depth*2 - int(strlen(title_prefix)), title);
auto current_index = structurals.at_beginning() ? nullptr : structurals.next_structural-1;
auto next_index = structurals.next_structural;
auto current = current_index ? &structurals.buf[*current_index] : (const uint8_t*)" ";
auto next = &structurals.buf[*next_index];
{
// Print the next N characters in the buffer.
printf("| ");
// Otherwise, print the characters starting from the buffer position.
// Print spaces for unprintable or newline characters.
for (int i=0;i<LOG_BUFFER_LEN;i++) {
printf("%c", printable_char(current[i]));
}
printf(" ");
// Print the next N characters in the buffer.
printf("| ");
// Otherwise, print the characters starting from the buffer position.
// Print spaces for unprintable or newline characters.
for (int i=0;i<LOG_SMALL_BUFFER_LEN;i++) {
printf("%c", printable_char(next[i]));
}
printf(" ");
}
if (current_index) {
printf("| %*u ", LOG_INDEX_LEN, *current_index);
} else {
printf("| %-*s ", LOG_INDEX_LEN, "");
}
// printf("| %*u ", LOG_INDEX_LEN, structurals.next_tape_index());
printf("| %-s ", detail);
printf("|\n");
}
}
} // namespace logger
} // unnamed namespace
} // namespace fallback
} // namespace simdjson
/* end file src/generic/stage2/logger.h */
namespace simdjson {
namespace fallback {
namespace {
namespace stage2 {
class json_iterator {
public:
const uint8_t* const buf;
uint32_t *next_structural;
dom_parser_implementation &dom_parser;
uint32_t depth{0};
/**
* Walk the JSON document.
*
* The visitor receives callbacks when values are encountered. All callbacks pass the iterator as
* the first parameter; some callbacks have other parameters as well:
*
* - visit_document_start() - at the beginning.
* - visit_document_end() - at the end (if things were successful).
*
* - visit_array_start() - at the start `[` of a non-empty array.
* - visit_array_end() - at the end `]` of a non-empty array.
* - visit_empty_array() - when an empty array is encountered.
*
* - visit_object_end() - at the start `]` of a non-empty object.
* - visit_object_start() - at the end `]` of a non-empty object.
* - visit_empty_object() - when an empty object is encountered.
* - visit_key(const uint8_t *key) - when a key in an object field is encountered. key is
* guaranteed to point at the first quote of the string (`"key"`).
* - visit_primitive(const uint8_t *value) - when a value is a string, number, boolean or null.
* - visit_root_primitive(iter, uint8_t *value) - when the top-level value is a string, number, boolean or null.
*
* - increment_count(iter) - each time a value is found in an array or object.
*/
template<bool STREAMING, typename V>
simdjson_warn_unused simdjson_really_inline error_code walk_document(V &visitor) noexcept;
/**
* Create an iterator capable of walking a JSON document.
*
* The document must have already passed through stage 1.
*/
simdjson_really_inline json_iterator(dom_parser_implementation &_dom_parser, size_t start_structural_index);
/**
* Look at the next token.
*
* Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)).
*
* They may include invalid JSON as well (such as `1.2.3` or `ture`).
*/
simdjson_really_inline const uint8_t *peek() const noexcept;
/**
* Advance to the next token.
*
* Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)).
*
* They may include invalid JSON as well (such as `1.2.3` or `ture`).
*/
simdjson_really_inline const uint8_t *advance() noexcept;
/**
* Get the remaining length of the document, from the start of the current token.
*/
simdjson_really_inline size_t remaining_len() const noexcept;
/**
* Check if we are at the end of the document.
*
* If this is true, there are no more tokens.
*/
simdjson_really_inline bool at_eof() const noexcept;
/**
* Check if we are at the beginning of the document.
*/
simdjson_really_inline bool at_beginning() const noexcept;
simdjson_really_inline uint8_t last_structural() const noexcept;
/**
* Log that a value has been found.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_value(const char *type) const noexcept;
/**
* Log the start of a multipart value.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_start_value(const char *type) const noexcept;
/**
* Log the end of a multipart value.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_end_value(const char *type) const noexcept;
/**
* Log an error.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_error(const char *error) const noexcept;
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code visit_root_primitive(V &visitor, const uint8_t *value) noexcept;
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code visit_primitive(V &visitor, const uint8_t *value) noexcept;
};
template<bool STREAMING, typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::walk_document(V &visitor) noexcept {
logger::log_start();
//
// Start the document
//
if (at_eof()) { return EMPTY; }
log_start_value("document");
SIMDJSON_TRY( visitor.visit_document_start(*this) );
//
// Read first value
//
{
auto value = advance();
// Make sure the outer hash or array is closed before continuing; otherwise, there are ways we
// could get into memory corruption. See https://github.com/simdjson/simdjson/issues/906
if (!STREAMING) {
switch (*value) {
case '{': if (last_structural() != '}') { return TAPE_ERROR; }; break;
case '[': if (last_structural() != ']') { return TAPE_ERROR; }; break;
}
}
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_root_primitive(*this, value) ); break;
}
}
goto document_end;
//
// Object parser states
//
object_begin:
log_start_value("object");
depth++;
if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; }
dom_parser.is_array[depth] = false;
SIMDJSON_TRY( visitor.visit_object_start(*this) );
{
auto key = advance();
if (*key != '"') { log_error("Object does not start with a key"); return TAPE_ERROR; }
SIMDJSON_TRY( visitor.increment_count(*this) );
SIMDJSON_TRY( visitor.visit_key(*this, key) );
}
object_field:
if (simdjson_unlikely( *advance() != ':' )) { log_error("Missing colon after key in object"); return TAPE_ERROR; }
{
auto value = advance();
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_primitive(*this, value) ); break;
}
}
object_continue:
switch (*advance()) {
case ',':
SIMDJSON_TRY( visitor.increment_count(*this) );
{
auto key = advance();
if (simdjson_unlikely( *key != '"' )) { log_error("Key string missing at beginning of field in object"); return TAPE_ERROR; }
SIMDJSON_TRY( visitor.visit_key(*this, key) );
}
goto object_field;
case '}': log_end_value("object"); SIMDJSON_TRY( visitor.visit_object_end(*this) ); goto scope_end;
default: log_error("No comma between object fields"); return TAPE_ERROR;
}
scope_end:
depth--;
if (depth == 0) { goto document_end; }
if (dom_parser.is_array[depth]) { goto array_continue; }
goto object_continue;
//
// Array parser states
//
array_begin:
log_start_value("array");
depth++;
if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; }
dom_parser.is_array[depth] = true;
SIMDJSON_TRY( visitor.visit_array_start(*this) );
SIMDJSON_TRY( visitor.increment_count(*this) );
array_value:
{
auto value = advance();
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_primitive(*this, value) ); break;
}
}
array_continue:
switch (*advance()) {
case ',': SIMDJSON_TRY( visitor.increment_count(*this) ); goto array_value;
case ']': log_end_value("array"); SIMDJSON_TRY( visitor.visit_array_end(*this) ); goto scope_end;
default: log_error("Missing comma between array values"); return TAPE_ERROR;
}
document_end:
log_end_value("document");
SIMDJSON_TRY( visitor.visit_document_end(*this) );
dom_parser.next_structural_index = uint32_t(next_structural - &dom_parser.structural_indexes[0]);
// If we didn't make it to the end, it's an error
if ( !STREAMING && dom_parser.next_structural_index != dom_parser.n_structural_indexes ) {
log_error("More than one JSON value at the root of the document, or extra characters at the end of the JSON!");
return TAPE_ERROR;
}
return SUCCESS;
} // walk_document()
simdjson_really_inline json_iterator::json_iterator(dom_parser_implementation &_dom_parser, size_t start_structural_index)
: buf{_dom_parser.buf},
next_structural{&_dom_parser.structural_indexes[start_structural_index]},
dom_parser{_dom_parser} {
}
simdjson_really_inline const uint8_t *json_iterator::peek() const noexcept {
return &buf[*(next_structural)];
}
simdjson_really_inline const uint8_t *json_iterator::advance() noexcept {
return &buf[*(next_structural++)];
}
simdjson_really_inline size_t json_iterator::remaining_len() const noexcept {
return dom_parser.len - *(next_structural-1);
}
simdjson_really_inline bool json_iterator::at_eof() const noexcept {
return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes];
}
simdjson_really_inline bool json_iterator::at_beginning() const noexcept {
return next_structural == dom_parser.structural_indexes.get();
}
simdjson_really_inline uint8_t json_iterator::last_structural() const noexcept {
return buf[dom_parser.structural_indexes[dom_parser.n_structural_indexes - 1]];
}
simdjson_really_inline void json_iterator::log_value(const char *type) const noexcept {
logger::log_line(*this, "", type, "");
}
simdjson_really_inline void json_iterator::log_start_value(const char *type) const noexcept {
logger::log_line(*this, "+", type, "");
if (logger::LOG_ENABLED) { logger::log_depth++; }
}
simdjson_really_inline void json_iterator::log_end_value(const char *type) const noexcept {
if (logger::LOG_ENABLED) { logger::log_depth--; }
logger::log_line(*this, "-", type, "");
}
simdjson_really_inline void json_iterator::log_error(const char *error) const noexcept {
logger::log_line(*this, "", "ERROR", error);
}
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::visit_root_primitive(V &visitor, const uint8_t *value) noexcept {
switch (*value) {
case '"': return visitor.visit_root_string(*this, value);
case 't': return visitor.visit_root_true_atom(*this, value);
case 'f': return visitor.visit_root_false_atom(*this, value);
case 'n': return visitor.visit_root_null_atom(*this, value);
case '-':
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
return visitor.visit_root_number(*this, value);
default:
log_error("Document starts with a non-value character");
return TAPE_ERROR;
}
}
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::visit_primitive(V &visitor, const uint8_t *value) noexcept {
switch (*value) {
case '"': return visitor.visit_string(*this, value);
case 't': return visitor.visit_true_atom(*this, value);
case 'f': return visitor.visit_false_atom(*this, value);
case 'n': return visitor.visit_null_atom(*this, value);
case '-':
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
return visitor.visit_number(*this, value);
default:
log_error("Non-value found when value was expected!");
return TAPE_ERROR;
}
}
} // namespace stage2
} // unnamed namespace
} // namespace fallback
} // namespace simdjson
/* end file src/generic/stage2/json_iterator.h */
/* begin file src/generic/stage2/tape_writer.h */
namespace simdjson {
namespace fallback {
namespace {
namespace stage2 {
struct tape_writer {
/** The next place to write to tape */
uint64_t *next_tape_loc;
/** Write a signed 64-bit value to tape. */
simdjson_really_inline void append_s64(int64_t value) noexcept;
/** Write an unsigned 64-bit value to tape. */
simdjson_really_inline void append_u64(uint64_t value) noexcept;
/** Write a double value to tape. */
simdjson_really_inline void append_double(double value) noexcept;
/**
* Append a tape entry (an 8-bit type,and 56 bits worth of value).
*/
simdjson_really_inline void append(uint64_t val, internal::tape_type t) noexcept;
/**
* Skip the current tape entry without writing.
*
* Used to skip the start of the container, since we'll come back later to fill it in when the
* container ends.
*/
simdjson_really_inline void skip() noexcept;
/**
* Skip the number of tape entries necessary to write a large u64 or i64.
*/
simdjson_really_inline void skip_large_integer() noexcept;
/**
* Skip the number of tape entries necessary to write a double.
*/
simdjson_really_inline void skip_double() noexcept;
/**
* Write a value to a known location on tape.
*
* Used to go back and write out the start of a container after the container ends.
*/
simdjson_really_inline static void write(uint64_t &tape_loc, uint64_t val, internal::tape_type t) noexcept;
private:
/**
* Append both the tape entry, and a supplementary value following it. Used for types that need
* all 64 bits, such as double and uint64_t.
*/
template<typename T>
simdjson_really_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept;
}; // struct number_writer
simdjson_really_inline void tape_writer::append_s64(int64_t value) noexcept {
append2(0, value, internal::tape_type::INT64);
}
simdjson_really_inline void tape_writer::append_u64(uint64_t value) noexcept {
append(0, internal::tape_type::UINT64);
*next_tape_loc = value;
next_tape_loc++;
}
/** Write a double value to tape. */
simdjson_really_inline void tape_writer::append_double(double value) noexcept {
append2(0, value, internal::tape_type::DOUBLE);
}
simdjson_really_inline void tape_writer::skip() noexcept {
next_tape_loc++;
}
simdjson_really_inline void tape_writer::skip_large_integer() noexcept {
next_tape_loc += 2;
}
simdjson_really_inline void tape_writer::skip_double() noexcept {
next_tape_loc += 2;
}
simdjson_really_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept {
*next_tape_loc = val | ((uint64_t(char(t))) << 56);
next_tape_loc++;
}
template<typename T>
simdjson_really_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept {
append(val, t);
static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!");
memcpy(next_tape_loc, &val2, sizeof(val2));
next_tape_loc++;
}
simdjson_really_inline void tape_writer::write(uint64_t &tape_loc, uint64_t val, internal::tape_type t) noexcept {
tape_loc = val | ((uint64_t(char(t))) << 56);
}
} // namespace stage2
} // unnamed namespace
} // namespace fallback
} // namespace simdjson
/* end file src/generic/stage2/tape_writer.h */
namespace simdjson {
namespace fallback {
namespace {
namespace stage2 {
struct tape_builder {
template<bool STREAMING>
simdjson_warn_unused static simdjson_really_inline error_code parse_document(
dom_parser_implementation &dom_parser,
dom::document &doc) noexcept;
/** Called when a non-empty document starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_document_start(json_iterator &iter) noexcept;
/** Called when a non-empty document ends without error. */
simdjson_warn_unused simdjson_really_inline error_code visit_document_end(json_iterator &iter) noexcept;
/** Called when a non-empty array starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_array_start(json_iterator &iter) noexcept;
/** Called when a non-empty array ends. */
simdjson_warn_unused simdjson_really_inline error_code visit_array_end(json_iterator &iter) noexcept;
/** Called when an empty array is found. */
simdjson_warn_unused simdjson_really_inline error_code visit_empty_array(json_iterator &iter) noexcept;
/** Called when a non-empty object starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_object_start(json_iterator &iter) noexcept;
/**
* Called when a key in a field is encountered.
*
* primitive, visit_object_start, visit_empty_object, visit_array_start, or visit_empty_array
* will be called after this with the field value.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_key(json_iterator &iter, const uint8_t *key) noexcept;
/** Called when a non-empty object ends. */
simdjson_warn_unused simdjson_really_inline error_code visit_object_end(json_iterator &iter) noexcept;
/** Called when an empty object is found. */
simdjson_warn_unused simdjson_really_inline error_code visit_empty_object(json_iterator &iter) noexcept;
/**
* Called when a string, number, boolean or null is found.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_primitive(json_iterator &iter, const uint8_t *value) noexcept;
/**
* Called when a string, number, boolean or null is found at the top level of a document (i.e.
* when there is no array or object and the entire document is a single string, number, boolean or
* null.
*
* This is separate from primitive() because simdjson's normal primitive parsing routines assume
* there is at least one more token after the value, which is only true in an array or object.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_root_primitive(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_string(json_iterator &iter, const uint8_t *value, bool key = false) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_number(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_true_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_false_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_null_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_string(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_number(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_true_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_false_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_null_atom(json_iterator &iter, const uint8_t *value) noexcept;
/** Called each time a new field or element in an array or object is found. */
simdjson_warn_unused simdjson_really_inline error_code increment_count(json_iterator &iter) noexcept;
/** Next location to write to tape */
tape_writer tape;
private:
/** Next write location in the string buf for stage 2 parsing */
uint8_t *current_string_buf_loc;
simdjson_really_inline tape_builder(dom::document &doc) noexcept;
simdjson_really_inline uint32_t next_tape_index(json_iterator &iter) const noexcept;
simdjson_really_inline void start_container(json_iterator &iter) noexcept;
simdjson_warn_unused simdjson_really_inline error_code end_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept;
simdjson_warn_unused simdjson_really_inline error_code empty_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept;
simdjson_really_inline uint8_t *on_start_string(json_iterator &iter) noexcept;
simdjson_really_inline void on_end_string(uint8_t *dst) noexcept;
}; // class tape_builder
template<bool STREAMING>
simdjson_warn_unused simdjson_really_inline error_code tape_builder::parse_document(
dom_parser_implementation &dom_parser,
dom::document &doc) noexcept {
dom_parser.doc = &doc;
json_iterator iter(dom_parser, STREAMING ? dom_parser.next_structural_index : 0);
tape_builder builder(doc);
return iter.walk_document<STREAMING>(builder);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_primitive(json_iterator &iter, const uint8_t *value) noexcept {
return iter.visit_root_primitive(*this, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_primitive(json_iterator &iter, const uint8_t *value) noexcept {
return iter.visit_primitive(*this, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_empty_object(json_iterator &iter) noexcept {
return empty_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_empty_array(json_iterator &iter) noexcept {
return empty_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_document_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_object_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_array_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_object_end(json_iterator &iter) noexcept {
return end_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_array_end(json_iterator &iter) noexcept {
return end_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_document_end(json_iterator &iter) noexcept {
constexpr uint32_t start_tape_index = 0;
tape.append(start_tape_index, internal::tape_type::ROOT);
tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter), internal::tape_type::ROOT);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_key(json_iterator &iter, const uint8_t *key) noexcept {
return visit_string(iter, key, true);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::increment_count(json_iterator &iter) noexcept {
iter.dom_parser.open_containers[iter.depth].count++; // we have a key value pair in the object at parser.dom_parser.depth - 1
return SUCCESS;
}
simdjson_really_inline tape_builder::tape_builder(dom::document &doc) noexcept : tape{doc.tape.get()}, current_string_buf_loc{doc.string_buf.get()} {}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_string(json_iterator &iter, const uint8_t *value, bool key) noexcept {
iter.log_value(key ? "key" : "string");
uint8_t *dst = on_start_string(iter);
dst = stringparsing::parse_string(value+1, dst);
if (dst == nullptr) {
iter.log_error("Invalid escape in string");
return STRING_ERROR;
}
on_end_string(dst);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_string(json_iterator &iter, const uint8_t *value) noexcept {
return visit_string(iter, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_number(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("number");
return numberparsing::parse_number(value, tape);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_number(json_iterator &iter, const uint8_t *value) noexcept {
//
// We need to make a copy to make sure that the string is space terminated.
// This is not about padding the input, which should already padded up
// to len + SIMDJSON_PADDING. However, we have no control at this stage
// on how the padding was done. What if the input string was padded with nulls?
// It is quite common for an input string to have an extra null character (C string).
// We do not want to allow 9\0 (where \0 is the null character) inside a JSON
// document, but the string "9\0" by itself is fine. So we make a copy and
// pad the input with spaces when we know that there is just one input element.
// This copy is relatively expensive, but it will almost never be called in
// practice unless you are in the strange scenario where you have many JSON
// documents made of single atoms.
//
uint8_t *copy = static_cast<uint8_t *>(malloc(iter.remaining_len() + SIMDJSON_PADDING));
if (copy == nullptr) { return MEMALLOC; }
std::memcpy(copy, value, iter.remaining_len());
std::memset(copy + iter.remaining_len(), ' ', SIMDJSON_PADDING);
error_code error = visit_number(iter, copy);
free(copy);
return error;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_true_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("true");
if (!atomparsing::is_valid_true_atom(value)) { return T_ATOM_ERROR; }
tape.append(0, internal::tape_type::TRUE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_true_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("true");
if (!atomparsing::is_valid_true_atom(value, iter.remaining_len())) { return T_ATOM_ERROR; }
tape.append(0, internal::tape_type::TRUE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_false_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("false");
if (!atomparsing::is_valid_false_atom(value)) { return F_ATOM_ERROR; }
tape.append(0, internal::tape_type::FALSE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_false_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("false");
if (!atomparsing::is_valid_false_atom(value, iter.remaining_len())) { return F_ATOM_ERROR; }
tape.append(0, internal::tape_type::FALSE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_null_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("null");
if (!atomparsing::is_valid_null_atom(value)) { return N_ATOM_ERROR; }
tape.append(0, internal::tape_type::NULL_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_null_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("null");
if (!atomparsing::is_valid_null_atom(value, iter.remaining_len())) { return N_ATOM_ERROR; }
tape.append(0, internal::tape_type::NULL_VALUE);
return SUCCESS;
}
// private:
simdjson_really_inline uint32_t tape_builder::next_tape_index(json_iterator &iter) const noexcept {
return uint32_t(tape.next_tape_loc - iter.dom_parser.doc->tape.get());
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::empty_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept {
auto start_index = next_tape_index(iter);
tape.append(start_index+2, start);
tape.append(start_index, end);
return SUCCESS;
}
simdjson_really_inline void tape_builder::start_container(json_iterator &iter) noexcept {
iter.dom_parser.open_containers[iter.depth].tape_index = next_tape_index(iter);
iter.dom_parser.open_containers[iter.depth].count = 0;
tape.skip(); // We don't actually *write* the start element until the end.
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::end_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept {
// Write the ending tape element, pointing at the start location
const uint32_t start_tape_index = iter.dom_parser.open_containers[iter.depth].tape_index;
tape.append(start_tape_index, end);
// Write the start tape element, pointing at the end location (and including count)
// count can overflow if it exceeds 24 bits... so we saturate
// the convention being that a cnt of 0xffffff or more is undetermined in value (>= 0xffffff).
const uint32_t count = iter.dom_parser.open_containers[iter.depth].count;
const uint32_t cntsat = count > 0xFFFFFF ? 0xFFFFFF : count;
tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter) | (uint64_t(cntsat) << 32), start);
return SUCCESS;
}
simdjson_really_inline uint8_t *tape_builder::on_start_string(json_iterator &iter) noexcept {
// we advance the point, accounting for the fact that we have a NULL termination
tape.append(current_string_buf_loc - iter.dom_parser.doc->string_buf.get(), internal::tape_type::STRING);
return current_string_buf_loc + sizeof(uint32_t);
}
simdjson_really_inline void tape_builder::on_end_string(uint8_t *dst) noexcept {
uint32_t str_length = uint32_t(dst - (current_string_buf_loc + sizeof(uint32_t)));
// TODO check for overflow in case someone has a crazy string (>=4GB?)
// But only add the overflow check when the document itself exceeds 4GB
// Currently unneeded because we refuse to parse docs larger or equal to 4GB.
memcpy(current_string_buf_loc, &str_length, sizeof(uint32_t));
// NULL termination is still handy if you expect all your strings to
// be NULL terminated? It comes at a small cost
*dst = 0;
current_string_buf_loc = dst + 1;
}
} // namespace stage2
} // unnamed namespace
} // namespace fallback
} // namespace simdjson
/* end file src/generic/stage2/tape_builder.h */
namespace simdjson {
namespace fallback {
simdjson_warn_unused error_code dom_parser_implementation::stage2(dom::document &_doc) noexcept {
return stage2::tape_builder::parse_document<false>(*this, _doc);
}
simdjson_warn_unused error_code dom_parser_implementation::stage2_next(dom::document &_doc) noexcept {
return stage2::tape_builder::parse_document<true>(*this, _doc);
}
simdjson_warn_unused error_code dom_parser_implementation::parse(const uint8_t *_buf, size_t _len, dom::document &_doc) noexcept {
auto error = stage1(_buf, _len, false);
if (error) { return error; }
return stage2(_doc);
}
} // namespace fallback
} // namespace simdjson
/* begin file include/simdjson/fallback/end.h */
#undef fallback
/* end file include/simdjson/fallback/end.h */
/* end file src/fallback/dom_parser_implementation.cpp */
#endif
#if SIMDJSON_IMPLEMENTATION_HASWELL
/* begin file src/haswell/implementation.cpp */
/* begin file include/simdjson/haswell/begin.h */
// redefining SIMDJSON_IMPLEMENTATION to "haswell"
// #define SIMDJSON_IMPLEMENTATION haswell
SIMDJSON_TARGET_HASWELL
/* end file include/simdjson/haswell/begin.h */
namespace simdjson {
namespace haswell {
simdjson_warn_unused error_code implementation::create_dom_parser_implementation(
size_t capacity,
size_t max_depth,
std::unique_ptr<internal::dom_parser_implementation>& dst
) const noexcept {
dst.reset( new (std::nothrow) dom_parser_implementation() );
if (!dst) { return MEMALLOC; }
dst->set_capacity(capacity);
dst->set_max_depth(max_depth);
return SUCCESS;
}
} // namespace haswell
} // namespace simdjson
/* begin file include/simdjson/haswell/end.h */
SIMDJSON_UNTARGET_REGION
#undef haswell
/* end file include/simdjson/haswell/end.h */
/* end file src/haswell/implementation.cpp */
/* begin file src/haswell/dom_parser_implementation.cpp */
/* begin file include/simdjson/haswell/begin.h */
// redefining SIMDJSON_IMPLEMENTATION to "haswell"
// #define SIMDJSON_IMPLEMENTATION haswell
SIMDJSON_TARGET_HASWELL
/* end file include/simdjson/haswell/begin.h */
//
// Stage 1
//
namespace simdjson {
namespace haswell {
namespace {
using namespace simd;
struct json_character_block {
static simdjson_really_inline json_character_block classify(const simd::simd8x64<uint8_t>& in);
// ASCII white-space ('\r','\n','\t',' ')
simdjson_really_inline uint64_t whitespace() const;
// non-quote structural characters (comma, colon, braces, brackets)
simdjson_really_inline uint64_t op() const;
// neither a structural character nor a white-space, so letters, numbers and quotes
simdjson_really_inline uint64_t scalar() const;
uint64_t _whitespace; // ASCII white-space ('\r','\n','\t',' ')
uint64_t _op; // structural characters (comma, colon, braces, brackets but not quotes)
};
simdjson_really_inline uint64_t json_character_block::whitespace() const { return _whitespace; }
simdjson_really_inline uint64_t json_character_block::op() const { return _op; }
simdjson_really_inline uint64_t json_character_block::scalar() const { return ~(op() | whitespace()); }
// This identifies structural characters (comma, colon, braces, brackets),
// and ASCII white-space ('\r','\n','\t',' ').
simdjson_really_inline json_character_block json_character_block::classify(const simd::simd8x64<uint8_t>& in) {
// These lookups rely on the fact that anything < 127 will match the lower 4 bits, which is why
// we can't use the generic lookup_16.
const auto whitespace_table = simd8<uint8_t>::repeat_16(' ', 100, 100, 100, 17, 100, 113, 2, 100, '\t', '\n', 112, 100, '\r', 100, 100);
// The 6 operators (:,[]{}) have these values:
//
// , 2C
// : 3A
// [ 5B
// { 7B
// ] 5D
// } 7D
//
// If you use | 0x20 to turn [ and ] into { and }, the lower 4 bits of each character is unique.
// We exploit this, using a simd 4-bit lookup to tell us which character match against, and then
// match it (against | 0x20).
//
// To prevent recognizing other characters, everything else gets compared with 0, which cannot
// match due to the | 0x20.
//
// NOTE: Due to the | 0x20, this ALSO treats <FF> and <SUB> (control characters 0C and 1A) like ,
// and :. This gets caught in stage 2, which checks the actual character to ensure the right
// operators are in the right places.
const auto op_table = simd8<uint8_t>::repeat_16(
0, 0, 0, 0,
0, 0, 0, 0,
0, 0, ':', '{', // : = 3A, [ = 5B, { = 7B
',', '}', 0, 0 // , = 2C, ] = 5D, } = 7D
);
// We compute whitespace and op separately. If later code only uses one or the
// other, given the fact that all functions are aggressively inlined, we can
// hope that useless computations will be omitted. This is namely case when
// minifying (we only need whitespace).
const uint64_t whitespace = in.eq({
_mm256_shuffle_epi8(whitespace_table, in.chunks[0]),
_mm256_shuffle_epi8(whitespace_table, in.chunks[1])
});
// Turn [ and ] into { and }
const simd8x64<uint8_t> curlified{
in.chunks[0] | 0x20,
in.chunks[1] | 0x20
};
const uint64_t op = curlified.eq({
_mm256_shuffle_epi8(op_table, in.chunks[0]),
_mm256_shuffle_epi8(op_table, in.chunks[1])
});
return { whitespace, op };
}
simdjson_really_inline bool is_ascii(const simd8x64<uint8_t>& input) {
return input.reduce_or().is_ascii();
}
simdjson_unused simdjson_really_inline simd8<bool> must_be_continuation(const simd8<uint8_t> prev1, const simd8<uint8_t> prev2, const simd8<uint8_t> prev3) {
simd8<uint8_t> is_second_byte = prev1.saturating_sub(0b11000000u-1); // Only 11______ will be > 0
simd8<uint8_t> is_third_byte = prev2.saturating_sub(0b11100000u-1); // Only 111_____ will be > 0
simd8<uint8_t> is_fourth_byte = prev3.saturating_sub(0b11110000u-1); // Only 1111____ will be > 0
// Caller requires a bool (all 1's). All values resulting from the subtraction will be <= 64, so signed comparison is fine.
return simd8<int8_t>(is_second_byte | is_third_byte | is_fourth_byte) > int8_t(0);
}
simdjson_really_inline simd8<bool> must_be_2_3_continuation(const simd8<uint8_t> prev2, const simd8<uint8_t> prev3) {
simd8<uint8_t> is_third_byte = prev2.saturating_sub(0b11100000u-1); // Only 111_____ will be > 0
simd8<uint8_t> is_fourth_byte = prev3.saturating_sub(0b11110000u-1); // Only 1111____ will be > 0
// Caller requires a bool (all 1's). All values resulting from the subtraction will be <= 64, so signed comparison is fine.
return simd8<int8_t>(is_third_byte | is_fourth_byte) > int8_t(0);
}
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* begin file src/generic/stage1/utf8_lookup4_algorithm.h */
namespace simdjson {
namespace haswell {
namespace {
namespace utf8_validation {
using namespace simd;
simdjson_really_inline simd8<uint8_t> check_special_cases(const simd8<uint8_t> input, const simd8<uint8_t> prev1) {
// Bit 0 = Too Short (lead byte/ASCII followed by lead byte/ASCII)
// Bit 1 = Too Long (ASCII followed by continuation)
// Bit 2 = Overlong 3-byte
// Bit 4 = Surrogate
// Bit 5 = Overlong 2-byte
// Bit 7 = Two Continuations
constexpr const uint8_t TOO_SHORT = 1<<0; // 11______ 0_______
// 11______ 11______
constexpr const uint8_t TOO_LONG = 1<<1; // 0_______ 10______
constexpr const uint8_t OVERLONG_3 = 1<<2; // 11100000 100_____
constexpr const uint8_t SURROGATE = 1<<4; // 11101101 101_____
constexpr const uint8_t OVERLONG_2 = 1<<5; // 1100000_ 10______
constexpr const uint8_t TWO_CONTS = 1<<7; // 10______ 10______
constexpr const uint8_t TOO_LARGE = 1<<3; // 11110100 1001____
// 11110100 101_____
// 11110101 1001____
// 11110101 101_____
// 1111011_ 1001____
// 1111011_ 101_____
// 11111___ 1001____
// 11111___ 101_____
constexpr const uint8_t TOO_LARGE_1000 = 1<<6;
// 11110101 1000____
// 1111011_ 1000____
// 11111___ 1000____
constexpr const uint8_t OVERLONG_4 = 1<<6; // 11110000 1000____
const simd8<uint8_t> byte_1_high = prev1.shr<4>().lookup_16<uint8_t>(
// 0_______ ________ <ASCII in byte 1>
TOO_LONG, TOO_LONG, TOO_LONG, TOO_LONG,
TOO_LONG, TOO_LONG, TOO_LONG, TOO_LONG,
// 10______ ________ <continuation in byte 1>
TWO_CONTS, TWO_CONTS, TWO_CONTS, TWO_CONTS,
// 1100____ ________ <two byte lead in byte 1>
TOO_SHORT | OVERLONG_2,
// 1101____ ________ <two byte lead in byte 1>
TOO_SHORT,
// 1110____ ________ <three byte lead in byte 1>
TOO_SHORT | OVERLONG_3 | SURROGATE,
// 1111____ ________ <four+ byte lead in byte 1>
TOO_SHORT | TOO_LARGE | TOO_LARGE_1000 | OVERLONG_4
);
constexpr const uint8_t CARRY = TOO_SHORT | TOO_LONG | TWO_CONTS; // These all have ____ in byte 1 .
const simd8<uint8_t> byte_1_low = (prev1 & 0x0F).lookup_16<uint8_t>(
// ____0000 ________
CARRY | OVERLONG_3 | OVERLONG_2 | OVERLONG_4,
// ____0001 ________
CARRY | OVERLONG_2,
// ____001_ ________
CARRY,
CARRY,
// ____0100 ________
CARRY | TOO_LARGE,
// ____0101 ________
CARRY | TOO_LARGE | TOO_LARGE_1000,
// ____011_ ________
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
// ____1___ ________
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
// ____1101 ________
CARRY | TOO_LARGE | TOO_LARGE_1000 | SURROGATE,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000
);
const simd8<uint8_t> byte_2_high = input.shr<4>().lookup_16<uint8_t>(
// ________ 0_______ <ASCII in byte 2>
TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT,
TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT,
// ________ 1000____
TOO_LONG | OVERLONG_2 | TWO_CONTS | OVERLONG_3 | TOO_LARGE_1000 | OVERLONG_4,
// ________ 1001____
TOO_LONG | OVERLONG_2 | TWO_CONTS | OVERLONG_3 | TOO_LARGE,
// ________ 101_____
TOO_LONG | OVERLONG_2 | TWO_CONTS | SURROGATE | TOO_LARGE,
TOO_LONG | OVERLONG_2 | TWO_CONTS | SURROGATE | TOO_LARGE,
// ________ 11______
TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT
);
return (byte_1_high & byte_1_low & byte_2_high);
}
simdjson_really_inline simd8<uint8_t> check_multibyte_lengths(const simd8<uint8_t> input,
const simd8<uint8_t> prev_input, const simd8<uint8_t> sc) {
simd8<uint8_t> prev2 = input.prev<2>(prev_input);
simd8<uint8_t> prev3 = input.prev<3>(prev_input);
simd8<uint8_t> must23 = simd8<uint8_t>(must_be_2_3_continuation(prev2, prev3));
simd8<uint8_t> must23_80 = must23 & uint8_t(0x80);
return must23_80 ^ sc;
}
//
// Return nonzero if there are incomplete multibyte characters at the end of the block:
// e.g. if there is a 4-byte character, but it's 3 bytes from the end.
//
simdjson_really_inline simd8<uint8_t> is_incomplete(const simd8<uint8_t> input) {
// If the previous input's last 3 bytes match this, they're too short (they ended at EOF):
// ... 1111____ 111_____ 11______
static const uint8_t max_array[32] = {
255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 0b11110000u-1, 0b11100000u-1, 0b11000000u-1
};
const simd8<uint8_t> max_value(&max_array[sizeof(max_array)-sizeof(simd8<uint8_t>)]);
return input.gt_bits(max_value);
}
struct utf8_checker {
// If this is nonzero, there has been a UTF-8 error.
simd8<uint8_t> error;
// The last input we received
simd8<uint8_t> prev_input_block;
// Whether the last input we received was incomplete (used for ASCII fast path)
simd8<uint8_t> prev_incomplete;
//
// Check whether the current bytes are valid UTF-8.
//
simdjson_really_inline void check_utf8_bytes(const simd8<uint8_t> input, const simd8<uint8_t> prev_input) {
// Flip prev1...prev3 so we can easily determine if they are 2+, 3+ or 4+ lead bytes
// (2, 3, 4-byte leads become large positive numbers instead of small negative numbers)
simd8<uint8_t> prev1 = input.prev<1>(prev_input);
simd8<uint8_t> sc = check_special_cases(input, prev1);
this->error |= check_multibyte_lengths(input, prev_input, sc);
}
// The only problem that can happen at EOF is that a multibyte character is too short
// or a byte value too large in the last bytes: check_special_cases only checks for bytes
// too large in the first of two bytes.
simdjson_really_inline void check_eof() {
// If the previous block had incomplete UTF-8 characters at the end, an ASCII block can't
// possibly finish them.
this->error |= this->prev_incomplete;
}
simdjson_really_inline void check_next_input(const simd8x64<uint8_t>& input) {
if(simdjson_likely(is_ascii(input))) {
this->error |= this->prev_incomplete;
} else {
// you might think that a for-loop would work, but under Visual Studio, it is not good enough.
static_assert((simd8x64<uint8_t>::NUM_CHUNKS == 2) || (simd8x64<uint8_t>::NUM_CHUNKS == 4),
"We support either two or four chunks per 64-byte block.");
if(simd8x64<uint8_t>::NUM_CHUNKS == 2) {
this->check_utf8_bytes(input.chunks[0], this->prev_input_block);
this->check_utf8_bytes(input.chunks[1], input.chunks[0]);
} else if(simd8x64<uint8_t>::NUM_CHUNKS == 4) {
this->check_utf8_bytes(input.chunks[0], this->prev_input_block);
this->check_utf8_bytes(input.chunks[1], input.chunks[0]);
this->check_utf8_bytes(input.chunks[2], input.chunks[1]);
this->check_utf8_bytes(input.chunks[3], input.chunks[2]);
}
this->prev_incomplete = is_incomplete(input.chunks[simd8x64<uint8_t>::NUM_CHUNKS-1]);
this->prev_input_block = input.chunks[simd8x64<uint8_t>::NUM_CHUNKS-1];
}
}
// do not forget to call check_eof!
simdjson_really_inline error_code errors() {
return this->error.any_bits_set_anywhere() ? error_code::UTF8_ERROR : error_code::SUCCESS;
}
}; // struct utf8_checker
} // namespace utf8_validation
using utf8_validation::utf8_checker;
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* end file src/generic/stage1/utf8_lookup4_algorithm.h */
/* begin file src/generic/stage1/json_structural_indexer.h */
// This file contains the common code every implementation uses in stage1
// It is intended to be included multiple times and compiled multiple times
// We assume the file in which it is included already includes
// "simdjson/stage1.h" (this simplifies amalgation)
/* begin file src/generic/stage1/buf_block_reader.h */
namespace simdjson {
namespace haswell {
namespace {
// Walks through a buffer in block-sized increments, loading the last part with spaces
template<size_t STEP_SIZE>
struct buf_block_reader {
public:
simdjson_really_inline buf_block_reader(const uint8_t *_buf, size_t _len);
simdjson_really_inline size_t block_index();
simdjson_really_inline bool has_full_block() const;
simdjson_really_inline const uint8_t *full_block() const;
/**
* Get the last block, padded with spaces.
*
* There will always be a last block, with at least 1 byte, unless len == 0 (in which case this
* function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there
* will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding.
*
* @return the number of effective characters in the last block.
*/
simdjson_really_inline size_t get_remainder(uint8_t *dst) const;
simdjson_really_inline void advance();
private:
const uint8_t *buf;
const size_t len;
const size_t lenminusstep;
size_t idx;
};
// Routines to print masks and text for debugging bitmask operations
simdjson_unused static char * format_input_text_64(const uint8_t *text) {
static char *buf = (char*)malloc(sizeof(simd8x64<uint8_t>) + 1);
for (size_t i=0; i<sizeof(simd8x64<uint8_t>); i++) {
buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]);
}
buf[sizeof(simd8x64<uint8_t>)] = '\0';
return buf;
}
// Routines to print masks and text for debugging bitmask operations
simdjson_unused static char * format_input_text(const simd8x64<uint8_t>& in) {
static char *buf = (char*)malloc(sizeof(simd8x64<uint8_t>) + 1);
in.store((uint8_t*)buf);
for (size_t i=0; i<sizeof(simd8x64<uint8_t>); i++) {
if (buf[i] < ' ') { buf[i] = '_'; }
}
buf[sizeof(simd8x64<uint8_t>)] = '\0';
return buf;
}
simdjson_unused static char * format_mask(uint64_t mask) {
static char *buf = (char*)malloc(64 + 1);
for (size_t i=0; i<64; i++) {
buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' ';
}
buf[64] = '\0';
return buf;
}
template<size_t STEP_SIZE>
simdjson_really_inline buf_block_reader<STEP_SIZE>::buf_block_reader(const uint8_t *_buf, size_t _len) : buf{_buf}, len{_len}, lenminusstep{len < STEP_SIZE ? 0 : len - STEP_SIZE}, idx{0} {}
template<size_t STEP_SIZE>
simdjson_really_inline size_t buf_block_reader<STEP_SIZE>::block_index() { return idx; }
template<size_t STEP_SIZE>
simdjson_really_inline bool buf_block_reader<STEP_SIZE>::has_full_block() const {
return idx < lenminusstep;
}
template<size_t STEP_SIZE>
simdjson_really_inline const uint8_t *buf_block_reader<STEP_SIZE>::full_block() const {
return &buf[idx];
}
template<size_t STEP_SIZE>
simdjson_really_inline size_t buf_block_reader<STEP_SIZE>::get_remainder(uint8_t *dst) const {
if(len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers
std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once.
std::memcpy(dst, buf + idx, len - idx);
return len - idx;
}
template<size_t STEP_SIZE>
simdjson_really_inline void buf_block_reader<STEP_SIZE>::advance() {
idx += STEP_SIZE;
}
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* end file src/generic/stage1/buf_block_reader.h */
/* begin file src/generic/stage1/json_string_scanner.h */
namespace simdjson {
namespace haswell {
namespace {
namespace stage1 {
struct json_string_block {
// Escaped characters (characters following an escape() character)
simdjson_really_inline uint64_t escaped() const { return _escaped; }
// Escape characters (backslashes that are not escaped--i.e. in \\, includes only the first \)
simdjson_really_inline uint64_t escape() const { return _backslash & ~_escaped; }
// Real (non-backslashed) quotes
simdjson_really_inline uint64_t quote() const { return _quote; }
// Start quotes of strings
simdjson_really_inline uint64_t string_start() const { return _quote & _in_string; }
// End quotes of strings
simdjson_really_inline uint64_t string_end() const { return _quote & ~_in_string; }
// Only characters inside the string (not including the quotes)
simdjson_really_inline uint64_t string_content() const { return _in_string & ~_quote; }
// Return a mask of whether the given characters are inside a string (only works on non-quotes)
simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; }
// Return a mask of whether the given characters are inside a string (only works on non-quotes)
simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; }
// Tail of string (everything except the start quote)
simdjson_really_inline uint64_t string_tail() const { return _in_string ^ _quote; }
// backslash characters
uint64_t _backslash;
// escaped characters (backslashed--does not include the hex characters after \u)
uint64_t _escaped;
// real quotes (non-backslashed ones)
uint64_t _quote;
// string characters (includes start quote but not end quote)
uint64_t _in_string;
};
// Scans blocks for string characters, storing the state necessary to do so
class json_string_scanner {
public:
simdjson_really_inline json_string_block next(const simd::simd8x64<uint8_t>& in);
// Returns either UNCLOSED_STRING or SUCCESS
simdjson_really_inline error_code finish();
private:
// Intended to be defined by the implementation
simdjson_really_inline uint64_t find_escaped(uint64_t escape);
simdjson_really_inline uint64_t find_escaped_branchless(uint64_t escape);
// Whether the last iteration was still inside a string (all 1's = true, all 0's = false).
uint64_t prev_in_string = 0ULL;
// Whether the first character of the next iteration is escaped.
uint64_t prev_escaped = 0ULL;
};
//
// Finds escaped characters (characters following \).
//
// Handles runs of backslashes like \\\" and \\\\" correctly (yielding 0101 and 01010, respectively).
//
// Does this by:
// - Shift the escape mask to get potentially escaped characters (characters after backslashes).
// - Mask escaped sequences that start on *even* bits with 1010101010 (odd bits are escaped, even bits are not)
// - Mask escaped sequences that start on *odd* bits with 0101010101 (even bits are escaped, odd bits are not)
//
// To distinguish between escaped sequences starting on even/odd bits, it finds the start of all
// escape sequences, filters out the ones that start on even bits, and adds that to the mask of
// escape sequences. This causes the addition to clear out the sequences starting on odd bits (since
// the start bit causes a carry), and leaves even-bit sequences alone.
//
// Example:
//
// text | \\\ | \\\"\\\" \\\" \\"\\" |
// escape | xxx | xx xxx xxx xx xx | Removed overflow backslash; will | it into follows_escape
// odd_starts | x | x x x | escape & ~even_bits & ~follows_escape
// even_seq | c| cxxx c xx c | c = carry bit -- will be masked out later
// invert_mask | | cxxx c xx c| even_seq << 1
// follows_escape | xx | x xx xxx xxx xx xx | Includes overflow bit
// escaped | x | x x x x x x x x |
// desired | x | x x x x x x x x |
// text | \\\ | \\\"\\\" \\\" \\"\\" |
//
simdjson_really_inline uint64_t json_string_scanner::find_escaped_branchless(uint64_t backslash) {
// If there was overflow, pretend the first character isn't a backslash
backslash &= ~prev_escaped;
uint64_t follows_escape = backslash << 1 | prev_escaped;
// Get sequences starting on even bits by clearing out the odd series using +
const uint64_t even_bits = 0x5555555555555555ULL;
uint64_t odd_sequence_starts = backslash & ~even_bits & ~follows_escape;
uint64_t sequences_starting_on_even_bits;
prev_escaped = add_overflow(odd_sequence_starts, backslash, &sequences_starting_on_even_bits);
uint64_t invert_mask = sequences_starting_on_even_bits << 1; // The mask we want to return is the *escaped* bits, not escapes.
// Mask every other backslashed character as an escaped character
// Flip the mask for sequences that start on even bits, to correct them
return (even_bits ^ invert_mask) & follows_escape;
}
//
// Return a mask of all string characters plus end quotes.
//
// prev_escaped is overflow saying whether the next character is escaped.
// prev_in_string is overflow saying whether we're still in a string.
//
// Backslash sequences outside of quotes will be detected in stage 2.
//
simdjson_really_inline json_string_block json_string_scanner::next(const simd::simd8x64<uint8_t>& in) {
const uint64_t backslash = in.eq('\\');
const uint64_t escaped = find_escaped(backslash);
const uint64_t quote = in.eq('"') & ~escaped;
//
// prefix_xor flips on bits inside the string (and flips off the end quote).
//
// Then we xor with prev_in_string: if we were in a string already, its effect is flipped
// (characters inside strings are outside, and characters outside strings are inside).
//
const uint64_t in_string = prefix_xor(quote) ^ prev_in_string;
//
// Check if we're still in a string at the end of the box so the next block will know
//
// right shift of a signed value expected to be well-defined and standard
// compliant as of C++20, John Regher from Utah U. says this is fine code
//
prev_in_string = uint64_t(static_cast<int64_t>(in_string) >> 63);
// Use ^ to turn the beginning quote off, and the end quote on.
return {
backslash,
escaped,
quote,
in_string
};
}
simdjson_really_inline error_code json_string_scanner::finish() {
if (prev_in_string) {
return UNCLOSED_STRING;
}
return SUCCESS;
}
} // namespace stage1
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* end file src/generic/stage1/json_string_scanner.h */
/* begin file src/generic/stage1/json_scanner.h */
namespace simdjson {
namespace haswell {
namespace {
namespace stage1 {
/**
* A block of scanned json, with information on operators and scalars.
*
* We seek to identify pseudo-structural characters. Anything that is inside
* a string must be omitted (hence & ~_string.string_tail()).
* Otherwise, pseudo-structural characters come in two forms.
* 1. We have the structural characters ([,],{,},:, comma). The
* term 'structural character' is from the JSON RFC.
* 2. We have the 'scalar pseudo-structural characters'.
* Scalars are quotes, and any character except structural characters and white space.
*
* To identify the scalar pseudo-structural characters, we must look at what comes
* before them: it must be a space, a quote or a structural characters.
* Starting with simdjson v0.3, we identify them by
* negation: we identify everything that is followed by a non-quote scalar,
* and we negate that. Whatever remains must be a 'scalar pseudo-structural character'.
*/
struct json_block {
public:
/**
* The start of structurals.
* In simdjson prior to v0.3, these were called the pseudo-structural characters.
**/
simdjson_really_inline uint64_t structural_start() { return potential_structural_start() & ~_string.string_tail(); }
/** All JSON whitespace (i.e. not in a string) */
simdjson_really_inline uint64_t whitespace() { return non_quote_outside_string(_characters.whitespace()); }
// Helpers
/** Whether the given characters are inside a string (only works on non-quotes) */
simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) { return _string.non_quote_inside_string(mask); }
/** Whether the given characters are outside a string (only works on non-quotes) */
simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) { return _string.non_quote_outside_string(mask); }
// string and escape characters
json_string_block _string;
// whitespace, structural characters ('operators'), scalars
json_character_block _characters;
// whether the previous character was a scalar
uint64_t _follows_potential_nonquote_scalar;
private:
// Potential structurals (i.e. disregarding strings)
/**
* structural elements ([,],{,},:, comma) plus scalar starts like 123, true and "abc".
* They may reside inside a string.
**/
simdjson_really_inline uint64_t potential_structural_start() { return _characters.op() | potential_scalar_start(); }
/**
* The start of non-operator runs, like 123, true and "abc".
* It main reside inside a string.
**/
simdjson_really_inline uint64_t potential_scalar_start() {
// The term "scalar" refers to anything except structural characters and white space
// (so letters, numbers, quotes).
// Whenever it is preceded by something that is not a structural element ({,},[,],:, ") nor a white-space
// then we know that it is irrelevant structurally.
return _characters.scalar() & ~follows_potential_scalar();
}
/**
* Whether the given character is immediately after a non-operator like 123, true.
* The characters following a quote are not included.
*/
simdjson_really_inline uint64_t follows_potential_scalar() {
// _follows_potential_nonquote_scalar: is defined as marking any character that follows a character
// that is not a structural element ({,},[,],:, comma) nor a quote (") and that is not a
// white space.
// It is understood that within quoted region, anything at all could be marked (irrelevant).
return _follows_potential_nonquote_scalar;
}
};
/**
* Scans JSON for important bits: structural characters or 'operators', strings, and scalars.
*
* The scanner starts by calculating two distinct things:
* - string characters (taking \" into account)
* - structural characters or 'operators' ([]{},:, comma)
* and scalars (runs of non-operators like 123, true and "abc")
*
* To minimize data dependency (a key component of the scanner's speed), it finds these in parallel:
* in particular, the operator/scalar bit will find plenty of things that are actually part of
* strings. When we're done, json_block will fuse the two together by masking out tokens that are
* part of a string.
*/
class json_scanner {
public:
json_scanner() {}
simdjson_really_inline json_block next(const simd::simd8x64<uint8_t>& in);
// Returns either UNCLOSED_STRING or SUCCESS
simdjson_really_inline error_code finish();
private:
// Whether the last character of the previous iteration is part of a scalar token
// (anything except whitespace or a structural character/'operator').
uint64_t prev_scalar = 0ULL;
json_string_scanner string_scanner{};
};
//
// Check if the current character immediately follows a matching character.
//
// For example, this checks for quotes with backslashes in front of them:
//
// const uint64_t backslashed_quote = in.eq('"') & immediately_follows(in.eq('\'), prev_backslash);
//
simdjson_really_inline uint64_t follows(const uint64_t match, uint64_t &overflow) {
const uint64_t result = match << 1 | overflow;
overflow = match >> 63;
return result;
}
simdjson_really_inline json_block json_scanner::next(const simd::simd8x64<uint8_t>& in) {
json_string_block strings = string_scanner.next(in);
// identifies the white-space and the structurat characters
json_character_block characters = json_character_block::classify(in);
// The term "scalar" refers to anything except structural characters and white space
// (so letters, numbers, quotes).
// We want follows_scalar to mark anything that follows a non-quote scalar (so letters and numbers).
//
// A terminal quote should either be followed by a structural character (comma, brace, bracket, colon)
// or nothing. However, we still want ' "a string"true ' to mark the 't' of 'true' as a potential
// pseudo-structural character just like we would if we had ' "a string" true '; otherwise we
// may need to add an extra check when parsing strings.
//
// Performance: there are many ways to skin this cat.
const uint64_t nonquote_scalar = characters.scalar() & ~strings.quote();
uint64_t follows_nonquote_scalar = follows(nonquote_scalar, prev_scalar);
return {
strings,
characters,
follows_nonquote_scalar
};
}
simdjson_really_inline error_code json_scanner::finish() {
return string_scanner.finish();
}
} // namespace stage1
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* end file src/generic/stage1/json_scanner.h */
/* begin file src/generic/stage1/json_minifier.h */
// This file contains the common code every implementation uses in stage1
// It is intended to be included multiple times and compiled multiple times
// We assume the file in which it is included already includes
// "simdjson/stage1.h" (this simplifies amalgation)
namespace simdjson {
namespace haswell {
namespace {
namespace stage1 {
class json_minifier {
public:
template<size_t STEP_SIZE>
static error_code minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) noexcept;
private:
simdjson_really_inline json_minifier(uint8_t *_dst)
: dst{_dst}
{}
template<size_t STEP_SIZE>
simdjson_really_inline void step(const uint8_t *block_buf, buf_block_reader<STEP_SIZE> &reader) noexcept;
simdjson_really_inline void next(const simd::simd8x64<uint8_t>& in, json_block block);
simdjson_really_inline error_code finish(uint8_t *dst_start, size_t &dst_len);
json_scanner scanner{};
uint8_t *dst;
};
simdjson_really_inline void json_minifier::next(const simd::simd8x64<uint8_t>& in, json_block block) {
uint64_t mask = block.whitespace();
in.compress(mask, dst);
dst += 64 - count_ones(mask);
}
simdjson_really_inline error_code json_minifier::finish(uint8_t *dst_start, size_t &dst_len) {
error_code error = scanner.finish();
if (error) { dst_len = 0; return error; }
dst_len = dst - dst_start;
return SUCCESS;
}
template<>
simdjson_really_inline void json_minifier::step<128>(const uint8_t *block_buf, buf_block_reader<128> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block_buf);
simd::simd8x64<uint8_t> in_2(block_buf+64);
json_block block_1 = scanner.next(in_1);
json_block block_2 = scanner.next(in_2);
this->next(in_1, block_1);
this->next(in_2, block_2);
reader.advance();
}
template<>
simdjson_really_inline void json_minifier::step<64>(const uint8_t *block_buf, buf_block_reader<64> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block_buf);
json_block block_1 = scanner.next(in_1);
this->next(block_buf, block_1);
reader.advance();
}
template<size_t STEP_SIZE>
error_code json_minifier::minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) noexcept {
buf_block_reader<STEP_SIZE> reader(buf, len);
json_minifier minifier(dst);
// Index the first n-1 blocks
while (reader.has_full_block()) {
minifier.step<STEP_SIZE>(reader.full_block(), reader);
}
// Index the last (remainder) block, padded with spaces
uint8_t block[STEP_SIZE];
size_t remaining_bytes = reader.get_remainder(block);
if (remaining_bytes > 0) {
// We do not want to write directly to the output stream. Rather, we write
// to a local buffer (for safety).
uint8_t out_block[STEP_SIZE];
uint8_t * const guarded_dst{minifier.dst};
minifier.dst = out_block;
minifier.step<STEP_SIZE>(block, reader);
size_t to_write = minifier.dst - out_block;
// In some cases, we could be enticed to consider the padded spaces
// as part of the string. This is fine as long as we do not write more
// than we consumed.
if(to_write > remaining_bytes) { to_write = remaining_bytes; }
memcpy(guarded_dst, out_block, to_write);
minifier.dst = guarded_dst + to_write;
}
return minifier.finish(dst, dst_len);
}
} // namespace stage1
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* end file src/generic/stage1/json_minifier.h */
/* begin file src/generic/stage1/find_next_document_index.h */
namespace simdjson {
namespace haswell {
namespace {
/**
* This algorithm is used to quickly identify the last structural position that
* makes up a complete document.
*
* It does this by going backwards and finding the last *document boundary* (a
* place where one value follows another without a comma between them). If the
* last document (the characters after the boundary) has an equal number of
* start and end brackets, it is considered complete.
*
* Simply put, we iterate over the structural characters, starting from
* the end. We consider that we found the end of a JSON document when the
* first element of the pair is NOT one of these characters: '{' '[' ';' ','
* and when the second element is NOT one of these characters: '}' '}' ';' ','.
*
* This simple comparison works most of the time, but it does not cover cases
* where the batch's structural indexes contain a perfect amount of documents.
* In such a case, we do not have access to the structural index which follows
* the last document, therefore, we do not have access to the second element in
* the pair, and that means we cannot identify the last document. To fix this
* issue, we keep a count of the open and closed curly/square braces we found
* while searching for the pair. When we find a pair AND the count of open and
* closed curly/square braces is the same, we know that we just passed a
* complete document, therefore the last json buffer location is the end of the
* batch.
*/
simdjson_really_inline uint32_t find_next_document_index(dom_parser_implementation &parser) {
// TODO don't count separately, just figure out depth
auto arr_cnt = 0;
auto obj_cnt = 0;
for (auto i = parser.n_structural_indexes - 1; i > 0; i--) {
auto idxb = parser.structural_indexes[i];
switch (parser.buf[idxb]) {
case ':':
case ',':
continue;
case '}':
obj_cnt--;
continue;
case ']':
arr_cnt--;
continue;
case '{':
obj_cnt++;
break;
case '[':
arr_cnt++;
break;
}
auto idxa = parser.structural_indexes[i - 1];
switch (parser.buf[idxa]) {
case '{':
case '[':
case ':':
case ',':
continue;
}
// Last document is complete, so the next document will appear after!
if (!arr_cnt && !obj_cnt) {
return parser.n_structural_indexes;
}
// Last document is incomplete; mark the document at i + 1 as the next one
return i;
}
return 0;
}
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* end file src/generic/stage1/find_next_document_index.h */
namespace simdjson {
namespace haswell {
namespace {
namespace stage1 {
class bit_indexer {
public:
uint32_t *tail;
simdjson_really_inline bit_indexer(uint32_t *index_buf) : tail(index_buf) {}
// flatten out values in 'bits' assuming that they are are to have values of idx
// plus their position in the bitvector, and store these indexes at
// base_ptr[base] incrementing base as we go
// will potentially store extra values beyond end of valid bits, so base_ptr
// needs to be large enough to handle this
simdjson_really_inline void write(uint32_t idx, uint64_t bits) {
// In some instances, the next branch is expensive because it is mispredicted.
// Unfortunately, in other cases,
// it helps tremendously.
if (bits == 0)
return;
int cnt = static_cast<int>(count_ones(bits));
// Do the first 8 all together
for (int i=0; i<8; i++) {
this->tail[i] = idx + trailing_zeroes(bits);
bits = clear_lowest_bit(bits);
}
// Do the next 8 all together (we hope in most cases it won't happen at all
// and the branch is easily predicted).
if (simdjson_unlikely(cnt > 8)) {
for (int i=8; i<16; i++) {
this->tail[i] = idx + trailing_zeroes(bits);
bits = clear_lowest_bit(bits);
}
// Most files don't have 16+ structurals per block, so we take several basically guaranteed
// branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :)
// or the start of a value ("abc" true 123) every four characters.
if (simdjson_unlikely(cnt > 16)) {
int i = 16;
do {
this->tail[i] = idx + trailing_zeroes(bits);
bits = clear_lowest_bit(bits);
i++;
} while (i < cnt);
}
}
this->tail += cnt;
}
};
class json_structural_indexer {
public:
/**
* Find the important bits of JSON in a 128-byte chunk, and add them to structural_indexes.
*
* @param partial Setting the partial parameter to true allows the find_structural_bits to
* tolerate unclosed strings. The caller should still ensure that the input is valid UTF-8. If
* you are processing substrings, you may want to call on a function like trimmed_length_safe_utf8.
*/
template<size_t STEP_SIZE>
static error_code index(const uint8_t *buf, size_t len, dom_parser_implementation &parser, bool partial) noexcept;
private:
simdjson_really_inline json_structural_indexer(uint32_t *structural_indexes);
template<size_t STEP_SIZE>
simdjson_really_inline void step(const uint8_t *block, buf_block_reader<STEP_SIZE> &reader) noexcept;
simdjson_really_inline void next(const simd::simd8x64<uint8_t>& in, json_block block, size_t idx);
simdjson_really_inline error_code finish(dom_parser_implementation &parser, size_t idx, size_t len, bool partial);
json_scanner scanner{};
utf8_checker checker{};
bit_indexer indexer;
uint64_t prev_structurals = 0;
uint64_t unescaped_chars_error = 0;
};
simdjson_really_inline json_structural_indexer::json_structural_indexer(uint32_t *structural_indexes) : indexer{structural_indexes} {}
// Skip the last character if it is partial
simdjson_really_inline size_t trim_partial_utf8(const uint8_t *buf, size_t len) {
if (simdjson_unlikely(len < 3)) {
switch (len) {
case 2:
if (buf[len-1] >= 0b11000000) { return len-1; } // 2-, 3- and 4-byte characters with only 1 byte left
if (buf[len-2] >= 0b11100000) { return len-2; } // 3- and 4-byte characters with only 2 bytes left
return len;
case 1:
if (buf[len-1] >= 0b11000000) { return len-1; } // 2-, 3- and 4-byte characters with only 1 byte left
return len;
case 0:
return len;
}
}
if (buf[len-1] >= 0b11000000) { return len-1; } // 2-, 3- and 4-byte characters with only 1 byte left
if (buf[len-2] >= 0b11100000) { return len-2; } // 3- and 4-byte characters with only 1 byte left
if (buf[len-3] >= 0b11110000) { return len-3; } // 4-byte characters with only 3 bytes left
return len;
}
//
// PERF NOTES:
// We pipe 2 inputs through these stages:
// 1. Load JSON into registers. This takes a long time and is highly parallelizable, so we load
// 2 inputs' worth at once so that by the time step 2 is looking for them input, it's available.
// 2. Scan the JSON for critical data: strings, scalars and operators. This is the critical path.
// The output of step 1 depends entirely on this information. These functions don't quite use
// up enough CPU: the second half of the functions is highly serial, only using 1 execution core
// at a time. The second input's scans has some dependency on the first ones finishing it, but
// they can make a lot of progress before they need that information.
// 3. Step 1 doesn't use enough capacity, so we run some extra stuff while we're waiting for that
// to finish: utf-8 checks and generating the output from the last iteration.
//
// The reason we run 2 inputs at a time, is steps 2 and 3 are *still* not enough to soak up all
// available capacity with just one input. Running 2 at a time seems to give the CPU a good enough
// workout.
//
template<size_t STEP_SIZE>
error_code json_structural_indexer::index(const uint8_t *buf, size_t len, dom_parser_implementation &parser, bool partial) noexcept {
if (simdjson_unlikely(len > parser.capacity())) { return CAPACITY; }
if (partial) { len = trim_partial_utf8(buf, len); }
buf_block_reader<STEP_SIZE> reader(buf, len);
json_structural_indexer indexer(parser.structural_indexes.get());
// Read all but the last block
while (reader.has_full_block()) {
indexer.step<STEP_SIZE>(reader.full_block(), reader);
}
// Take care of the last block (will always be there unless file is empty)
uint8_t block[STEP_SIZE];
if (simdjson_unlikely(reader.get_remainder(block) == 0)) { return EMPTY; }
indexer.step<STEP_SIZE>(block, reader);
return indexer.finish(parser, reader.block_index(), len, partial);
}
template<>
simdjson_really_inline void json_structural_indexer::step<128>(const uint8_t *block, buf_block_reader<128> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block);
simd::simd8x64<uint8_t> in_2(block+64);
json_block block_1 = scanner.next(in_1);
json_block block_2 = scanner.next(in_2);
this->next(in_1, block_1, reader.block_index());
this->next(in_2, block_2, reader.block_index()+64);
reader.advance();
}
template<>
simdjson_really_inline void json_structural_indexer::step<64>(const uint8_t *block, buf_block_reader<64> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block);
json_block block_1 = scanner.next(in_1);
this->next(in_1, block_1, reader.block_index());
reader.advance();
}
simdjson_really_inline void json_structural_indexer::next(const simd::simd8x64<uint8_t>& in, json_block block, size_t idx) {
uint64_t unescaped = in.lteq(0x1F);
checker.check_next_input(in);
indexer.write(uint32_t(idx-64), prev_structurals); // Output *last* iteration's structurals to the parser
prev_structurals = block.structural_start();
unescaped_chars_error |= block.non_quote_inside_string(unescaped);
}
simdjson_really_inline error_code json_structural_indexer::finish(dom_parser_implementation &parser, size_t idx, size_t len, bool partial) {
// Write out the final iteration's structurals
indexer.write(uint32_t(idx-64), prev_structurals);
error_code error = scanner.finish();
// We deliberately break down the next expression so that it is
// human readable.
const bool should_we_exit = partial ?
((error != SUCCESS) && (error != UNCLOSED_STRING)) // when partial we tolerate UNCLOSED_STRING
: (error != SUCCESS); // if partial is false, we must have SUCCESS
const bool have_unclosed_string = (error == UNCLOSED_STRING);
if (simdjson_unlikely(should_we_exit)) { return error; }
if (unescaped_chars_error) {
return UNESCAPED_CHARS;
}
parser.n_structural_indexes = uint32_t(indexer.tail - parser.structural_indexes.get());
/***
* This is related to https://github.com/simdjson/simdjson/issues/906
* Basically, we want to make sure that if the parsing continues beyond the last (valid)
* structural character, it quickly stops.
* Only three structural characters can be repeated without triggering an error in JSON: [,] and }.
* We repeat the padding character (at 'len'). We don't know what it is, but if the parsing
* continues, then it must be [,] or }.
* Suppose it is ] or }. We backtrack to the first character, what could it be that would
* not trigger an error? It could be ] or } but no, because you can't start a document that way.
* It can't be a comma, a colon or any simple value. So the only way we could continue is
* if the repeated character is [. But if so, the document must start with [. But if the document
* starts with [, it should end with ]. If we enforce that rule, then we would get
* ][[ which is invalid.
**/
parser.structural_indexes[parser.n_structural_indexes] = uint32_t(len);
parser.structural_indexes[parser.n_structural_indexes + 1] = uint32_t(len);
parser.structural_indexes[parser.n_structural_indexes + 2] = 0;
parser.next_structural_index = 0;
// a valid JSON file cannot have zero structural indexes - we should have found something
if (simdjson_unlikely(parser.n_structural_indexes == 0u)) {
return EMPTY;
}
if (simdjson_unlikely(parser.structural_indexes[parser.n_structural_indexes - 1] > len)) {
return UNEXPECTED_ERROR;
}
if (partial) {
// If we have an unclosed string, then the last structural
// will be the quote and we want to make sure to omit it.
if(have_unclosed_string) {
parser.n_structural_indexes--;
// a valid JSON file cannot have zero structural indexes - we should have found something
if (simdjson_unlikely(parser.n_structural_indexes == 0u)) { return CAPACITY; }
}
auto new_structural_indexes = find_next_document_index(parser);
if (new_structural_indexes == 0 && parser.n_structural_indexes > 0) {
return CAPACITY; // If the buffer is partial but the document is incomplete, it's too big to parse.
}
parser.n_structural_indexes = new_structural_indexes;
}
checker.check_eof();
return checker.errors();
}
} // namespace stage1
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* end file src/generic/stage1/json_structural_indexer.h */
/* begin file src/generic/stage1/utf8_validator.h */
namespace simdjson {
namespace haswell {
namespace {
namespace stage1 {
/**
* Validates that the string is actual UTF-8.
*/
template<class checker>
bool generic_validate_utf8(const uint8_t * input, size_t length) {
checker c{};
buf_block_reader<64> reader(input, length);
while (reader.has_full_block()) {
simd::simd8x64<uint8_t> in(reader.full_block());
c.check_next_input(in);
reader.advance();
}
uint8_t block[64]{};
reader.get_remainder(block);
simd::simd8x64<uint8_t> in(block);
c.check_next_input(in);
reader.advance();
c.check_eof();
return c.errors() == error_code::SUCCESS;
}
bool generic_validate_utf8(const char * input, size_t length) {
return generic_validate_utf8<utf8_checker>((const uint8_t *)input,length);
}
} // namespace stage1
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* end file src/generic/stage1/utf8_validator.h */
//
// Stage 2
//
/* begin file src/generic/stage2/tape_builder.h */
/* begin file src/generic/stage2/json_iterator.h */
/* begin file src/generic/stage2/logger.h */
// This is for an internal-only stage 2 specific logger.
// Set LOG_ENABLED = true to log what stage 2 is doing!
namespace simdjson {
namespace haswell {
namespace {
namespace logger {
static constexpr const char * DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------";
#if SIMDJSON_VERBOSE_LOGGING
static constexpr const bool LOG_ENABLED = true;
#else
static constexpr const bool LOG_ENABLED = false;
#endif
static constexpr const int LOG_EVENT_LEN = 20;
static constexpr const int LOG_BUFFER_LEN = 30;
static constexpr const int LOG_SMALL_BUFFER_LEN = 10;
static constexpr const int LOG_INDEX_LEN = 5;
static int log_depth; // Not threadsafe. Log only.
// Helper to turn unprintable or newline characters into spaces
static simdjson_really_inline char printable_char(char c) {
if (c >= 0x20) {
return c;
} else {
return ' ';
}
}
// Print the header and set up log_start
static simdjson_really_inline void log_start() {
if (LOG_ENABLED) {
log_depth = 0;
printf("\n");
printf("| %-*s | %-*s | %-*s | %-*s | Detail |\n", LOG_EVENT_LEN, "Event", LOG_BUFFER_LEN, "Buffer", LOG_SMALL_BUFFER_LEN, "Next", 5, "Next#");
printf("|%.*s|%.*s|%.*s|%.*s|--------|\n", LOG_EVENT_LEN+2, DASHES, LOG_BUFFER_LEN+2, DASHES, LOG_SMALL_BUFFER_LEN+2, DASHES, 5+2, DASHES);
}
}
simdjson_unused static simdjson_really_inline void log_string(const char *message) {
if (LOG_ENABLED) {
printf("%s\n", message);
}
}
// Logs a single line from the stage 2 DOM parser
template<typename S>
static simdjson_really_inline void log_line(S &structurals, const char *title_prefix, const char *title, const char *detail) {
if (LOG_ENABLED) {
printf("| %*s%s%-*s ", log_depth*2, "", title_prefix, LOG_EVENT_LEN - log_depth*2 - int(strlen(title_prefix)), title);
auto current_index = structurals.at_beginning() ? nullptr : structurals.next_structural-1;
auto next_index = structurals.next_structural;
auto current = current_index ? &structurals.buf[*current_index] : (const uint8_t*)" ";
auto next = &structurals.buf[*next_index];
{
// Print the next N characters in the buffer.
printf("| ");
// Otherwise, print the characters starting from the buffer position.
// Print spaces for unprintable or newline characters.
for (int i=0;i<LOG_BUFFER_LEN;i++) {
printf("%c", printable_char(current[i]));
}
printf(" ");
// Print the next N characters in the buffer.
printf("| ");
// Otherwise, print the characters starting from the buffer position.
// Print spaces for unprintable or newline characters.
for (int i=0;i<LOG_SMALL_BUFFER_LEN;i++) {
printf("%c", printable_char(next[i]));
}
printf(" ");
}
if (current_index) {
printf("| %*u ", LOG_INDEX_LEN, *current_index);
} else {
printf("| %-*s ", LOG_INDEX_LEN, "");
}
// printf("| %*u ", LOG_INDEX_LEN, structurals.next_tape_index());
printf("| %-s ", detail);
printf("|\n");
}
}
} // namespace logger
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* end file src/generic/stage2/logger.h */
namespace simdjson {
namespace haswell {
namespace {
namespace stage2 {
class json_iterator {
public:
const uint8_t* const buf;
uint32_t *next_structural;
dom_parser_implementation &dom_parser;
uint32_t depth{0};
/**
* Walk the JSON document.
*
* The visitor receives callbacks when values are encountered. All callbacks pass the iterator as
* the first parameter; some callbacks have other parameters as well:
*
* - visit_document_start() - at the beginning.
* - visit_document_end() - at the end (if things were successful).
*
* - visit_array_start() - at the start `[` of a non-empty array.
* - visit_array_end() - at the end `]` of a non-empty array.
* - visit_empty_array() - when an empty array is encountered.
*
* - visit_object_end() - at the start `]` of a non-empty object.
* - visit_object_start() - at the end `]` of a non-empty object.
* - visit_empty_object() - when an empty object is encountered.
* - visit_key(const uint8_t *key) - when a key in an object field is encountered. key is
* guaranteed to point at the first quote of the string (`"key"`).
* - visit_primitive(const uint8_t *value) - when a value is a string, number, boolean or null.
* - visit_root_primitive(iter, uint8_t *value) - when the top-level value is a string, number, boolean or null.
*
* - increment_count(iter) - each time a value is found in an array or object.
*/
template<bool STREAMING, typename V>
simdjson_warn_unused simdjson_really_inline error_code walk_document(V &visitor) noexcept;
/**
* Create an iterator capable of walking a JSON document.
*
* The document must have already passed through stage 1.
*/
simdjson_really_inline json_iterator(dom_parser_implementation &_dom_parser, size_t start_structural_index);
/**
* Look at the next token.
*
* Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)).
*
* They may include invalid JSON as well (such as `1.2.3` or `ture`).
*/
simdjson_really_inline const uint8_t *peek() const noexcept;
/**
* Advance to the next token.
*
* Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)).
*
* They may include invalid JSON as well (such as `1.2.3` or `ture`).
*/
simdjson_really_inline const uint8_t *advance() noexcept;
/**
* Get the remaining length of the document, from the start of the current token.
*/
simdjson_really_inline size_t remaining_len() const noexcept;
/**
* Check if we are at the end of the document.
*
* If this is true, there are no more tokens.
*/
simdjson_really_inline bool at_eof() const noexcept;
/**
* Check if we are at the beginning of the document.
*/
simdjson_really_inline bool at_beginning() const noexcept;
simdjson_really_inline uint8_t last_structural() const noexcept;
/**
* Log that a value has been found.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_value(const char *type) const noexcept;
/**
* Log the start of a multipart value.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_start_value(const char *type) const noexcept;
/**
* Log the end of a multipart value.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_end_value(const char *type) const noexcept;
/**
* Log an error.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_error(const char *error) const noexcept;
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code visit_root_primitive(V &visitor, const uint8_t *value) noexcept;
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code visit_primitive(V &visitor, const uint8_t *value) noexcept;
};
template<bool STREAMING, typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::walk_document(V &visitor) noexcept {
logger::log_start();
//
// Start the document
//
if (at_eof()) { return EMPTY; }
log_start_value("document");
SIMDJSON_TRY( visitor.visit_document_start(*this) );
//
// Read first value
//
{
auto value = advance();
// Make sure the outer hash or array is closed before continuing; otherwise, there are ways we
// could get into memory corruption. See https://github.com/simdjson/simdjson/issues/906
if (!STREAMING) {
switch (*value) {
case '{': if (last_structural() != '}') { return TAPE_ERROR; }; break;
case '[': if (last_structural() != ']') { return TAPE_ERROR; }; break;
}
}
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_root_primitive(*this, value) ); break;
}
}
goto document_end;
//
// Object parser states
//
object_begin:
log_start_value("object");
depth++;
if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; }
dom_parser.is_array[depth] = false;
SIMDJSON_TRY( visitor.visit_object_start(*this) );
{
auto key = advance();
if (*key != '"') { log_error("Object does not start with a key"); return TAPE_ERROR; }
SIMDJSON_TRY( visitor.increment_count(*this) );
SIMDJSON_TRY( visitor.visit_key(*this, key) );
}
object_field:
if (simdjson_unlikely( *advance() != ':' )) { log_error("Missing colon after key in object"); return TAPE_ERROR; }
{
auto value = advance();
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_primitive(*this, value) ); break;
}
}
object_continue:
switch (*advance()) {
case ',':
SIMDJSON_TRY( visitor.increment_count(*this) );
{
auto key = advance();
if (simdjson_unlikely( *key != '"' )) { log_error("Key string missing at beginning of field in object"); return TAPE_ERROR; }
SIMDJSON_TRY( visitor.visit_key(*this, key) );
}
goto object_field;
case '}': log_end_value("object"); SIMDJSON_TRY( visitor.visit_object_end(*this) ); goto scope_end;
default: log_error("No comma between object fields"); return TAPE_ERROR;
}
scope_end:
depth--;
if (depth == 0) { goto document_end; }
if (dom_parser.is_array[depth]) { goto array_continue; }
goto object_continue;
//
// Array parser states
//
array_begin:
log_start_value("array");
depth++;
if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; }
dom_parser.is_array[depth] = true;
SIMDJSON_TRY( visitor.visit_array_start(*this) );
SIMDJSON_TRY( visitor.increment_count(*this) );
array_value:
{
auto value = advance();
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_primitive(*this, value) ); break;
}
}
array_continue:
switch (*advance()) {
case ',': SIMDJSON_TRY( visitor.increment_count(*this) ); goto array_value;
case ']': log_end_value("array"); SIMDJSON_TRY( visitor.visit_array_end(*this) ); goto scope_end;
default: log_error("Missing comma between array values"); return TAPE_ERROR;
}
document_end:
log_end_value("document");
SIMDJSON_TRY( visitor.visit_document_end(*this) );
dom_parser.next_structural_index = uint32_t(next_structural - &dom_parser.structural_indexes[0]);
// If we didn't make it to the end, it's an error
if ( !STREAMING && dom_parser.next_structural_index != dom_parser.n_structural_indexes ) {
log_error("More than one JSON value at the root of the document, or extra characters at the end of the JSON!");
return TAPE_ERROR;
}
return SUCCESS;
} // walk_document()
simdjson_really_inline json_iterator::json_iterator(dom_parser_implementation &_dom_parser, size_t start_structural_index)
: buf{_dom_parser.buf},
next_structural{&_dom_parser.structural_indexes[start_structural_index]},
dom_parser{_dom_parser} {
}
simdjson_really_inline const uint8_t *json_iterator::peek() const noexcept {
return &buf[*(next_structural)];
}
simdjson_really_inline const uint8_t *json_iterator::advance() noexcept {
return &buf[*(next_structural++)];
}
simdjson_really_inline size_t json_iterator::remaining_len() const noexcept {
return dom_parser.len - *(next_structural-1);
}
simdjson_really_inline bool json_iterator::at_eof() const noexcept {
return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes];
}
simdjson_really_inline bool json_iterator::at_beginning() const noexcept {
return next_structural == dom_parser.structural_indexes.get();
}
simdjson_really_inline uint8_t json_iterator::last_structural() const noexcept {
return buf[dom_parser.structural_indexes[dom_parser.n_structural_indexes - 1]];
}
simdjson_really_inline void json_iterator::log_value(const char *type) const noexcept {
logger::log_line(*this, "", type, "");
}
simdjson_really_inline void json_iterator::log_start_value(const char *type) const noexcept {
logger::log_line(*this, "+", type, "");
if (logger::LOG_ENABLED) { logger::log_depth++; }
}
simdjson_really_inline void json_iterator::log_end_value(const char *type) const noexcept {
if (logger::LOG_ENABLED) { logger::log_depth--; }
logger::log_line(*this, "-", type, "");
}
simdjson_really_inline void json_iterator::log_error(const char *error) const noexcept {
logger::log_line(*this, "", "ERROR", error);
}
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::visit_root_primitive(V &visitor, const uint8_t *value) noexcept {
switch (*value) {
case '"': return visitor.visit_root_string(*this, value);
case 't': return visitor.visit_root_true_atom(*this, value);
case 'f': return visitor.visit_root_false_atom(*this, value);
case 'n': return visitor.visit_root_null_atom(*this, value);
case '-':
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
return visitor.visit_root_number(*this, value);
default:
log_error("Document starts with a non-value character");
return TAPE_ERROR;
}
}
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::visit_primitive(V &visitor, const uint8_t *value) noexcept {
switch (*value) {
case '"': return visitor.visit_string(*this, value);
case 't': return visitor.visit_true_atom(*this, value);
case 'f': return visitor.visit_false_atom(*this, value);
case 'n': return visitor.visit_null_atom(*this, value);
case '-':
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
return visitor.visit_number(*this, value);
default:
log_error("Non-value found when value was expected!");
return TAPE_ERROR;
}
}
} // namespace stage2
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* end file src/generic/stage2/json_iterator.h */
/* begin file src/generic/stage2/tape_writer.h */
namespace simdjson {
namespace haswell {
namespace {
namespace stage2 {
struct tape_writer {
/** The next place to write to tape */
uint64_t *next_tape_loc;
/** Write a signed 64-bit value to tape. */
simdjson_really_inline void append_s64(int64_t value) noexcept;
/** Write an unsigned 64-bit value to tape. */
simdjson_really_inline void append_u64(uint64_t value) noexcept;
/** Write a double value to tape. */
simdjson_really_inline void append_double(double value) noexcept;
/**
* Append a tape entry (an 8-bit type,and 56 bits worth of value).
*/
simdjson_really_inline void append(uint64_t val, internal::tape_type t) noexcept;
/**
* Skip the current tape entry without writing.
*
* Used to skip the start of the container, since we'll come back later to fill it in when the
* container ends.
*/
simdjson_really_inline void skip() noexcept;
/**
* Skip the number of tape entries necessary to write a large u64 or i64.
*/
simdjson_really_inline void skip_large_integer() noexcept;
/**
* Skip the number of tape entries necessary to write a double.
*/
simdjson_really_inline void skip_double() noexcept;
/**
* Write a value to a known location on tape.
*
* Used to go back and write out the start of a container after the container ends.
*/
simdjson_really_inline static void write(uint64_t &tape_loc, uint64_t val, internal::tape_type t) noexcept;
private:
/**
* Append both the tape entry, and a supplementary value following it. Used for types that need
* all 64 bits, such as double and uint64_t.
*/
template<typename T>
simdjson_really_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept;
}; // struct number_writer
simdjson_really_inline void tape_writer::append_s64(int64_t value) noexcept {
append2(0, value, internal::tape_type::INT64);
}
simdjson_really_inline void tape_writer::append_u64(uint64_t value) noexcept {
append(0, internal::tape_type::UINT64);
*next_tape_loc = value;
next_tape_loc++;
}
/** Write a double value to tape. */
simdjson_really_inline void tape_writer::append_double(double value) noexcept {
append2(0, value, internal::tape_type::DOUBLE);
}
simdjson_really_inline void tape_writer::skip() noexcept {
next_tape_loc++;
}
simdjson_really_inline void tape_writer::skip_large_integer() noexcept {
next_tape_loc += 2;
}
simdjson_really_inline void tape_writer::skip_double() noexcept {
next_tape_loc += 2;
}
simdjson_really_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept {
*next_tape_loc = val | ((uint64_t(char(t))) << 56);
next_tape_loc++;
}
template<typename T>
simdjson_really_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept {
append(val, t);
static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!");
memcpy(next_tape_loc, &val2, sizeof(val2));
next_tape_loc++;
}
simdjson_really_inline void tape_writer::write(uint64_t &tape_loc, uint64_t val, internal::tape_type t) noexcept {
tape_loc = val | ((uint64_t(char(t))) << 56);
}
} // namespace stage2
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* end file src/generic/stage2/tape_writer.h */
namespace simdjson {
namespace haswell {
namespace {
namespace stage2 {
struct tape_builder {
template<bool STREAMING>
simdjson_warn_unused static simdjson_really_inline error_code parse_document(
dom_parser_implementation &dom_parser,
dom::document &doc) noexcept;
/** Called when a non-empty document starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_document_start(json_iterator &iter) noexcept;
/** Called when a non-empty document ends without error. */
simdjson_warn_unused simdjson_really_inline error_code visit_document_end(json_iterator &iter) noexcept;
/** Called when a non-empty array starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_array_start(json_iterator &iter) noexcept;
/** Called when a non-empty array ends. */
simdjson_warn_unused simdjson_really_inline error_code visit_array_end(json_iterator &iter) noexcept;
/** Called when an empty array is found. */
simdjson_warn_unused simdjson_really_inline error_code visit_empty_array(json_iterator &iter) noexcept;
/** Called when a non-empty object starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_object_start(json_iterator &iter) noexcept;
/**
* Called when a key in a field is encountered.
*
* primitive, visit_object_start, visit_empty_object, visit_array_start, or visit_empty_array
* will be called after this with the field value.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_key(json_iterator &iter, const uint8_t *key) noexcept;
/** Called when a non-empty object ends. */
simdjson_warn_unused simdjson_really_inline error_code visit_object_end(json_iterator &iter) noexcept;
/** Called when an empty object is found. */
simdjson_warn_unused simdjson_really_inline error_code visit_empty_object(json_iterator &iter) noexcept;
/**
* Called when a string, number, boolean or null is found.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_primitive(json_iterator &iter, const uint8_t *value) noexcept;
/**
* Called when a string, number, boolean or null is found at the top level of a document (i.e.
* when there is no array or object and the entire document is a single string, number, boolean or
* null.
*
* This is separate from primitive() because simdjson's normal primitive parsing routines assume
* there is at least one more token after the value, which is only true in an array or object.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_root_primitive(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_string(json_iterator &iter, const uint8_t *value, bool key = false) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_number(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_true_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_false_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_null_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_string(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_number(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_true_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_false_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_null_atom(json_iterator &iter, const uint8_t *value) noexcept;
/** Called each time a new field or element in an array or object is found. */
simdjson_warn_unused simdjson_really_inline error_code increment_count(json_iterator &iter) noexcept;
/** Next location to write to tape */
tape_writer tape;
private:
/** Next write location in the string buf for stage 2 parsing */
uint8_t *current_string_buf_loc;
simdjson_really_inline tape_builder(dom::document &doc) noexcept;
simdjson_really_inline uint32_t next_tape_index(json_iterator &iter) const noexcept;
simdjson_really_inline void start_container(json_iterator &iter) noexcept;
simdjson_warn_unused simdjson_really_inline error_code end_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept;
simdjson_warn_unused simdjson_really_inline error_code empty_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept;
simdjson_really_inline uint8_t *on_start_string(json_iterator &iter) noexcept;
simdjson_really_inline void on_end_string(uint8_t *dst) noexcept;
}; // class tape_builder
template<bool STREAMING>
simdjson_warn_unused simdjson_really_inline error_code tape_builder::parse_document(
dom_parser_implementation &dom_parser,
dom::document &doc) noexcept {
dom_parser.doc = &doc;
json_iterator iter(dom_parser, STREAMING ? dom_parser.next_structural_index : 0);
tape_builder builder(doc);
return iter.walk_document<STREAMING>(builder);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_primitive(json_iterator &iter, const uint8_t *value) noexcept {
return iter.visit_root_primitive(*this, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_primitive(json_iterator &iter, const uint8_t *value) noexcept {
return iter.visit_primitive(*this, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_empty_object(json_iterator &iter) noexcept {
return empty_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_empty_array(json_iterator &iter) noexcept {
return empty_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_document_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_object_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_array_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_object_end(json_iterator &iter) noexcept {
return end_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_array_end(json_iterator &iter) noexcept {
return end_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_document_end(json_iterator &iter) noexcept {
constexpr uint32_t start_tape_index = 0;
tape.append(start_tape_index, internal::tape_type::ROOT);
tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter), internal::tape_type::ROOT);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_key(json_iterator &iter, const uint8_t *key) noexcept {
return visit_string(iter, key, true);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::increment_count(json_iterator &iter) noexcept {
iter.dom_parser.open_containers[iter.depth].count++; // we have a key value pair in the object at parser.dom_parser.depth - 1
return SUCCESS;
}
simdjson_really_inline tape_builder::tape_builder(dom::document &doc) noexcept : tape{doc.tape.get()}, current_string_buf_loc{doc.string_buf.get()} {}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_string(json_iterator &iter, const uint8_t *value, bool key) noexcept {
iter.log_value(key ? "key" : "string");
uint8_t *dst = on_start_string(iter);
dst = stringparsing::parse_string(value+1, dst);
if (dst == nullptr) {
iter.log_error("Invalid escape in string");
return STRING_ERROR;
}
on_end_string(dst);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_string(json_iterator &iter, const uint8_t *value) noexcept {
return visit_string(iter, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_number(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("number");
return numberparsing::parse_number(value, tape);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_number(json_iterator &iter, const uint8_t *value) noexcept {
//
// We need to make a copy to make sure that the string is space terminated.
// This is not about padding the input, which should already padded up
// to len + SIMDJSON_PADDING. However, we have no control at this stage
// on how the padding was done. What if the input string was padded with nulls?
// It is quite common for an input string to have an extra null character (C string).
// We do not want to allow 9\0 (where \0 is the null character) inside a JSON
// document, but the string "9\0" by itself is fine. So we make a copy and
// pad the input with spaces when we know that there is just one input element.
// This copy is relatively expensive, but it will almost never be called in
// practice unless you are in the strange scenario where you have many JSON
// documents made of single atoms.
//
uint8_t *copy = static_cast<uint8_t *>(malloc(iter.remaining_len() + SIMDJSON_PADDING));
if (copy == nullptr) { return MEMALLOC; }
std::memcpy(copy, value, iter.remaining_len());
std::memset(copy + iter.remaining_len(), ' ', SIMDJSON_PADDING);
error_code error = visit_number(iter, copy);
free(copy);
return error;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_true_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("true");
if (!atomparsing::is_valid_true_atom(value)) { return T_ATOM_ERROR; }
tape.append(0, internal::tape_type::TRUE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_true_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("true");
if (!atomparsing::is_valid_true_atom(value, iter.remaining_len())) { return T_ATOM_ERROR; }
tape.append(0, internal::tape_type::TRUE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_false_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("false");
if (!atomparsing::is_valid_false_atom(value)) { return F_ATOM_ERROR; }
tape.append(0, internal::tape_type::FALSE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_false_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("false");
if (!atomparsing::is_valid_false_atom(value, iter.remaining_len())) { return F_ATOM_ERROR; }
tape.append(0, internal::tape_type::FALSE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_null_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("null");
if (!atomparsing::is_valid_null_atom(value)) { return N_ATOM_ERROR; }
tape.append(0, internal::tape_type::NULL_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_null_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("null");
if (!atomparsing::is_valid_null_atom(value, iter.remaining_len())) { return N_ATOM_ERROR; }
tape.append(0, internal::tape_type::NULL_VALUE);
return SUCCESS;
}
// private:
simdjson_really_inline uint32_t tape_builder::next_tape_index(json_iterator &iter) const noexcept {
return uint32_t(tape.next_tape_loc - iter.dom_parser.doc->tape.get());
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::empty_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept {
auto start_index = next_tape_index(iter);
tape.append(start_index+2, start);
tape.append(start_index, end);
return SUCCESS;
}
simdjson_really_inline void tape_builder::start_container(json_iterator &iter) noexcept {
iter.dom_parser.open_containers[iter.depth].tape_index = next_tape_index(iter);
iter.dom_parser.open_containers[iter.depth].count = 0;
tape.skip(); // We don't actually *write* the start element until the end.
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::end_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept {
// Write the ending tape element, pointing at the start location
const uint32_t start_tape_index = iter.dom_parser.open_containers[iter.depth].tape_index;
tape.append(start_tape_index, end);
// Write the start tape element, pointing at the end location (and including count)
// count can overflow if it exceeds 24 bits... so we saturate
// the convention being that a cnt of 0xffffff or more is undetermined in value (>= 0xffffff).
const uint32_t count = iter.dom_parser.open_containers[iter.depth].count;
const uint32_t cntsat = count > 0xFFFFFF ? 0xFFFFFF : count;
tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter) | (uint64_t(cntsat) << 32), start);
return SUCCESS;
}
simdjson_really_inline uint8_t *tape_builder::on_start_string(json_iterator &iter) noexcept {
// we advance the point, accounting for the fact that we have a NULL termination
tape.append(current_string_buf_loc - iter.dom_parser.doc->string_buf.get(), internal::tape_type::STRING);
return current_string_buf_loc + sizeof(uint32_t);
}
simdjson_really_inline void tape_builder::on_end_string(uint8_t *dst) noexcept {
uint32_t str_length = uint32_t(dst - (current_string_buf_loc + sizeof(uint32_t)));
// TODO check for overflow in case someone has a crazy string (>=4GB?)
// But only add the overflow check when the document itself exceeds 4GB
// Currently unneeded because we refuse to parse docs larger or equal to 4GB.
memcpy(current_string_buf_loc, &str_length, sizeof(uint32_t));
// NULL termination is still handy if you expect all your strings to
// be NULL terminated? It comes at a small cost
*dst = 0;
current_string_buf_loc = dst + 1;
}
} // namespace stage2
} // unnamed namespace
} // namespace haswell
} // namespace simdjson
/* end file src/generic/stage2/tape_builder.h */
//
// Implementation-specific overrides
//
namespace simdjson {
namespace haswell {
namespace {
namespace stage1 {
simdjson_really_inline uint64_t json_string_scanner::find_escaped(uint64_t backslash) {
if (!backslash) { uint64_t escaped = prev_escaped; prev_escaped = 0; return escaped; }
return find_escaped_branchless(backslash);
}
} // namespace stage1
} // unnamed namespace
simdjson_warn_unused error_code implementation::minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) const noexcept {
return haswell::stage1::json_minifier::minify<128>(buf, len, dst, dst_len);
}
simdjson_warn_unused error_code dom_parser_implementation::stage1(const uint8_t *_buf, size_t _len, bool streaming) noexcept {
this->buf = _buf;
this->len = _len;
return haswell::stage1::json_structural_indexer::index<128>(_buf, _len, *this, streaming);
}
simdjson_warn_unused bool implementation::validate_utf8(const char *buf, size_t len) const noexcept {
return haswell::stage1::generic_validate_utf8(buf,len);
}
simdjson_warn_unused error_code dom_parser_implementation::stage2(dom::document &_doc) noexcept {
return stage2::tape_builder::parse_document<false>(*this, _doc);
}
simdjson_warn_unused error_code dom_parser_implementation::stage2_next(dom::document &_doc) noexcept {
return stage2::tape_builder::parse_document<true>(*this, _doc);
}
simdjson_warn_unused error_code dom_parser_implementation::parse(const uint8_t *_buf, size_t _len, dom::document &_doc) noexcept {
auto error = stage1(_buf, _len, false);
if (error) { return error; }
return stage2(_doc);
}
} // namespace haswell
} // namespace simdjson
/* begin file include/simdjson/haswell/end.h */
SIMDJSON_UNTARGET_REGION
#undef haswell
/* end file include/simdjson/haswell/end.h */
/* end file src/haswell/dom_parser_implementation.cpp */
#endif
#if SIMDJSON_IMPLEMENTATION_PPC64
/* begin file src/ppc64/implementation.cpp */
/* begin file include/simdjson/ppc64/begin.h */
// redefining SIMDJSON_IMPLEMENTATION to "ppc64"
// #define SIMDJSON_IMPLEMENTATION ppc64
/* end file include/simdjson/ppc64/begin.h */
namespace simdjson {
namespace ppc64 {
simdjson_warn_unused error_code implementation::create_dom_parser_implementation(
size_t capacity,
size_t max_depth,
std::unique_ptr<internal::dom_parser_implementation>& dst
) const noexcept {
dst.reset( new (std::nothrow) dom_parser_implementation() );
if (!dst) { return MEMALLOC; }
dst->set_capacity(capacity);
dst->set_max_depth(max_depth);
return SUCCESS;
}
} // namespace ppc64
} // namespace simdjson
/* begin file include/simdjson/ppc64/end.h */
#undef ppc64
/* end file include/simdjson/ppc64/end.h */
/* end file src/ppc64/implementation.cpp */
/* begin file src/ppc64/dom_parser_implementation.cpp */
/* begin file include/simdjson/ppc64/begin.h */
// redefining SIMDJSON_IMPLEMENTATION to "ppc64"
// #define SIMDJSON_IMPLEMENTATION ppc64
/* end file include/simdjson/ppc64/begin.h */
//
// Stage 1
//
namespace simdjson {
namespace ppc64 {
namespace {
using namespace simd;
struct json_character_block {
static simdjson_really_inline json_character_block classify(const simd::simd8x64<uint8_t>& in);
simdjson_really_inline uint64_t whitespace() const { return _whitespace; }
simdjson_really_inline uint64_t op() const { return _op; }
simdjson_really_inline uint64_t scalar() { return ~(op() | whitespace()); }
uint64_t _whitespace;
uint64_t _op;
};
simdjson_really_inline json_character_block json_character_block::classify(const simd::simd8x64<uint8_t>& in) {
const simd8<uint8_t> table1(16, 0, 0, 0, 0, 0, 0, 0, 0, 8, 12, 1, 2, 9, 0, 0);
const simd8<uint8_t> table2(8, 0, 18, 4, 0, 1, 0, 1, 0, 0, 0, 3, 2, 1, 0, 0);
simd8x64<uint8_t> v(
(in.chunks[0] & 0xf).lookup_16(table1) & (in.chunks[0].shr<4>()).lookup_16(table2),
(in.chunks[1] & 0xf).lookup_16(table1) & (in.chunks[1].shr<4>()).lookup_16(table2),
(in.chunks[2] & 0xf).lookup_16(table1) & (in.chunks[2].shr<4>()).lookup_16(table2),
(in.chunks[3] & 0xf).lookup_16(table1) & (in.chunks[3].shr<4>()).lookup_16(table2)
);
uint64_t op = simd8x64<bool>(
v.chunks[0].any_bits_set(0x7),
v.chunks[1].any_bits_set(0x7),
v.chunks[2].any_bits_set(0x7),
v.chunks[3].any_bits_set(0x7)
).to_bitmask();
uint64_t whitespace = simd8x64<bool>(
v.chunks[0].any_bits_set(0x18),
v.chunks[1].any_bits_set(0x18),
v.chunks[2].any_bits_set(0x18),
v.chunks[3].any_bits_set(0x18)
).to_bitmask();
return { whitespace, op };
}
simdjson_really_inline bool is_ascii(const simd8x64<uint8_t>& input) {
// careful: 0x80 is not ascii.
return input.reduce_or().saturating_sub(0b01111111u).bits_not_set_anywhere();
}
simdjson_unused simdjson_really_inline simd8<bool> must_be_continuation(const simd8<uint8_t> prev1, const simd8<uint8_t> prev2, const simd8<uint8_t> prev3) {
simd8<uint8_t> is_second_byte = prev1.saturating_sub(0b11000000u-1); // Only 11______ will be > 0
simd8<uint8_t> is_third_byte = prev2.saturating_sub(0b11100000u-1); // Only 111_____ will be > 0
simd8<uint8_t> is_fourth_byte = prev3.saturating_sub(0b11110000u-1); // Only 1111____ will be > 0
// Caller requires a bool (all 1's). All values resulting from the subtraction will be <= 64, so signed comparison is fine.
return simd8<int8_t>(is_second_byte | is_third_byte | is_fourth_byte) > int8_t(0);
}
simdjson_really_inline simd8<bool> must_be_2_3_continuation(const simd8<uint8_t> prev2, const simd8<uint8_t> prev3) {
simd8<uint8_t> is_third_byte = prev2.saturating_sub(0b11100000u-1); // Only 111_____ will be > 0
simd8<uint8_t> is_fourth_byte = prev3.saturating_sub(0b11110000u-1); // Only 1111____ will be > 0
// Caller requires a bool (all 1's). All values resulting from the subtraction will be <= 64, so signed comparison is fine.
return simd8<int8_t>(is_third_byte | is_fourth_byte) > int8_t(0);
}
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* begin file src/generic/stage1/utf8_lookup4_algorithm.h */
namespace simdjson {
namespace ppc64 {
namespace {
namespace utf8_validation {
using namespace simd;
simdjson_really_inline simd8<uint8_t> check_special_cases(const simd8<uint8_t> input, const simd8<uint8_t> prev1) {
// Bit 0 = Too Short (lead byte/ASCII followed by lead byte/ASCII)
// Bit 1 = Too Long (ASCII followed by continuation)
// Bit 2 = Overlong 3-byte
// Bit 4 = Surrogate
// Bit 5 = Overlong 2-byte
// Bit 7 = Two Continuations
constexpr const uint8_t TOO_SHORT = 1<<0; // 11______ 0_______
// 11______ 11______
constexpr const uint8_t TOO_LONG = 1<<1; // 0_______ 10______
constexpr const uint8_t OVERLONG_3 = 1<<2; // 11100000 100_____
constexpr const uint8_t SURROGATE = 1<<4; // 11101101 101_____
constexpr const uint8_t OVERLONG_2 = 1<<5; // 1100000_ 10______
constexpr const uint8_t TWO_CONTS = 1<<7; // 10______ 10______
constexpr const uint8_t TOO_LARGE = 1<<3; // 11110100 1001____
// 11110100 101_____
// 11110101 1001____
// 11110101 101_____
// 1111011_ 1001____
// 1111011_ 101_____
// 11111___ 1001____
// 11111___ 101_____
constexpr const uint8_t TOO_LARGE_1000 = 1<<6;
// 11110101 1000____
// 1111011_ 1000____
// 11111___ 1000____
constexpr const uint8_t OVERLONG_4 = 1<<6; // 11110000 1000____
const simd8<uint8_t> byte_1_high = prev1.shr<4>().lookup_16<uint8_t>(
// 0_______ ________ <ASCII in byte 1>
TOO_LONG, TOO_LONG, TOO_LONG, TOO_LONG,
TOO_LONG, TOO_LONG, TOO_LONG, TOO_LONG,
// 10______ ________ <continuation in byte 1>
TWO_CONTS, TWO_CONTS, TWO_CONTS, TWO_CONTS,
// 1100____ ________ <two byte lead in byte 1>
TOO_SHORT | OVERLONG_2,
// 1101____ ________ <two byte lead in byte 1>
TOO_SHORT,
// 1110____ ________ <three byte lead in byte 1>
TOO_SHORT | OVERLONG_3 | SURROGATE,
// 1111____ ________ <four+ byte lead in byte 1>
TOO_SHORT | TOO_LARGE | TOO_LARGE_1000 | OVERLONG_4
);
constexpr const uint8_t CARRY = TOO_SHORT | TOO_LONG | TWO_CONTS; // These all have ____ in byte 1 .
const simd8<uint8_t> byte_1_low = (prev1 & 0x0F).lookup_16<uint8_t>(
// ____0000 ________
CARRY | OVERLONG_3 | OVERLONG_2 | OVERLONG_4,
// ____0001 ________
CARRY | OVERLONG_2,
// ____001_ ________
CARRY,
CARRY,
// ____0100 ________
CARRY | TOO_LARGE,
// ____0101 ________
CARRY | TOO_LARGE | TOO_LARGE_1000,
// ____011_ ________
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
// ____1___ ________
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
// ____1101 ________
CARRY | TOO_LARGE | TOO_LARGE_1000 | SURROGATE,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000
);
const simd8<uint8_t> byte_2_high = input.shr<4>().lookup_16<uint8_t>(
// ________ 0_______ <ASCII in byte 2>
TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT,
TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT,
// ________ 1000____
TOO_LONG | OVERLONG_2 | TWO_CONTS | OVERLONG_3 | TOO_LARGE_1000 | OVERLONG_4,
// ________ 1001____
TOO_LONG | OVERLONG_2 | TWO_CONTS | OVERLONG_3 | TOO_LARGE,
// ________ 101_____
TOO_LONG | OVERLONG_2 | TWO_CONTS | SURROGATE | TOO_LARGE,
TOO_LONG | OVERLONG_2 | TWO_CONTS | SURROGATE | TOO_LARGE,
// ________ 11______
TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT
);
return (byte_1_high & byte_1_low & byte_2_high);
}
simdjson_really_inline simd8<uint8_t> check_multibyte_lengths(const simd8<uint8_t> input,
const simd8<uint8_t> prev_input, const simd8<uint8_t> sc) {
simd8<uint8_t> prev2 = input.prev<2>(prev_input);
simd8<uint8_t> prev3 = input.prev<3>(prev_input);
simd8<uint8_t> must23 = simd8<uint8_t>(must_be_2_3_continuation(prev2, prev3));
simd8<uint8_t> must23_80 = must23 & uint8_t(0x80);
return must23_80 ^ sc;
}
//
// Return nonzero if there are incomplete multibyte characters at the end of the block:
// e.g. if there is a 4-byte character, but it's 3 bytes from the end.
//
simdjson_really_inline simd8<uint8_t> is_incomplete(const simd8<uint8_t> input) {
// If the previous input's last 3 bytes match this, they're too short (they ended at EOF):
// ... 1111____ 111_____ 11______
static const uint8_t max_array[32] = {
255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 0b11110000u-1, 0b11100000u-1, 0b11000000u-1
};
const simd8<uint8_t> max_value(&max_array[sizeof(max_array)-sizeof(simd8<uint8_t>)]);
return input.gt_bits(max_value);
}
struct utf8_checker {
// If this is nonzero, there has been a UTF-8 error.
simd8<uint8_t> error;
// The last input we received
simd8<uint8_t> prev_input_block;
// Whether the last input we received was incomplete (used for ASCII fast path)
simd8<uint8_t> prev_incomplete;
//
// Check whether the current bytes are valid UTF-8.
//
simdjson_really_inline void check_utf8_bytes(const simd8<uint8_t> input, const simd8<uint8_t> prev_input) {
// Flip prev1...prev3 so we can easily determine if they are 2+, 3+ or 4+ lead bytes
// (2, 3, 4-byte leads become large positive numbers instead of small negative numbers)
simd8<uint8_t> prev1 = input.prev<1>(prev_input);
simd8<uint8_t> sc = check_special_cases(input, prev1);
this->error |= check_multibyte_lengths(input, prev_input, sc);
}
// The only problem that can happen at EOF is that a multibyte character is too short
// or a byte value too large in the last bytes: check_special_cases only checks for bytes
// too large in the first of two bytes.
simdjson_really_inline void check_eof() {
// If the previous block had incomplete UTF-8 characters at the end, an ASCII block can't
// possibly finish them.
this->error |= this->prev_incomplete;
}
simdjson_really_inline void check_next_input(const simd8x64<uint8_t>& input) {
if(simdjson_likely(is_ascii(input))) {
this->error |= this->prev_incomplete;
} else {
// you might think that a for-loop would work, but under Visual Studio, it is not good enough.
static_assert((simd8x64<uint8_t>::NUM_CHUNKS == 2) || (simd8x64<uint8_t>::NUM_CHUNKS == 4),
"We support either two or four chunks per 64-byte block.");
if(simd8x64<uint8_t>::NUM_CHUNKS == 2) {
this->check_utf8_bytes(input.chunks[0], this->prev_input_block);
this->check_utf8_bytes(input.chunks[1], input.chunks[0]);
} else if(simd8x64<uint8_t>::NUM_CHUNKS == 4) {
this->check_utf8_bytes(input.chunks[0], this->prev_input_block);
this->check_utf8_bytes(input.chunks[1], input.chunks[0]);
this->check_utf8_bytes(input.chunks[2], input.chunks[1]);
this->check_utf8_bytes(input.chunks[3], input.chunks[2]);
}
this->prev_incomplete = is_incomplete(input.chunks[simd8x64<uint8_t>::NUM_CHUNKS-1]);
this->prev_input_block = input.chunks[simd8x64<uint8_t>::NUM_CHUNKS-1];
}
}
// do not forget to call check_eof!
simdjson_really_inline error_code errors() {
return this->error.any_bits_set_anywhere() ? error_code::UTF8_ERROR : error_code::SUCCESS;
}
}; // struct utf8_checker
} // namespace utf8_validation
using utf8_validation::utf8_checker;
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* end file src/generic/stage1/utf8_lookup4_algorithm.h */
/* begin file src/generic/stage1/json_structural_indexer.h */
// This file contains the common code every implementation uses in stage1
// It is intended to be included multiple times and compiled multiple times
// We assume the file in which it is included already includes
// "simdjson/stage1.h" (this simplifies amalgation)
/* begin file src/generic/stage1/buf_block_reader.h */
namespace simdjson {
namespace ppc64 {
namespace {
// Walks through a buffer in block-sized increments, loading the last part with spaces
template<size_t STEP_SIZE>
struct buf_block_reader {
public:
simdjson_really_inline buf_block_reader(const uint8_t *_buf, size_t _len);
simdjson_really_inline size_t block_index();
simdjson_really_inline bool has_full_block() const;
simdjson_really_inline const uint8_t *full_block() const;
/**
* Get the last block, padded with spaces.
*
* There will always be a last block, with at least 1 byte, unless len == 0 (in which case this
* function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there
* will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding.
*
* @return the number of effective characters in the last block.
*/
simdjson_really_inline size_t get_remainder(uint8_t *dst) const;
simdjson_really_inline void advance();
private:
const uint8_t *buf;
const size_t len;
const size_t lenminusstep;
size_t idx;
};
// Routines to print masks and text for debugging bitmask operations
simdjson_unused static char * format_input_text_64(const uint8_t *text) {
static char *buf = (char*)malloc(sizeof(simd8x64<uint8_t>) + 1);
for (size_t i=0; i<sizeof(simd8x64<uint8_t>); i++) {
buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]);
}
buf[sizeof(simd8x64<uint8_t>)] = '\0';
return buf;
}
// Routines to print masks and text for debugging bitmask operations
simdjson_unused static char * format_input_text(const simd8x64<uint8_t>& in) {
static char *buf = (char*)malloc(sizeof(simd8x64<uint8_t>) + 1);
in.store((uint8_t*)buf);
for (size_t i=0; i<sizeof(simd8x64<uint8_t>); i++) {
if (buf[i] < ' ') { buf[i] = '_'; }
}
buf[sizeof(simd8x64<uint8_t>)] = '\0';
return buf;
}
simdjson_unused static char * format_mask(uint64_t mask) {
static char *buf = (char*)malloc(64 + 1);
for (size_t i=0; i<64; i++) {
buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' ';
}
buf[64] = '\0';
return buf;
}
template<size_t STEP_SIZE>
simdjson_really_inline buf_block_reader<STEP_SIZE>::buf_block_reader(const uint8_t *_buf, size_t _len) : buf{_buf}, len{_len}, lenminusstep{len < STEP_SIZE ? 0 : len - STEP_SIZE}, idx{0} {}
template<size_t STEP_SIZE>
simdjson_really_inline size_t buf_block_reader<STEP_SIZE>::block_index() { return idx; }
template<size_t STEP_SIZE>
simdjson_really_inline bool buf_block_reader<STEP_SIZE>::has_full_block() const {
return idx < lenminusstep;
}
template<size_t STEP_SIZE>
simdjson_really_inline const uint8_t *buf_block_reader<STEP_SIZE>::full_block() const {
return &buf[idx];
}
template<size_t STEP_SIZE>
simdjson_really_inline size_t buf_block_reader<STEP_SIZE>::get_remainder(uint8_t *dst) const {
if(len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers
std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once.
std::memcpy(dst, buf + idx, len - idx);
return len - idx;
}
template<size_t STEP_SIZE>
simdjson_really_inline void buf_block_reader<STEP_SIZE>::advance() {
idx += STEP_SIZE;
}
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* end file src/generic/stage1/buf_block_reader.h */
/* begin file src/generic/stage1/json_string_scanner.h */
namespace simdjson {
namespace ppc64 {
namespace {
namespace stage1 {
struct json_string_block {
// Escaped characters (characters following an escape() character)
simdjson_really_inline uint64_t escaped() const { return _escaped; }
// Escape characters (backslashes that are not escaped--i.e. in \\, includes only the first \)
simdjson_really_inline uint64_t escape() const { return _backslash & ~_escaped; }
// Real (non-backslashed) quotes
simdjson_really_inline uint64_t quote() const { return _quote; }
// Start quotes of strings
simdjson_really_inline uint64_t string_start() const { return _quote & _in_string; }
// End quotes of strings
simdjson_really_inline uint64_t string_end() const { return _quote & ~_in_string; }
// Only characters inside the string (not including the quotes)
simdjson_really_inline uint64_t string_content() const { return _in_string & ~_quote; }
// Return a mask of whether the given characters are inside a string (only works on non-quotes)
simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; }
// Return a mask of whether the given characters are inside a string (only works on non-quotes)
simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; }
// Tail of string (everything except the start quote)
simdjson_really_inline uint64_t string_tail() const { return _in_string ^ _quote; }
// backslash characters
uint64_t _backslash;
// escaped characters (backslashed--does not include the hex characters after \u)
uint64_t _escaped;
// real quotes (non-backslashed ones)
uint64_t _quote;
// string characters (includes start quote but not end quote)
uint64_t _in_string;
};
// Scans blocks for string characters, storing the state necessary to do so
class json_string_scanner {
public:
simdjson_really_inline json_string_block next(const simd::simd8x64<uint8_t>& in);
// Returns either UNCLOSED_STRING or SUCCESS
simdjson_really_inline error_code finish();
private:
// Intended to be defined by the implementation
simdjson_really_inline uint64_t find_escaped(uint64_t escape);
simdjson_really_inline uint64_t find_escaped_branchless(uint64_t escape);
// Whether the last iteration was still inside a string (all 1's = true, all 0's = false).
uint64_t prev_in_string = 0ULL;
// Whether the first character of the next iteration is escaped.
uint64_t prev_escaped = 0ULL;
};
//
// Finds escaped characters (characters following \).
//
// Handles runs of backslashes like \\\" and \\\\" correctly (yielding 0101 and 01010, respectively).
//
// Does this by:
// - Shift the escape mask to get potentially escaped characters (characters after backslashes).
// - Mask escaped sequences that start on *even* bits with 1010101010 (odd bits are escaped, even bits are not)
// - Mask escaped sequences that start on *odd* bits with 0101010101 (even bits are escaped, odd bits are not)
//
// To distinguish between escaped sequences starting on even/odd bits, it finds the start of all
// escape sequences, filters out the ones that start on even bits, and adds that to the mask of
// escape sequences. This causes the addition to clear out the sequences starting on odd bits (since
// the start bit causes a carry), and leaves even-bit sequences alone.
//
// Example:
//
// text | \\\ | \\\"\\\" \\\" \\"\\" |
// escape | xxx | xx xxx xxx xx xx | Removed overflow backslash; will | it into follows_escape
// odd_starts | x | x x x | escape & ~even_bits & ~follows_escape
// even_seq | c| cxxx c xx c | c = carry bit -- will be masked out later
// invert_mask | | cxxx c xx c| even_seq << 1
// follows_escape | xx | x xx xxx xxx xx xx | Includes overflow bit
// escaped | x | x x x x x x x x |
// desired | x | x x x x x x x x |
// text | \\\ | \\\"\\\" \\\" \\"\\" |
//
simdjson_really_inline uint64_t json_string_scanner::find_escaped_branchless(uint64_t backslash) {
// If there was overflow, pretend the first character isn't a backslash
backslash &= ~prev_escaped;
uint64_t follows_escape = backslash << 1 | prev_escaped;
// Get sequences starting on even bits by clearing out the odd series using +
const uint64_t even_bits = 0x5555555555555555ULL;
uint64_t odd_sequence_starts = backslash & ~even_bits & ~follows_escape;
uint64_t sequences_starting_on_even_bits;
prev_escaped = add_overflow(odd_sequence_starts, backslash, &sequences_starting_on_even_bits);
uint64_t invert_mask = sequences_starting_on_even_bits << 1; // The mask we want to return is the *escaped* bits, not escapes.
// Mask every other backslashed character as an escaped character
// Flip the mask for sequences that start on even bits, to correct them
return (even_bits ^ invert_mask) & follows_escape;
}
//
// Return a mask of all string characters plus end quotes.
//
// prev_escaped is overflow saying whether the next character is escaped.
// prev_in_string is overflow saying whether we're still in a string.
//
// Backslash sequences outside of quotes will be detected in stage 2.
//
simdjson_really_inline json_string_block json_string_scanner::next(const simd::simd8x64<uint8_t>& in) {
const uint64_t backslash = in.eq('\\');
const uint64_t escaped = find_escaped(backslash);
const uint64_t quote = in.eq('"') & ~escaped;
//
// prefix_xor flips on bits inside the string (and flips off the end quote).
//
// Then we xor with prev_in_string: if we were in a string already, its effect is flipped
// (characters inside strings are outside, and characters outside strings are inside).
//
const uint64_t in_string = prefix_xor(quote) ^ prev_in_string;
//
// Check if we're still in a string at the end of the box so the next block will know
//
// right shift of a signed value expected to be well-defined and standard
// compliant as of C++20, John Regher from Utah U. says this is fine code
//
prev_in_string = uint64_t(static_cast<int64_t>(in_string) >> 63);
// Use ^ to turn the beginning quote off, and the end quote on.
return {
backslash,
escaped,
quote,
in_string
};
}
simdjson_really_inline error_code json_string_scanner::finish() {
if (prev_in_string) {
return UNCLOSED_STRING;
}
return SUCCESS;
}
} // namespace stage1
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* end file src/generic/stage1/json_string_scanner.h */
/* begin file src/generic/stage1/json_scanner.h */
namespace simdjson {
namespace ppc64 {
namespace {
namespace stage1 {
/**
* A block of scanned json, with information on operators and scalars.
*
* We seek to identify pseudo-structural characters. Anything that is inside
* a string must be omitted (hence & ~_string.string_tail()).
* Otherwise, pseudo-structural characters come in two forms.
* 1. We have the structural characters ([,],{,},:, comma). The
* term 'structural character' is from the JSON RFC.
* 2. We have the 'scalar pseudo-structural characters'.
* Scalars are quotes, and any character except structural characters and white space.
*
* To identify the scalar pseudo-structural characters, we must look at what comes
* before them: it must be a space, a quote or a structural characters.
* Starting with simdjson v0.3, we identify them by
* negation: we identify everything that is followed by a non-quote scalar,
* and we negate that. Whatever remains must be a 'scalar pseudo-structural character'.
*/
struct json_block {
public:
/**
* The start of structurals.
* In simdjson prior to v0.3, these were called the pseudo-structural characters.
**/
simdjson_really_inline uint64_t structural_start() { return potential_structural_start() & ~_string.string_tail(); }
/** All JSON whitespace (i.e. not in a string) */
simdjson_really_inline uint64_t whitespace() { return non_quote_outside_string(_characters.whitespace()); }
// Helpers
/** Whether the given characters are inside a string (only works on non-quotes) */
simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) { return _string.non_quote_inside_string(mask); }
/** Whether the given characters are outside a string (only works on non-quotes) */
simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) { return _string.non_quote_outside_string(mask); }
// string and escape characters
json_string_block _string;
// whitespace, structural characters ('operators'), scalars
json_character_block _characters;
// whether the previous character was a scalar
uint64_t _follows_potential_nonquote_scalar;
private:
// Potential structurals (i.e. disregarding strings)
/**
* structural elements ([,],{,},:, comma) plus scalar starts like 123, true and "abc".
* They may reside inside a string.
**/
simdjson_really_inline uint64_t potential_structural_start() { return _characters.op() | potential_scalar_start(); }
/**
* The start of non-operator runs, like 123, true and "abc".
* It main reside inside a string.
**/
simdjson_really_inline uint64_t potential_scalar_start() {
// The term "scalar" refers to anything except structural characters and white space
// (so letters, numbers, quotes).
// Whenever it is preceded by something that is not a structural element ({,},[,],:, ") nor a white-space
// then we know that it is irrelevant structurally.
return _characters.scalar() & ~follows_potential_scalar();
}
/**
* Whether the given character is immediately after a non-operator like 123, true.
* The characters following a quote are not included.
*/
simdjson_really_inline uint64_t follows_potential_scalar() {
// _follows_potential_nonquote_scalar: is defined as marking any character that follows a character
// that is not a structural element ({,},[,],:, comma) nor a quote (") and that is not a
// white space.
// It is understood that within quoted region, anything at all could be marked (irrelevant).
return _follows_potential_nonquote_scalar;
}
};
/**
* Scans JSON for important bits: structural characters or 'operators', strings, and scalars.
*
* The scanner starts by calculating two distinct things:
* - string characters (taking \" into account)
* - structural characters or 'operators' ([]{},:, comma)
* and scalars (runs of non-operators like 123, true and "abc")
*
* To minimize data dependency (a key component of the scanner's speed), it finds these in parallel:
* in particular, the operator/scalar bit will find plenty of things that are actually part of
* strings. When we're done, json_block will fuse the two together by masking out tokens that are
* part of a string.
*/
class json_scanner {
public:
json_scanner() {}
simdjson_really_inline json_block next(const simd::simd8x64<uint8_t>& in);
// Returns either UNCLOSED_STRING or SUCCESS
simdjson_really_inline error_code finish();
private:
// Whether the last character of the previous iteration is part of a scalar token
// (anything except whitespace or a structural character/'operator').
uint64_t prev_scalar = 0ULL;
json_string_scanner string_scanner{};
};
//
// Check if the current character immediately follows a matching character.
//
// For example, this checks for quotes with backslashes in front of them:
//
// const uint64_t backslashed_quote = in.eq('"') & immediately_follows(in.eq('\'), prev_backslash);
//
simdjson_really_inline uint64_t follows(const uint64_t match, uint64_t &overflow) {
const uint64_t result = match << 1 | overflow;
overflow = match >> 63;
return result;
}
simdjson_really_inline json_block json_scanner::next(const simd::simd8x64<uint8_t>& in) {
json_string_block strings = string_scanner.next(in);
// identifies the white-space and the structurat characters
json_character_block characters = json_character_block::classify(in);
// The term "scalar" refers to anything except structural characters and white space
// (so letters, numbers, quotes).
// We want follows_scalar to mark anything that follows a non-quote scalar (so letters and numbers).
//
// A terminal quote should either be followed by a structural character (comma, brace, bracket, colon)
// or nothing. However, we still want ' "a string"true ' to mark the 't' of 'true' as a potential
// pseudo-structural character just like we would if we had ' "a string" true '; otherwise we
// may need to add an extra check when parsing strings.
//
// Performance: there are many ways to skin this cat.
const uint64_t nonquote_scalar = characters.scalar() & ~strings.quote();
uint64_t follows_nonquote_scalar = follows(nonquote_scalar, prev_scalar);
return {
strings,
characters,
follows_nonquote_scalar
};
}
simdjson_really_inline error_code json_scanner::finish() {
return string_scanner.finish();
}
} // namespace stage1
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* end file src/generic/stage1/json_scanner.h */
/* begin file src/generic/stage1/json_minifier.h */
// This file contains the common code every implementation uses in stage1
// It is intended to be included multiple times and compiled multiple times
// We assume the file in which it is included already includes
// "simdjson/stage1.h" (this simplifies amalgation)
namespace simdjson {
namespace ppc64 {
namespace {
namespace stage1 {
class json_minifier {
public:
template<size_t STEP_SIZE>
static error_code minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) noexcept;
private:
simdjson_really_inline json_minifier(uint8_t *_dst)
: dst{_dst}
{}
template<size_t STEP_SIZE>
simdjson_really_inline void step(const uint8_t *block_buf, buf_block_reader<STEP_SIZE> &reader) noexcept;
simdjson_really_inline void next(const simd::simd8x64<uint8_t>& in, json_block block);
simdjson_really_inline error_code finish(uint8_t *dst_start, size_t &dst_len);
json_scanner scanner{};
uint8_t *dst;
};
simdjson_really_inline void json_minifier::next(const simd::simd8x64<uint8_t>& in, json_block block) {
uint64_t mask = block.whitespace();
in.compress(mask, dst);
dst += 64 - count_ones(mask);
}
simdjson_really_inline error_code json_minifier::finish(uint8_t *dst_start, size_t &dst_len) {
error_code error = scanner.finish();
if (error) { dst_len = 0; return error; }
dst_len = dst - dst_start;
return SUCCESS;
}
template<>
simdjson_really_inline void json_minifier::step<128>(const uint8_t *block_buf, buf_block_reader<128> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block_buf);
simd::simd8x64<uint8_t> in_2(block_buf+64);
json_block block_1 = scanner.next(in_1);
json_block block_2 = scanner.next(in_2);
this->next(in_1, block_1);
this->next(in_2, block_2);
reader.advance();
}
template<>
simdjson_really_inline void json_minifier::step<64>(const uint8_t *block_buf, buf_block_reader<64> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block_buf);
json_block block_1 = scanner.next(in_1);
this->next(block_buf, block_1);
reader.advance();
}
template<size_t STEP_SIZE>
error_code json_minifier::minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) noexcept {
buf_block_reader<STEP_SIZE> reader(buf, len);
json_minifier minifier(dst);
// Index the first n-1 blocks
while (reader.has_full_block()) {
minifier.step<STEP_SIZE>(reader.full_block(), reader);
}
// Index the last (remainder) block, padded with spaces
uint8_t block[STEP_SIZE];
size_t remaining_bytes = reader.get_remainder(block);
if (remaining_bytes > 0) {
// We do not want to write directly to the output stream. Rather, we write
// to a local buffer (for safety).
uint8_t out_block[STEP_SIZE];
uint8_t * const guarded_dst{minifier.dst};
minifier.dst = out_block;
minifier.step<STEP_SIZE>(block, reader);
size_t to_write = minifier.dst - out_block;
// In some cases, we could be enticed to consider the padded spaces
// as part of the string. This is fine as long as we do not write more
// than we consumed.
if(to_write > remaining_bytes) { to_write = remaining_bytes; }
memcpy(guarded_dst, out_block, to_write);
minifier.dst = guarded_dst + to_write;
}
return minifier.finish(dst, dst_len);
}
} // namespace stage1
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* end file src/generic/stage1/json_minifier.h */
/* begin file src/generic/stage1/find_next_document_index.h */
namespace simdjson {
namespace ppc64 {
namespace {
/**
* This algorithm is used to quickly identify the last structural position that
* makes up a complete document.
*
* It does this by going backwards and finding the last *document boundary* (a
* place where one value follows another without a comma between them). If the
* last document (the characters after the boundary) has an equal number of
* start and end brackets, it is considered complete.
*
* Simply put, we iterate over the structural characters, starting from
* the end. We consider that we found the end of a JSON document when the
* first element of the pair is NOT one of these characters: '{' '[' ';' ','
* and when the second element is NOT one of these characters: '}' '}' ';' ','.
*
* This simple comparison works most of the time, but it does not cover cases
* where the batch's structural indexes contain a perfect amount of documents.
* In such a case, we do not have access to the structural index which follows
* the last document, therefore, we do not have access to the second element in
* the pair, and that means we cannot identify the last document. To fix this
* issue, we keep a count of the open and closed curly/square braces we found
* while searching for the pair. When we find a pair AND the count of open and
* closed curly/square braces is the same, we know that we just passed a
* complete document, therefore the last json buffer location is the end of the
* batch.
*/
simdjson_really_inline uint32_t find_next_document_index(dom_parser_implementation &parser) {
// TODO don't count separately, just figure out depth
auto arr_cnt = 0;
auto obj_cnt = 0;
for (auto i = parser.n_structural_indexes - 1; i > 0; i--) {
auto idxb = parser.structural_indexes[i];
switch (parser.buf[idxb]) {
case ':':
case ',':
continue;
case '}':
obj_cnt--;
continue;
case ']':
arr_cnt--;
continue;
case '{':
obj_cnt++;
break;
case '[':
arr_cnt++;
break;
}
auto idxa = parser.structural_indexes[i - 1];
switch (parser.buf[idxa]) {
case '{':
case '[':
case ':':
case ',':
continue;
}
// Last document is complete, so the next document will appear after!
if (!arr_cnt && !obj_cnt) {
return parser.n_structural_indexes;
}
// Last document is incomplete; mark the document at i + 1 as the next one
return i;
}
return 0;
}
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* end file src/generic/stage1/find_next_document_index.h */
namespace simdjson {
namespace ppc64 {
namespace {
namespace stage1 {
class bit_indexer {
public:
uint32_t *tail;
simdjson_really_inline bit_indexer(uint32_t *index_buf) : tail(index_buf) {}
// flatten out values in 'bits' assuming that they are are to have values of idx
// plus their position in the bitvector, and store these indexes at
// base_ptr[base] incrementing base as we go
// will potentially store extra values beyond end of valid bits, so base_ptr
// needs to be large enough to handle this
simdjson_really_inline void write(uint32_t idx, uint64_t bits) {
// In some instances, the next branch is expensive because it is mispredicted.
// Unfortunately, in other cases,
// it helps tremendously.
if (bits == 0)
return;
int cnt = static_cast<int>(count_ones(bits));
// Do the first 8 all together
for (int i=0; i<8; i++) {
this->tail[i] = idx + trailing_zeroes(bits);
bits = clear_lowest_bit(bits);
}
// Do the next 8 all together (we hope in most cases it won't happen at all
// and the branch is easily predicted).
if (simdjson_unlikely(cnt > 8)) {
for (int i=8; i<16; i++) {
this->tail[i] = idx + trailing_zeroes(bits);
bits = clear_lowest_bit(bits);
}
// Most files don't have 16+ structurals per block, so we take several basically guaranteed
// branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :)
// or the start of a value ("abc" true 123) every four characters.
if (simdjson_unlikely(cnt > 16)) {
int i = 16;
do {
this->tail[i] = idx + trailing_zeroes(bits);
bits = clear_lowest_bit(bits);
i++;
} while (i < cnt);
}
}
this->tail += cnt;
}
};
class json_structural_indexer {
public:
/**
* Find the important bits of JSON in a 128-byte chunk, and add them to structural_indexes.
*
* @param partial Setting the partial parameter to true allows the find_structural_bits to
* tolerate unclosed strings. The caller should still ensure that the input is valid UTF-8. If
* you are processing substrings, you may want to call on a function like trimmed_length_safe_utf8.
*/
template<size_t STEP_SIZE>
static error_code index(const uint8_t *buf, size_t len, dom_parser_implementation &parser, bool partial) noexcept;
private:
simdjson_really_inline json_structural_indexer(uint32_t *structural_indexes);
template<size_t STEP_SIZE>
simdjson_really_inline void step(const uint8_t *block, buf_block_reader<STEP_SIZE> &reader) noexcept;
simdjson_really_inline void next(const simd::simd8x64<uint8_t>& in, json_block block, size_t idx);
simdjson_really_inline error_code finish(dom_parser_implementation &parser, size_t idx, size_t len, bool partial);
json_scanner scanner{};
utf8_checker checker{};
bit_indexer indexer;
uint64_t prev_structurals = 0;
uint64_t unescaped_chars_error = 0;
};
simdjson_really_inline json_structural_indexer::json_structural_indexer(uint32_t *structural_indexes) : indexer{structural_indexes} {}
// Skip the last character if it is partial
simdjson_really_inline size_t trim_partial_utf8(const uint8_t *buf, size_t len) {
if (simdjson_unlikely(len < 3)) {
switch (len) {
case 2:
if (buf[len-1] >= 0b11000000) { return len-1; } // 2-, 3- and 4-byte characters with only 1 byte left
if (buf[len-2] >= 0b11100000) { return len-2; } // 3- and 4-byte characters with only 2 bytes left
return len;
case 1:
if (buf[len-1] >= 0b11000000) { return len-1; } // 2-, 3- and 4-byte characters with only 1 byte left
return len;
case 0:
return len;
}
}
if (buf[len-1] >= 0b11000000) { return len-1; } // 2-, 3- and 4-byte characters with only 1 byte left
if (buf[len-2] >= 0b11100000) { return len-2; } // 3- and 4-byte characters with only 1 byte left
if (buf[len-3] >= 0b11110000) { return len-3; } // 4-byte characters with only 3 bytes left
return len;
}
//
// PERF NOTES:
// We pipe 2 inputs through these stages:
// 1. Load JSON into registers. This takes a long time and is highly parallelizable, so we load
// 2 inputs' worth at once so that by the time step 2 is looking for them input, it's available.
// 2. Scan the JSON for critical data: strings, scalars and operators. This is the critical path.
// The output of step 1 depends entirely on this information. These functions don't quite use
// up enough CPU: the second half of the functions is highly serial, only using 1 execution core
// at a time. The second input's scans has some dependency on the first ones finishing it, but
// they can make a lot of progress before they need that information.
// 3. Step 1 doesn't use enough capacity, so we run some extra stuff while we're waiting for that
// to finish: utf-8 checks and generating the output from the last iteration.
//
// The reason we run 2 inputs at a time, is steps 2 and 3 are *still* not enough to soak up all
// available capacity with just one input. Running 2 at a time seems to give the CPU a good enough
// workout.
//
template<size_t STEP_SIZE>
error_code json_structural_indexer::index(const uint8_t *buf, size_t len, dom_parser_implementation &parser, bool partial) noexcept {
if (simdjson_unlikely(len > parser.capacity())) { return CAPACITY; }
if (partial) { len = trim_partial_utf8(buf, len); }
buf_block_reader<STEP_SIZE> reader(buf, len);
json_structural_indexer indexer(parser.structural_indexes.get());
// Read all but the last block
while (reader.has_full_block()) {
indexer.step<STEP_SIZE>(reader.full_block(), reader);
}
// Take care of the last block (will always be there unless file is empty)
uint8_t block[STEP_SIZE];
if (simdjson_unlikely(reader.get_remainder(block) == 0)) { return EMPTY; }
indexer.step<STEP_SIZE>(block, reader);
return indexer.finish(parser, reader.block_index(), len, partial);
}
template<>
simdjson_really_inline void json_structural_indexer::step<128>(const uint8_t *block, buf_block_reader<128> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block);
simd::simd8x64<uint8_t> in_2(block+64);
json_block block_1 = scanner.next(in_1);
json_block block_2 = scanner.next(in_2);
this->next(in_1, block_1, reader.block_index());
this->next(in_2, block_2, reader.block_index()+64);
reader.advance();
}
template<>
simdjson_really_inline void json_structural_indexer::step<64>(const uint8_t *block, buf_block_reader<64> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block);
json_block block_1 = scanner.next(in_1);
this->next(in_1, block_1, reader.block_index());
reader.advance();
}
simdjson_really_inline void json_structural_indexer::next(const simd::simd8x64<uint8_t>& in, json_block block, size_t idx) {
uint64_t unescaped = in.lteq(0x1F);
checker.check_next_input(in);
indexer.write(uint32_t(idx-64), prev_structurals); // Output *last* iteration's structurals to the parser
prev_structurals = block.structural_start();
unescaped_chars_error |= block.non_quote_inside_string(unescaped);
}
simdjson_really_inline error_code json_structural_indexer::finish(dom_parser_implementation &parser, size_t idx, size_t len, bool partial) {
// Write out the final iteration's structurals
indexer.write(uint32_t(idx-64), prev_structurals);
error_code error = scanner.finish();
// We deliberately break down the next expression so that it is
// human readable.
const bool should_we_exit = partial ?
((error != SUCCESS) && (error != UNCLOSED_STRING)) // when partial we tolerate UNCLOSED_STRING
: (error != SUCCESS); // if partial is false, we must have SUCCESS
const bool have_unclosed_string = (error == UNCLOSED_STRING);
if (simdjson_unlikely(should_we_exit)) { return error; }
if (unescaped_chars_error) {
return UNESCAPED_CHARS;
}
parser.n_structural_indexes = uint32_t(indexer.tail - parser.structural_indexes.get());
/***
* This is related to https://github.com/simdjson/simdjson/issues/906
* Basically, we want to make sure that if the parsing continues beyond the last (valid)
* structural character, it quickly stops.
* Only three structural characters can be repeated without triggering an error in JSON: [,] and }.
* We repeat the padding character (at 'len'). We don't know what it is, but if the parsing
* continues, then it must be [,] or }.
* Suppose it is ] or }. We backtrack to the first character, what could it be that would
* not trigger an error? It could be ] or } but no, because you can't start a document that way.
* It can't be a comma, a colon or any simple value. So the only way we could continue is
* if the repeated character is [. But if so, the document must start with [. But if the document
* starts with [, it should end with ]. If we enforce that rule, then we would get
* ][[ which is invalid.
**/
parser.structural_indexes[parser.n_structural_indexes] = uint32_t(len);
parser.structural_indexes[parser.n_structural_indexes + 1] = uint32_t(len);
parser.structural_indexes[parser.n_structural_indexes + 2] = 0;
parser.next_structural_index = 0;
// a valid JSON file cannot have zero structural indexes - we should have found something
if (simdjson_unlikely(parser.n_structural_indexes == 0u)) {
return EMPTY;
}
if (simdjson_unlikely(parser.structural_indexes[parser.n_structural_indexes - 1] > len)) {
return UNEXPECTED_ERROR;
}
if (partial) {
// If we have an unclosed string, then the last structural
// will be the quote and we want to make sure to omit it.
if(have_unclosed_string) {
parser.n_structural_indexes--;
// a valid JSON file cannot have zero structural indexes - we should have found something
if (simdjson_unlikely(parser.n_structural_indexes == 0u)) { return CAPACITY; }
}
auto new_structural_indexes = find_next_document_index(parser);
if (new_structural_indexes == 0 && parser.n_structural_indexes > 0) {
return CAPACITY; // If the buffer is partial but the document is incomplete, it's too big to parse.
}
parser.n_structural_indexes = new_structural_indexes;
}
checker.check_eof();
return checker.errors();
}
} // namespace stage1
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* end file src/generic/stage1/json_structural_indexer.h */
/* begin file src/generic/stage1/utf8_validator.h */
namespace simdjson {
namespace ppc64 {
namespace {
namespace stage1 {
/**
* Validates that the string is actual UTF-8.
*/
template<class checker>
bool generic_validate_utf8(const uint8_t * input, size_t length) {
checker c{};
buf_block_reader<64> reader(input, length);
while (reader.has_full_block()) {
simd::simd8x64<uint8_t> in(reader.full_block());
c.check_next_input(in);
reader.advance();
}
uint8_t block[64]{};
reader.get_remainder(block);
simd::simd8x64<uint8_t> in(block);
c.check_next_input(in);
reader.advance();
c.check_eof();
return c.errors() == error_code::SUCCESS;
}
bool generic_validate_utf8(const char * input, size_t length) {
return generic_validate_utf8<utf8_checker>((const uint8_t *)input,length);
}
} // namespace stage1
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* end file src/generic/stage1/utf8_validator.h */
//
// Stage 2
//
/* begin file src/generic/stage2/tape_builder.h */
/* begin file src/generic/stage2/json_iterator.h */
/* begin file src/generic/stage2/logger.h */
// This is for an internal-only stage 2 specific logger.
// Set LOG_ENABLED = true to log what stage 2 is doing!
namespace simdjson {
namespace ppc64 {
namespace {
namespace logger {
static constexpr const char * DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------";
#if SIMDJSON_VERBOSE_LOGGING
static constexpr const bool LOG_ENABLED = true;
#else
static constexpr const bool LOG_ENABLED = false;
#endif
static constexpr const int LOG_EVENT_LEN = 20;
static constexpr const int LOG_BUFFER_LEN = 30;
static constexpr const int LOG_SMALL_BUFFER_LEN = 10;
static constexpr const int LOG_INDEX_LEN = 5;
static int log_depth; // Not threadsafe. Log only.
// Helper to turn unprintable or newline characters into spaces
static simdjson_really_inline char printable_char(char c) {
if (c >= 0x20) {
return c;
} else {
return ' ';
}
}
// Print the header and set up log_start
static simdjson_really_inline void log_start() {
if (LOG_ENABLED) {
log_depth = 0;
printf("\n");
printf("| %-*s | %-*s | %-*s | %-*s | Detail |\n", LOG_EVENT_LEN, "Event", LOG_BUFFER_LEN, "Buffer", LOG_SMALL_BUFFER_LEN, "Next", 5, "Next#");
printf("|%.*s|%.*s|%.*s|%.*s|--------|\n", LOG_EVENT_LEN+2, DASHES, LOG_BUFFER_LEN+2, DASHES, LOG_SMALL_BUFFER_LEN+2, DASHES, 5+2, DASHES);
}
}
simdjson_unused static simdjson_really_inline void log_string(const char *message) {
if (LOG_ENABLED) {
printf("%s\n", message);
}
}
// Logs a single line from the stage 2 DOM parser
template<typename S>
static simdjson_really_inline void log_line(S &structurals, const char *title_prefix, const char *title, const char *detail) {
if (LOG_ENABLED) {
printf("| %*s%s%-*s ", log_depth*2, "", title_prefix, LOG_EVENT_LEN - log_depth*2 - int(strlen(title_prefix)), title);
auto current_index = structurals.at_beginning() ? nullptr : structurals.next_structural-1;
auto next_index = structurals.next_structural;
auto current = current_index ? &structurals.buf[*current_index] : (const uint8_t*)" ";
auto next = &structurals.buf[*next_index];
{
// Print the next N characters in the buffer.
printf("| ");
// Otherwise, print the characters starting from the buffer position.
// Print spaces for unprintable or newline characters.
for (int i=0;i<LOG_BUFFER_LEN;i++) {
printf("%c", printable_char(current[i]));
}
printf(" ");
// Print the next N characters in the buffer.
printf("| ");
// Otherwise, print the characters starting from the buffer position.
// Print spaces for unprintable or newline characters.
for (int i=0;i<LOG_SMALL_BUFFER_LEN;i++) {
printf("%c", printable_char(next[i]));
}
printf(" ");
}
if (current_index) {
printf("| %*u ", LOG_INDEX_LEN, *current_index);
} else {
printf("| %-*s ", LOG_INDEX_LEN, "");
}
// printf("| %*u ", LOG_INDEX_LEN, structurals.next_tape_index());
printf("| %-s ", detail);
printf("|\n");
}
}
} // namespace logger
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* end file src/generic/stage2/logger.h */
namespace simdjson {
namespace ppc64 {
namespace {
namespace stage2 {
class json_iterator {
public:
const uint8_t* const buf;
uint32_t *next_structural;
dom_parser_implementation &dom_parser;
uint32_t depth{0};
/**
* Walk the JSON document.
*
* The visitor receives callbacks when values are encountered. All callbacks pass the iterator as
* the first parameter; some callbacks have other parameters as well:
*
* - visit_document_start() - at the beginning.
* - visit_document_end() - at the end (if things were successful).
*
* - visit_array_start() - at the start `[` of a non-empty array.
* - visit_array_end() - at the end `]` of a non-empty array.
* - visit_empty_array() - when an empty array is encountered.
*
* - visit_object_end() - at the start `]` of a non-empty object.
* - visit_object_start() - at the end `]` of a non-empty object.
* - visit_empty_object() - when an empty object is encountered.
* - visit_key(const uint8_t *key) - when a key in an object field is encountered. key is
* guaranteed to point at the first quote of the string (`"key"`).
* - visit_primitive(const uint8_t *value) - when a value is a string, number, boolean or null.
* - visit_root_primitive(iter, uint8_t *value) - when the top-level value is a string, number, boolean or null.
*
* - increment_count(iter) - each time a value is found in an array or object.
*/
template<bool STREAMING, typename V>
simdjson_warn_unused simdjson_really_inline error_code walk_document(V &visitor) noexcept;
/**
* Create an iterator capable of walking a JSON document.
*
* The document must have already passed through stage 1.
*/
simdjson_really_inline json_iterator(dom_parser_implementation &_dom_parser, size_t start_structural_index);
/**
* Look at the next token.
*
* Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)).
*
* They may include invalid JSON as well (such as `1.2.3` or `ture`).
*/
simdjson_really_inline const uint8_t *peek() const noexcept;
/**
* Advance to the next token.
*
* Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)).
*
* They may include invalid JSON as well (such as `1.2.3` or `ture`).
*/
simdjson_really_inline const uint8_t *advance() noexcept;
/**
* Get the remaining length of the document, from the start of the current token.
*/
simdjson_really_inline size_t remaining_len() const noexcept;
/**
* Check if we are at the end of the document.
*
* If this is true, there are no more tokens.
*/
simdjson_really_inline bool at_eof() const noexcept;
/**
* Check if we are at the beginning of the document.
*/
simdjson_really_inline bool at_beginning() const noexcept;
simdjson_really_inline uint8_t last_structural() const noexcept;
/**
* Log that a value has been found.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_value(const char *type) const noexcept;
/**
* Log the start of a multipart value.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_start_value(const char *type) const noexcept;
/**
* Log the end of a multipart value.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_end_value(const char *type) const noexcept;
/**
* Log an error.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_error(const char *error) const noexcept;
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code visit_root_primitive(V &visitor, const uint8_t *value) noexcept;
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code visit_primitive(V &visitor, const uint8_t *value) noexcept;
};
template<bool STREAMING, typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::walk_document(V &visitor) noexcept {
logger::log_start();
//
// Start the document
//
if (at_eof()) { return EMPTY; }
log_start_value("document");
SIMDJSON_TRY( visitor.visit_document_start(*this) );
//
// Read first value
//
{
auto value = advance();
// Make sure the outer hash or array is closed before continuing; otherwise, there are ways we
// could get into memory corruption. See https://github.com/simdjson/simdjson/issues/906
if (!STREAMING) {
switch (*value) {
case '{': if (last_structural() != '}') { return TAPE_ERROR; }; break;
case '[': if (last_structural() != ']') { return TAPE_ERROR; }; break;
}
}
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_root_primitive(*this, value) ); break;
}
}
goto document_end;
//
// Object parser states
//
object_begin:
log_start_value("object");
depth++;
if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; }
dom_parser.is_array[depth] = false;
SIMDJSON_TRY( visitor.visit_object_start(*this) );
{
auto key = advance();
if (*key != '"') { log_error("Object does not start with a key"); return TAPE_ERROR; }
SIMDJSON_TRY( visitor.increment_count(*this) );
SIMDJSON_TRY( visitor.visit_key(*this, key) );
}
object_field:
if (simdjson_unlikely( *advance() != ':' )) { log_error("Missing colon after key in object"); return TAPE_ERROR; }
{
auto value = advance();
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_primitive(*this, value) ); break;
}
}
object_continue:
switch (*advance()) {
case ',':
SIMDJSON_TRY( visitor.increment_count(*this) );
{
auto key = advance();
if (simdjson_unlikely( *key != '"' )) { log_error("Key string missing at beginning of field in object"); return TAPE_ERROR; }
SIMDJSON_TRY( visitor.visit_key(*this, key) );
}
goto object_field;
case '}': log_end_value("object"); SIMDJSON_TRY( visitor.visit_object_end(*this) ); goto scope_end;
default: log_error("No comma between object fields"); return TAPE_ERROR;
}
scope_end:
depth--;
if (depth == 0) { goto document_end; }
if (dom_parser.is_array[depth]) { goto array_continue; }
goto object_continue;
//
// Array parser states
//
array_begin:
log_start_value("array");
depth++;
if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; }
dom_parser.is_array[depth] = true;
SIMDJSON_TRY( visitor.visit_array_start(*this) );
SIMDJSON_TRY( visitor.increment_count(*this) );
array_value:
{
auto value = advance();
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_primitive(*this, value) ); break;
}
}
array_continue:
switch (*advance()) {
case ',': SIMDJSON_TRY( visitor.increment_count(*this) ); goto array_value;
case ']': log_end_value("array"); SIMDJSON_TRY( visitor.visit_array_end(*this) ); goto scope_end;
default: log_error("Missing comma between array values"); return TAPE_ERROR;
}
document_end:
log_end_value("document");
SIMDJSON_TRY( visitor.visit_document_end(*this) );
dom_parser.next_structural_index = uint32_t(next_structural - &dom_parser.structural_indexes[0]);
// If we didn't make it to the end, it's an error
if ( !STREAMING && dom_parser.next_structural_index != dom_parser.n_structural_indexes ) {
log_error("More than one JSON value at the root of the document, or extra characters at the end of the JSON!");
return TAPE_ERROR;
}
return SUCCESS;
} // walk_document()
simdjson_really_inline json_iterator::json_iterator(dom_parser_implementation &_dom_parser, size_t start_structural_index)
: buf{_dom_parser.buf},
next_structural{&_dom_parser.structural_indexes[start_structural_index]},
dom_parser{_dom_parser} {
}
simdjson_really_inline const uint8_t *json_iterator::peek() const noexcept {
return &buf[*(next_structural)];
}
simdjson_really_inline const uint8_t *json_iterator::advance() noexcept {
return &buf[*(next_structural++)];
}
simdjson_really_inline size_t json_iterator::remaining_len() const noexcept {
return dom_parser.len - *(next_structural-1);
}
simdjson_really_inline bool json_iterator::at_eof() const noexcept {
return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes];
}
simdjson_really_inline bool json_iterator::at_beginning() const noexcept {
return next_structural == dom_parser.structural_indexes.get();
}
simdjson_really_inline uint8_t json_iterator::last_structural() const noexcept {
return buf[dom_parser.structural_indexes[dom_parser.n_structural_indexes - 1]];
}
simdjson_really_inline void json_iterator::log_value(const char *type) const noexcept {
logger::log_line(*this, "", type, "");
}
simdjson_really_inline void json_iterator::log_start_value(const char *type) const noexcept {
logger::log_line(*this, "+", type, "");
if (logger::LOG_ENABLED) { logger::log_depth++; }
}
simdjson_really_inline void json_iterator::log_end_value(const char *type) const noexcept {
if (logger::LOG_ENABLED) { logger::log_depth--; }
logger::log_line(*this, "-", type, "");
}
simdjson_really_inline void json_iterator::log_error(const char *error) const noexcept {
logger::log_line(*this, "", "ERROR", error);
}
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::visit_root_primitive(V &visitor, const uint8_t *value) noexcept {
switch (*value) {
case '"': return visitor.visit_root_string(*this, value);
case 't': return visitor.visit_root_true_atom(*this, value);
case 'f': return visitor.visit_root_false_atom(*this, value);
case 'n': return visitor.visit_root_null_atom(*this, value);
case '-':
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
return visitor.visit_root_number(*this, value);
default:
log_error("Document starts with a non-value character");
return TAPE_ERROR;
}
}
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::visit_primitive(V &visitor, const uint8_t *value) noexcept {
switch (*value) {
case '"': return visitor.visit_string(*this, value);
case 't': return visitor.visit_true_atom(*this, value);
case 'f': return visitor.visit_false_atom(*this, value);
case 'n': return visitor.visit_null_atom(*this, value);
case '-':
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
return visitor.visit_number(*this, value);
default:
log_error("Non-value found when value was expected!");
return TAPE_ERROR;
}
}
} // namespace stage2
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* end file src/generic/stage2/json_iterator.h */
/* begin file src/generic/stage2/tape_writer.h */
namespace simdjson {
namespace ppc64 {
namespace {
namespace stage2 {
struct tape_writer {
/** The next place to write to tape */
uint64_t *next_tape_loc;
/** Write a signed 64-bit value to tape. */
simdjson_really_inline void append_s64(int64_t value) noexcept;
/** Write an unsigned 64-bit value to tape. */
simdjson_really_inline void append_u64(uint64_t value) noexcept;
/** Write a double value to tape. */
simdjson_really_inline void append_double(double value) noexcept;
/**
* Append a tape entry (an 8-bit type,and 56 bits worth of value).
*/
simdjson_really_inline void append(uint64_t val, internal::tape_type t) noexcept;
/**
* Skip the current tape entry without writing.
*
* Used to skip the start of the container, since we'll come back later to fill it in when the
* container ends.
*/
simdjson_really_inline void skip() noexcept;
/**
* Skip the number of tape entries necessary to write a large u64 or i64.
*/
simdjson_really_inline void skip_large_integer() noexcept;
/**
* Skip the number of tape entries necessary to write a double.
*/
simdjson_really_inline void skip_double() noexcept;
/**
* Write a value to a known location on tape.
*
* Used to go back and write out the start of a container after the container ends.
*/
simdjson_really_inline static void write(uint64_t &tape_loc, uint64_t val, internal::tape_type t) noexcept;
private:
/**
* Append both the tape entry, and a supplementary value following it. Used for types that need
* all 64 bits, such as double and uint64_t.
*/
template<typename T>
simdjson_really_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept;
}; // struct number_writer
simdjson_really_inline void tape_writer::append_s64(int64_t value) noexcept {
append2(0, value, internal::tape_type::INT64);
}
simdjson_really_inline void tape_writer::append_u64(uint64_t value) noexcept {
append(0, internal::tape_type::UINT64);
*next_tape_loc = value;
next_tape_loc++;
}
/** Write a double value to tape. */
simdjson_really_inline void tape_writer::append_double(double value) noexcept {
append2(0, value, internal::tape_type::DOUBLE);
}
simdjson_really_inline void tape_writer::skip() noexcept {
next_tape_loc++;
}
simdjson_really_inline void tape_writer::skip_large_integer() noexcept {
next_tape_loc += 2;
}
simdjson_really_inline void tape_writer::skip_double() noexcept {
next_tape_loc += 2;
}
simdjson_really_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept {
*next_tape_loc = val | ((uint64_t(char(t))) << 56);
next_tape_loc++;
}
template<typename T>
simdjson_really_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept {
append(val, t);
static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!");
memcpy(next_tape_loc, &val2, sizeof(val2));
next_tape_loc++;
}
simdjson_really_inline void tape_writer::write(uint64_t &tape_loc, uint64_t val, internal::tape_type t) noexcept {
tape_loc = val | ((uint64_t(char(t))) << 56);
}
} // namespace stage2
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* end file src/generic/stage2/tape_writer.h */
namespace simdjson {
namespace ppc64 {
namespace {
namespace stage2 {
struct tape_builder {
template<bool STREAMING>
simdjson_warn_unused static simdjson_really_inline error_code parse_document(
dom_parser_implementation &dom_parser,
dom::document &doc) noexcept;
/** Called when a non-empty document starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_document_start(json_iterator &iter) noexcept;
/** Called when a non-empty document ends without error. */
simdjson_warn_unused simdjson_really_inline error_code visit_document_end(json_iterator &iter) noexcept;
/** Called when a non-empty array starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_array_start(json_iterator &iter) noexcept;
/** Called when a non-empty array ends. */
simdjson_warn_unused simdjson_really_inline error_code visit_array_end(json_iterator &iter) noexcept;
/** Called when an empty array is found. */
simdjson_warn_unused simdjson_really_inline error_code visit_empty_array(json_iterator &iter) noexcept;
/** Called when a non-empty object starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_object_start(json_iterator &iter) noexcept;
/**
* Called when a key in a field is encountered.
*
* primitive, visit_object_start, visit_empty_object, visit_array_start, or visit_empty_array
* will be called after this with the field value.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_key(json_iterator &iter, const uint8_t *key) noexcept;
/** Called when a non-empty object ends. */
simdjson_warn_unused simdjson_really_inline error_code visit_object_end(json_iterator &iter) noexcept;
/** Called when an empty object is found. */
simdjson_warn_unused simdjson_really_inline error_code visit_empty_object(json_iterator &iter) noexcept;
/**
* Called when a string, number, boolean or null is found.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_primitive(json_iterator &iter, const uint8_t *value) noexcept;
/**
* Called when a string, number, boolean or null is found at the top level of a document (i.e.
* when there is no array or object and the entire document is a single string, number, boolean or
* null.
*
* This is separate from primitive() because simdjson's normal primitive parsing routines assume
* there is at least one more token after the value, which is only true in an array or object.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_root_primitive(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_string(json_iterator &iter, const uint8_t *value, bool key = false) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_number(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_true_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_false_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_null_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_string(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_number(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_true_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_false_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_null_atom(json_iterator &iter, const uint8_t *value) noexcept;
/** Called each time a new field or element in an array or object is found. */
simdjson_warn_unused simdjson_really_inline error_code increment_count(json_iterator &iter) noexcept;
/** Next location to write to tape */
tape_writer tape;
private:
/** Next write location in the string buf for stage 2 parsing */
uint8_t *current_string_buf_loc;
simdjson_really_inline tape_builder(dom::document &doc) noexcept;
simdjson_really_inline uint32_t next_tape_index(json_iterator &iter) const noexcept;
simdjson_really_inline void start_container(json_iterator &iter) noexcept;
simdjson_warn_unused simdjson_really_inline error_code end_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept;
simdjson_warn_unused simdjson_really_inline error_code empty_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept;
simdjson_really_inline uint8_t *on_start_string(json_iterator &iter) noexcept;
simdjson_really_inline void on_end_string(uint8_t *dst) noexcept;
}; // class tape_builder
template<bool STREAMING>
simdjson_warn_unused simdjson_really_inline error_code tape_builder::parse_document(
dom_parser_implementation &dom_parser,
dom::document &doc) noexcept {
dom_parser.doc = &doc;
json_iterator iter(dom_parser, STREAMING ? dom_parser.next_structural_index : 0);
tape_builder builder(doc);
return iter.walk_document<STREAMING>(builder);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_primitive(json_iterator &iter, const uint8_t *value) noexcept {
return iter.visit_root_primitive(*this, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_primitive(json_iterator &iter, const uint8_t *value) noexcept {
return iter.visit_primitive(*this, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_empty_object(json_iterator &iter) noexcept {
return empty_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_empty_array(json_iterator &iter) noexcept {
return empty_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_document_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_object_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_array_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_object_end(json_iterator &iter) noexcept {
return end_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_array_end(json_iterator &iter) noexcept {
return end_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_document_end(json_iterator &iter) noexcept {
constexpr uint32_t start_tape_index = 0;
tape.append(start_tape_index, internal::tape_type::ROOT);
tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter), internal::tape_type::ROOT);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_key(json_iterator &iter, const uint8_t *key) noexcept {
return visit_string(iter, key, true);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::increment_count(json_iterator &iter) noexcept {
iter.dom_parser.open_containers[iter.depth].count++; // we have a key value pair in the object at parser.dom_parser.depth - 1
return SUCCESS;
}
simdjson_really_inline tape_builder::tape_builder(dom::document &doc) noexcept : tape{doc.tape.get()}, current_string_buf_loc{doc.string_buf.get()} {}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_string(json_iterator &iter, const uint8_t *value, bool key) noexcept {
iter.log_value(key ? "key" : "string");
uint8_t *dst = on_start_string(iter);
dst = stringparsing::parse_string(value+1, dst);
if (dst == nullptr) {
iter.log_error("Invalid escape in string");
return STRING_ERROR;
}
on_end_string(dst);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_string(json_iterator &iter, const uint8_t *value) noexcept {
return visit_string(iter, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_number(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("number");
return numberparsing::parse_number(value, tape);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_number(json_iterator &iter, const uint8_t *value) noexcept {
//
// We need to make a copy to make sure that the string is space terminated.
// This is not about padding the input, which should already padded up
// to len + SIMDJSON_PADDING. However, we have no control at this stage
// on how the padding was done. What if the input string was padded with nulls?
// It is quite common for an input string to have an extra null character (C string).
// We do not want to allow 9\0 (where \0 is the null character) inside a JSON
// document, but the string "9\0" by itself is fine. So we make a copy and
// pad the input with spaces when we know that there is just one input element.
// This copy is relatively expensive, but it will almost never be called in
// practice unless you are in the strange scenario where you have many JSON
// documents made of single atoms.
//
uint8_t *copy = static_cast<uint8_t *>(malloc(iter.remaining_len() + SIMDJSON_PADDING));
if (copy == nullptr) { return MEMALLOC; }
std::memcpy(copy, value, iter.remaining_len());
std::memset(copy + iter.remaining_len(), ' ', SIMDJSON_PADDING);
error_code error = visit_number(iter, copy);
free(copy);
return error;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_true_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("true");
if (!atomparsing::is_valid_true_atom(value)) { return T_ATOM_ERROR; }
tape.append(0, internal::tape_type::TRUE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_true_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("true");
if (!atomparsing::is_valid_true_atom(value, iter.remaining_len())) { return T_ATOM_ERROR; }
tape.append(0, internal::tape_type::TRUE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_false_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("false");
if (!atomparsing::is_valid_false_atom(value)) { return F_ATOM_ERROR; }
tape.append(0, internal::tape_type::FALSE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_false_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("false");
if (!atomparsing::is_valid_false_atom(value, iter.remaining_len())) { return F_ATOM_ERROR; }
tape.append(0, internal::tape_type::FALSE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_null_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("null");
if (!atomparsing::is_valid_null_atom(value)) { return N_ATOM_ERROR; }
tape.append(0, internal::tape_type::NULL_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_null_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("null");
if (!atomparsing::is_valid_null_atom(value, iter.remaining_len())) { return N_ATOM_ERROR; }
tape.append(0, internal::tape_type::NULL_VALUE);
return SUCCESS;
}
// private:
simdjson_really_inline uint32_t tape_builder::next_tape_index(json_iterator &iter) const noexcept {
return uint32_t(tape.next_tape_loc - iter.dom_parser.doc->tape.get());
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::empty_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept {
auto start_index = next_tape_index(iter);
tape.append(start_index+2, start);
tape.append(start_index, end);
return SUCCESS;
}
simdjson_really_inline void tape_builder::start_container(json_iterator &iter) noexcept {
iter.dom_parser.open_containers[iter.depth].tape_index = next_tape_index(iter);
iter.dom_parser.open_containers[iter.depth].count = 0;
tape.skip(); // We don't actually *write* the start element until the end.
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::end_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept {
// Write the ending tape element, pointing at the start location
const uint32_t start_tape_index = iter.dom_parser.open_containers[iter.depth].tape_index;
tape.append(start_tape_index, end);
// Write the start tape element, pointing at the end location (and including count)
// count can overflow if it exceeds 24 bits... so we saturate
// the convention being that a cnt of 0xffffff or more is undetermined in value (>= 0xffffff).
const uint32_t count = iter.dom_parser.open_containers[iter.depth].count;
const uint32_t cntsat = count > 0xFFFFFF ? 0xFFFFFF : count;
tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter) | (uint64_t(cntsat) << 32), start);
return SUCCESS;
}
simdjson_really_inline uint8_t *tape_builder::on_start_string(json_iterator &iter) noexcept {
// we advance the point, accounting for the fact that we have a NULL termination
tape.append(current_string_buf_loc - iter.dom_parser.doc->string_buf.get(), internal::tape_type::STRING);
return current_string_buf_loc + sizeof(uint32_t);
}
simdjson_really_inline void tape_builder::on_end_string(uint8_t *dst) noexcept {
uint32_t str_length = uint32_t(dst - (current_string_buf_loc + sizeof(uint32_t)));
// TODO check for overflow in case someone has a crazy string (>=4GB?)
// But only add the overflow check when the document itself exceeds 4GB
// Currently unneeded because we refuse to parse docs larger or equal to 4GB.
memcpy(current_string_buf_loc, &str_length, sizeof(uint32_t));
// NULL termination is still handy if you expect all your strings to
// be NULL terminated? It comes at a small cost
*dst = 0;
current_string_buf_loc = dst + 1;
}
} // namespace stage2
} // unnamed namespace
} // namespace ppc64
} // namespace simdjson
/* end file src/generic/stage2/tape_builder.h */
//
// Implementation-specific overrides
//
namespace simdjson {
namespace ppc64 {
namespace {
namespace stage1 {
simdjson_really_inline uint64_t json_string_scanner::find_escaped(uint64_t backslash) {
// On PPC, we don't short-circuit this if there are no backslashes, because the branch gives us no
// benefit and therefore makes things worse.
// if (!backslash) { uint64_t escaped = prev_escaped; prev_escaped = 0; return escaped; }
return find_escaped_branchless(backslash);
}
} // namespace stage1
} // unnamed namespace
simdjson_warn_unused error_code implementation::minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) const noexcept {
return ppc64::stage1::json_minifier::minify<64>(buf, len, dst, dst_len);
}
simdjson_warn_unused error_code dom_parser_implementation::stage1(const uint8_t *_buf, size_t _len, bool streaming) noexcept {
this->buf = _buf;
this->len = _len;
return ppc64::stage1::json_structural_indexer::index<64>(buf, len, *this, streaming);
}
simdjson_warn_unused bool implementation::validate_utf8(const char *buf, size_t len) const noexcept {
return ppc64::stage1::generic_validate_utf8(buf,len);
}
simdjson_warn_unused error_code dom_parser_implementation::stage2(dom::document &_doc) noexcept {
return stage2::tape_builder::parse_document<false>(*this, _doc);
}
simdjson_warn_unused error_code dom_parser_implementation::stage2_next(dom::document &_doc) noexcept {
return stage2::tape_builder::parse_document<true>(*this, _doc);
}
simdjson_warn_unused error_code dom_parser_implementation::parse(const uint8_t *_buf, size_t _len, dom::document &_doc) noexcept {
auto error = stage1(_buf, _len, false);
if (error) { return error; }
return stage2(_doc);
}
} // namespace ppc64
} // namespace simdjson
/* begin file include/simdjson/ppc64/end.h */
#undef ppc64
/* end file include/simdjson/ppc64/end.h */
/* end file src/ppc64/dom_parser_implementation.cpp */
#endif
#if SIMDJSON_IMPLEMENTATION_WESTMERE
/* begin file src/westmere/implementation.cpp */
/* begin file include/simdjson/westmere/begin.h */
// redefining SIMDJSON_IMPLEMENTATION to "westmere"
// #define SIMDJSON_IMPLEMENTATION westmere
SIMDJSON_TARGET_WESTMERE
/* end file include/simdjson/westmere/begin.h */
namespace simdjson {
namespace westmere {
simdjson_warn_unused error_code implementation::create_dom_parser_implementation(
size_t capacity,
size_t max_depth,
std::unique_ptr<internal::dom_parser_implementation>& dst
) const noexcept {
dst.reset( new (std::nothrow) dom_parser_implementation() );
if (!dst) { return MEMALLOC; }
dst->set_capacity(capacity);
dst->set_max_depth(max_depth);
return SUCCESS;
}
} // namespace westmere
} // namespace simdjson
/* begin file include/simdjson/westmere/end.h */
SIMDJSON_UNTARGET_REGION
#undef westmere
/* end file include/simdjson/westmere/end.h */
/* end file src/westmere/implementation.cpp */
/* begin file src/westmere/dom_parser_implementation.cpp */
/* begin file include/simdjson/westmere/begin.h */
// redefining SIMDJSON_IMPLEMENTATION to "westmere"
// #define SIMDJSON_IMPLEMENTATION westmere
SIMDJSON_TARGET_WESTMERE
/* end file include/simdjson/westmere/begin.h */
//
// Stage 1
//
namespace simdjson {
namespace westmere {
namespace {
using namespace simd;
struct json_character_block {
static simdjson_really_inline json_character_block classify(const simd::simd8x64<uint8_t>& in);
simdjson_really_inline uint64_t whitespace() const { return _whitespace; }
simdjson_really_inline uint64_t op() const { return _op; }
simdjson_really_inline uint64_t scalar() { return ~(op() | whitespace()); }
uint64_t _whitespace;
uint64_t _op;
};
simdjson_really_inline json_character_block json_character_block::classify(const simd::simd8x64<uint8_t>& in) {
// These lookups rely on the fact that anything < 127 will match the lower 4 bits, which is why
// we can't use the generic lookup_16.
auto whitespace_table = simd8<uint8_t>::repeat_16(' ', 100, 100, 100, 17, 100, 113, 2, 100, '\t', '\n', 112, 100, '\r', 100, 100);
// The 6 operators (:,[]{}) have these values:
//
// , 2C
// : 3A
// [ 5B
// { 7B
// ] 5D
// } 7D
//
// If you use | 0x20 to turn [ and ] into { and }, the lower 4 bits of each character is unique.
// We exploit this, using a simd 4-bit lookup to tell us which character match against, and then
// match it (against | 0x20).
//
// To prevent recognizing other characters, everything else gets compared with 0, which cannot
// match due to the | 0x20.
//
// NOTE: Due to the | 0x20, this ALSO treats <FF> and <SUB> (control characters 0C and 1A) like ,
// and :. This gets caught in stage 2, which checks the actual character to ensure the right
// operators are in the right places.
const auto op_table = simd8<uint8_t>::repeat_16(
0, 0, 0, 0,
0, 0, 0, 0,
0, 0, ':', '{', // : = 3A, [ = 5B, { = 7B
',', '}', 0, 0 // , = 2C, ] = 5D, } = 7D
);
// We compute whitespace and op separately. If the code later only use one or the
// other, given the fact that all functions are aggressively inlined, we can
// hope that useless computations will be omitted. This is namely case when
// minifying (we only need whitespace).
const uint64_t whitespace = in.eq({
_mm_shuffle_epi8(whitespace_table, in.chunks[0]),
_mm_shuffle_epi8(whitespace_table, in.chunks[1]),
_mm_shuffle_epi8(whitespace_table, in.chunks[2]),
_mm_shuffle_epi8(whitespace_table, in.chunks[3])
});
// Turn [ and ] into { and }
const simd8x64<uint8_t> curlified{
in.chunks[0] | 0x20,
in.chunks[1] | 0x20,
in.chunks[2] | 0x20,
in.chunks[3] | 0x20
};
const uint64_t op = curlified.eq({
_mm_shuffle_epi8(op_table, in.chunks[0]),
_mm_shuffle_epi8(op_table, in.chunks[1]),
_mm_shuffle_epi8(op_table, in.chunks[2]),
_mm_shuffle_epi8(op_table, in.chunks[3])
});
return { whitespace, op };
}
simdjson_really_inline bool is_ascii(const simd8x64<uint8_t>& input) {
return input.reduce_or().is_ascii();
}
simdjson_unused simdjson_really_inline simd8<bool> must_be_continuation(const simd8<uint8_t> prev1, const simd8<uint8_t> prev2, const simd8<uint8_t> prev3) {
simd8<uint8_t> is_second_byte = prev1.saturating_sub(0b11000000u-1); // Only 11______ will be > 0
simd8<uint8_t> is_third_byte = prev2.saturating_sub(0b11100000u-1); // Only 111_____ will be > 0
simd8<uint8_t> is_fourth_byte = prev3.saturating_sub(0b11110000u-1); // Only 1111____ will be > 0
// Caller requires a bool (all 1's). All values resulting from the subtraction will be <= 64, so signed comparison is fine.
return simd8<int8_t>(is_second_byte | is_third_byte | is_fourth_byte) > int8_t(0);
}
simdjson_really_inline simd8<bool> must_be_2_3_continuation(const simd8<uint8_t> prev2, const simd8<uint8_t> prev3) {
simd8<uint8_t> is_third_byte = prev2.saturating_sub(0b11100000u-1); // Only 111_____ will be > 0
simd8<uint8_t> is_fourth_byte = prev3.saturating_sub(0b11110000u-1); // Only 1111____ will be > 0
// Caller requires a bool (all 1's). All values resulting from the subtraction will be <= 64, so signed comparison is fine.
return simd8<int8_t>(is_third_byte | is_fourth_byte) > int8_t(0);
}
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* begin file src/generic/stage1/utf8_lookup4_algorithm.h */
namespace simdjson {
namespace westmere {
namespace {
namespace utf8_validation {
using namespace simd;
simdjson_really_inline simd8<uint8_t> check_special_cases(const simd8<uint8_t> input, const simd8<uint8_t> prev1) {
// Bit 0 = Too Short (lead byte/ASCII followed by lead byte/ASCII)
// Bit 1 = Too Long (ASCII followed by continuation)
// Bit 2 = Overlong 3-byte
// Bit 4 = Surrogate
// Bit 5 = Overlong 2-byte
// Bit 7 = Two Continuations
constexpr const uint8_t TOO_SHORT = 1<<0; // 11______ 0_______
// 11______ 11______
constexpr const uint8_t TOO_LONG = 1<<1; // 0_______ 10______
constexpr const uint8_t OVERLONG_3 = 1<<2; // 11100000 100_____
constexpr const uint8_t SURROGATE = 1<<4; // 11101101 101_____
constexpr const uint8_t OVERLONG_2 = 1<<5; // 1100000_ 10______
constexpr const uint8_t TWO_CONTS = 1<<7; // 10______ 10______
constexpr const uint8_t TOO_LARGE = 1<<3; // 11110100 1001____
// 11110100 101_____
// 11110101 1001____
// 11110101 101_____
// 1111011_ 1001____
// 1111011_ 101_____
// 11111___ 1001____
// 11111___ 101_____
constexpr const uint8_t TOO_LARGE_1000 = 1<<6;
// 11110101 1000____
// 1111011_ 1000____
// 11111___ 1000____
constexpr const uint8_t OVERLONG_4 = 1<<6; // 11110000 1000____
const simd8<uint8_t> byte_1_high = prev1.shr<4>().lookup_16<uint8_t>(
// 0_______ ________ <ASCII in byte 1>
TOO_LONG, TOO_LONG, TOO_LONG, TOO_LONG,
TOO_LONG, TOO_LONG, TOO_LONG, TOO_LONG,
// 10______ ________ <continuation in byte 1>
TWO_CONTS, TWO_CONTS, TWO_CONTS, TWO_CONTS,
// 1100____ ________ <two byte lead in byte 1>
TOO_SHORT | OVERLONG_2,
// 1101____ ________ <two byte lead in byte 1>
TOO_SHORT,
// 1110____ ________ <three byte lead in byte 1>
TOO_SHORT | OVERLONG_3 | SURROGATE,
// 1111____ ________ <four+ byte lead in byte 1>
TOO_SHORT | TOO_LARGE | TOO_LARGE_1000 | OVERLONG_4
);
constexpr const uint8_t CARRY = TOO_SHORT | TOO_LONG | TWO_CONTS; // These all have ____ in byte 1 .
const simd8<uint8_t> byte_1_low = (prev1 & 0x0F).lookup_16<uint8_t>(
// ____0000 ________
CARRY | OVERLONG_3 | OVERLONG_2 | OVERLONG_4,
// ____0001 ________
CARRY | OVERLONG_2,
// ____001_ ________
CARRY,
CARRY,
// ____0100 ________
CARRY | TOO_LARGE,
// ____0101 ________
CARRY | TOO_LARGE | TOO_LARGE_1000,
// ____011_ ________
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
// ____1___ ________
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000,
// ____1101 ________
CARRY | TOO_LARGE | TOO_LARGE_1000 | SURROGATE,
CARRY | TOO_LARGE | TOO_LARGE_1000,
CARRY | TOO_LARGE | TOO_LARGE_1000
);
const simd8<uint8_t> byte_2_high = input.shr<4>().lookup_16<uint8_t>(
// ________ 0_______ <ASCII in byte 2>
TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT,
TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT,
// ________ 1000____
TOO_LONG | OVERLONG_2 | TWO_CONTS | OVERLONG_3 | TOO_LARGE_1000 | OVERLONG_4,
// ________ 1001____
TOO_LONG | OVERLONG_2 | TWO_CONTS | OVERLONG_3 | TOO_LARGE,
// ________ 101_____
TOO_LONG | OVERLONG_2 | TWO_CONTS | SURROGATE | TOO_LARGE,
TOO_LONG | OVERLONG_2 | TWO_CONTS | SURROGATE | TOO_LARGE,
// ________ 11______
TOO_SHORT, TOO_SHORT, TOO_SHORT, TOO_SHORT
);
return (byte_1_high & byte_1_low & byte_2_high);
}
simdjson_really_inline simd8<uint8_t> check_multibyte_lengths(const simd8<uint8_t> input,
const simd8<uint8_t> prev_input, const simd8<uint8_t> sc) {
simd8<uint8_t> prev2 = input.prev<2>(prev_input);
simd8<uint8_t> prev3 = input.prev<3>(prev_input);
simd8<uint8_t> must23 = simd8<uint8_t>(must_be_2_3_continuation(prev2, prev3));
simd8<uint8_t> must23_80 = must23 & uint8_t(0x80);
return must23_80 ^ sc;
}
//
// Return nonzero if there are incomplete multibyte characters at the end of the block:
// e.g. if there is a 4-byte character, but it's 3 bytes from the end.
//
simdjson_really_inline simd8<uint8_t> is_incomplete(const simd8<uint8_t> input) {
// If the previous input's last 3 bytes match this, they're too short (they ended at EOF):
// ... 1111____ 111_____ 11______
static const uint8_t max_array[32] = {
255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 0b11110000u-1, 0b11100000u-1, 0b11000000u-1
};
const simd8<uint8_t> max_value(&max_array[sizeof(max_array)-sizeof(simd8<uint8_t>)]);
return input.gt_bits(max_value);
}
struct utf8_checker {
// If this is nonzero, there has been a UTF-8 error.
simd8<uint8_t> error;
// The last input we received
simd8<uint8_t> prev_input_block;
// Whether the last input we received was incomplete (used for ASCII fast path)
simd8<uint8_t> prev_incomplete;
//
// Check whether the current bytes are valid UTF-8.
//
simdjson_really_inline void check_utf8_bytes(const simd8<uint8_t> input, const simd8<uint8_t> prev_input) {
// Flip prev1...prev3 so we can easily determine if they are 2+, 3+ or 4+ lead bytes
// (2, 3, 4-byte leads become large positive numbers instead of small negative numbers)
simd8<uint8_t> prev1 = input.prev<1>(prev_input);
simd8<uint8_t> sc = check_special_cases(input, prev1);
this->error |= check_multibyte_lengths(input, prev_input, sc);
}
// The only problem that can happen at EOF is that a multibyte character is too short
// or a byte value too large in the last bytes: check_special_cases only checks for bytes
// too large in the first of two bytes.
simdjson_really_inline void check_eof() {
// If the previous block had incomplete UTF-8 characters at the end, an ASCII block can't
// possibly finish them.
this->error |= this->prev_incomplete;
}
simdjson_really_inline void check_next_input(const simd8x64<uint8_t>& input) {
if(simdjson_likely(is_ascii(input))) {
this->error |= this->prev_incomplete;
} else {
// you might think that a for-loop would work, but under Visual Studio, it is not good enough.
static_assert((simd8x64<uint8_t>::NUM_CHUNKS == 2) || (simd8x64<uint8_t>::NUM_CHUNKS == 4),
"We support either two or four chunks per 64-byte block.");
if(simd8x64<uint8_t>::NUM_CHUNKS == 2) {
this->check_utf8_bytes(input.chunks[0], this->prev_input_block);
this->check_utf8_bytes(input.chunks[1], input.chunks[0]);
} else if(simd8x64<uint8_t>::NUM_CHUNKS == 4) {
this->check_utf8_bytes(input.chunks[0], this->prev_input_block);
this->check_utf8_bytes(input.chunks[1], input.chunks[0]);
this->check_utf8_bytes(input.chunks[2], input.chunks[1]);
this->check_utf8_bytes(input.chunks[3], input.chunks[2]);
}
this->prev_incomplete = is_incomplete(input.chunks[simd8x64<uint8_t>::NUM_CHUNKS-1]);
this->prev_input_block = input.chunks[simd8x64<uint8_t>::NUM_CHUNKS-1];
}
}
// do not forget to call check_eof!
simdjson_really_inline error_code errors() {
return this->error.any_bits_set_anywhere() ? error_code::UTF8_ERROR : error_code::SUCCESS;
}
}; // struct utf8_checker
} // namespace utf8_validation
using utf8_validation::utf8_checker;
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* end file src/generic/stage1/utf8_lookup4_algorithm.h */
/* begin file src/generic/stage1/json_structural_indexer.h */
// This file contains the common code every implementation uses in stage1
// It is intended to be included multiple times and compiled multiple times
// We assume the file in which it is included already includes
// "simdjson/stage1.h" (this simplifies amalgation)
/* begin file src/generic/stage1/buf_block_reader.h */
namespace simdjson {
namespace westmere {
namespace {
// Walks through a buffer in block-sized increments, loading the last part with spaces
template<size_t STEP_SIZE>
struct buf_block_reader {
public:
simdjson_really_inline buf_block_reader(const uint8_t *_buf, size_t _len);
simdjson_really_inline size_t block_index();
simdjson_really_inline bool has_full_block() const;
simdjson_really_inline const uint8_t *full_block() const;
/**
* Get the last block, padded with spaces.
*
* There will always be a last block, with at least 1 byte, unless len == 0 (in which case this
* function fills the buffer with spaces and returns 0. In particular, if len == STEP_SIZE there
* will be 0 full_blocks and 1 remainder block with STEP_SIZE bytes and no spaces for padding.
*
* @return the number of effective characters in the last block.
*/
simdjson_really_inline size_t get_remainder(uint8_t *dst) const;
simdjson_really_inline void advance();
private:
const uint8_t *buf;
const size_t len;
const size_t lenminusstep;
size_t idx;
};
// Routines to print masks and text for debugging bitmask operations
simdjson_unused static char * format_input_text_64(const uint8_t *text) {
static char *buf = (char*)malloc(sizeof(simd8x64<uint8_t>) + 1);
for (size_t i=0; i<sizeof(simd8x64<uint8_t>); i++) {
buf[i] = int8_t(text[i]) < ' ' ? '_' : int8_t(text[i]);
}
buf[sizeof(simd8x64<uint8_t>)] = '\0';
return buf;
}
// Routines to print masks and text for debugging bitmask operations
simdjson_unused static char * format_input_text(const simd8x64<uint8_t>& in) {
static char *buf = (char*)malloc(sizeof(simd8x64<uint8_t>) + 1);
in.store((uint8_t*)buf);
for (size_t i=0; i<sizeof(simd8x64<uint8_t>); i++) {
if (buf[i] < ' ') { buf[i] = '_'; }
}
buf[sizeof(simd8x64<uint8_t>)] = '\0';
return buf;
}
simdjson_unused static char * format_mask(uint64_t mask) {
static char *buf = (char*)malloc(64 + 1);
for (size_t i=0; i<64; i++) {
buf[i] = (mask & (size_t(1) << i)) ? 'X' : ' ';
}
buf[64] = '\0';
return buf;
}
template<size_t STEP_SIZE>
simdjson_really_inline buf_block_reader<STEP_SIZE>::buf_block_reader(const uint8_t *_buf, size_t _len) : buf{_buf}, len{_len}, lenminusstep{len < STEP_SIZE ? 0 : len - STEP_SIZE}, idx{0} {}
template<size_t STEP_SIZE>
simdjson_really_inline size_t buf_block_reader<STEP_SIZE>::block_index() { return idx; }
template<size_t STEP_SIZE>
simdjson_really_inline bool buf_block_reader<STEP_SIZE>::has_full_block() const {
return idx < lenminusstep;
}
template<size_t STEP_SIZE>
simdjson_really_inline const uint8_t *buf_block_reader<STEP_SIZE>::full_block() const {
return &buf[idx];
}
template<size_t STEP_SIZE>
simdjson_really_inline size_t buf_block_reader<STEP_SIZE>::get_remainder(uint8_t *dst) const {
if(len == idx) { return 0; } // memcpy(dst, null, 0) will trigger an error with some sanitizers
std::memset(dst, 0x20, STEP_SIZE); // std::memset STEP_SIZE because it's more efficient to write out 8 or 16 bytes at once.
std::memcpy(dst, buf + idx, len - idx);
return len - idx;
}
template<size_t STEP_SIZE>
simdjson_really_inline void buf_block_reader<STEP_SIZE>::advance() {
idx += STEP_SIZE;
}
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* end file src/generic/stage1/buf_block_reader.h */
/* begin file src/generic/stage1/json_string_scanner.h */
namespace simdjson {
namespace westmere {
namespace {
namespace stage1 {
struct json_string_block {
// Escaped characters (characters following an escape() character)
simdjson_really_inline uint64_t escaped() const { return _escaped; }
// Escape characters (backslashes that are not escaped--i.e. in \\, includes only the first \)
simdjson_really_inline uint64_t escape() const { return _backslash & ~_escaped; }
// Real (non-backslashed) quotes
simdjson_really_inline uint64_t quote() const { return _quote; }
// Start quotes of strings
simdjson_really_inline uint64_t string_start() const { return _quote & _in_string; }
// End quotes of strings
simdjson_really_inline uint64_t string_end() const { return _quote & ~_in_string; }
// Only characters inside the string (not including the quotes)
simdjson_really_inline uint64_t string_content() const { return _in_string & ~_quote; }
// Return a mask of whether the given characters are inside a string (only works on non-quotes)
simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) const { return mask & _in_string; }
// Return a mask of whether the given characters are inside a string (only works on non-quotes)
simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) const { return mask & ~_in_string; }
// Tail of string (everything except the start quote)
simdjson_really_inline uint64_t string_tail() const { return _in_string ^ _quote; }
// backslash characters
uint64_t _backslash;
// escaped characters (backslashed--does not include the hex characters after \u)
uint64_t _escaped;
// real quotes (non-backslashed ones)
uint64_t _quote;
// string characters (includes start quote but not end quote)
uint64_t _in_string;
};
// Scans blocks for string characters, storing the state necessary to do so
class json_string_scanner {
public:
simdjson_really_inline json_string_block next(const simd::simd8x64<uint8_t>& in);
// Returns either UNCLOSED_STRING or SUCCESS
simdjson_really_inline error_code finish();
private:
// Intended to be defined by the implementation
simdjson_really_inline uint64_t find_escaped(uint64_t escape);
simdjson_really_inline uint64_t find_escaped_branchless(uint64_t escape);
// Whether the last iteration was still inside a string (all 1's = true, all 0's = false).
uint64_t prev_in_string = 0ULL;
// Whether the first character of the next iteration is escaped.
uint64_t prev_escaped = 0ULL;
};
//
// Finds escaped characters (characters following \).
//
// Handles runs of backslashes like \\\" and \\\\" correctly (yielding 0101 and 01010, respectively).
//
// Does this by:
// - Shift the escape mask to get potentially escaped characters (characters after backslashes).
// - Mask escaped sequences that start on *even* bits with 1010101010 (odd bits are escaped, even bits are not)
// - Mask escaped sequences that start on *odd* bits with 0101010101 (even bits are escaped, odd bits are not)
//
// To distinguish between escaped sequences starting on even/odd bits, it finds the start of all
// escape sequences, filters out the ones that start on even bits, and adds that to the mask of
// escape sequences. This causes the addition to clear out the sequences starting on odd bits (since
// the start bit causes a carry), and leaves even-bit sequences alone.
//
// Example:
//
// text | \\\ | \\\"\\\" \\\" \\"\\" |
// escape | xxx | xx xxx xxx xx xx | Removed overflow backslash; will | it into follows_escape
// odd_starts | x | x x x | escape & ~even_bits & ~follows_escape
// even_seq | c| cxxx c xx c | c = carry bit -- will be masked out later
// invert_mask | | cxxx c xx c| even_seq << 1
// follows_escape | xx | x xx xxx xxx xx xx | Includes overflow bit
// escaped | x | x x x x x x x x |
// desired | x | x x x x x x x x |
// text | \\\ | \\\"\\\" \\\" \\"\\" |
//
simdjson_really_inline uint64_t json_string_scanner::find_escaped_branchless(uint64_t backslash) {
// If there was overflow, pretend the first character isn't a backslash
backslash &= ~prev_escaped;
uint64_t follows_escape = backslash << 1 | prev_escaped;
// Get sequences starting on even bits by clearing out the odd series using +
const uint64_t even_bits = 0x5555555555555555ULL;
uint64_t odd_sequence_starts = backslash & ~even_bits & ~follows_escape;
uint64_t sequences_starting_on_even_bits;
prev_escaped = add_overflow(odd_sequence_starts, backslash, &sequences_starting_on_even_bits);
uint64_t invert_mask = sequences_starting_on_even_bits << 1; // The mask we want to return is the *escaped* bits, not escapes.
// Mask every other backslashed character as an escaped character
// Flip the mask for sequences that start on even bits, to correct them
return (even_bits ^ invert_mask) & follows_escape;
}
//
// Return a mask of all string characters plus end quotes.
//
// prev_escaped is overflow saying whether the next character is escaped.
// prev_in_string is overflow saying whether we're still in a string.
//
// Backslash sequences outside of quotes will be detected in stage 2.
//
simdjson_really_inline json_string_block json_string_scanner::next(const simd::simd8x64<uint8_t>& in) {
const uint64_t backslash = in.eq('\\');
const uint64_t escaped = find_escaped(backslash);
const uint64_t quote = in.eq('"') & ~escaped;
//
// prefix_xor flips on bits inside the string (and flips off the end quote).
//
// Then we xor with prev_in_string: if we were in a string already, its effect is flipped
// (characters inside strings are outside, and characters outside strings are inside).
//
const uint64_t in_string = prefix_xor(quote) ^ prev_in_string;
//
// Check if we're still in a string at the end of the box so the next block will know
//
// right shift of a signed value expected to be well-defined and standard
// compliant as of C++20, John Regher from Utah U. says this is fine code
//
prev_in_string = uint64_t(static_cast<int64_t>(in_string) >> 63);
// Use ^ to turn the beginning quote off, and the end quote on.
return {
backslash,
escaped,
quote,
in_string
};
}
simdjson_really_inline error_code json_string_scanner::finish() {
if (prev_in_string) {
return UNCLOSED_STRING;
}
return SUCCESS;
}
} // namespace stage1
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* end file src/generic/stage1/json_string_scanner.h */
/* begin file src/generic/stage1/json_scanner.h */
namespace simdjson {
namespace westmere {
namespace {
namespace stage1 {
/**
* A block of scanned json, with information on operators and scalars.
*
* We seek to identify pseudo-structural characters. Anything that is inside
* a string must be omitted (hence & ~_string.string_tail()).
* Otherwise, pseudo-structural characters come in two forms.
* 1. We have the structural characters ([,],{,},:, comma). The
* term 'structural character' is from the JSON RFC.
* 2. We have the 'scalar pseudo-structural characters'.
* Scalars are quotes, and any character except structural characters and white space.
*
* To identify the scalar pseudo-structural characters, we must look at what comes
* before them: it must be a space, a quote or a structural characters.
* Starting with simdjson v0.3, we identify them by
* negation: we identify everything that is followed by a non-quote scalar,
* and we negate that. Whatever remains must be a 'scalar pseudo-structural character'.
*/
struct json_block {
public:
/**
* The start of structurals.
* In simdjson prior to v0.3, these were called the pseudo-structural characters.
**/
simdjson_really_inline uint64_t structural_start() { return potential_structural_start() & ~_string.string_tail(); }
/** All JSON whitespace (i.e. not in a string) */
simdjson_really_inline uint64_t whitespace() { return non_quote_outside_string(_characters.whitespace()); }
// Helpers
/** Whether the given characters are inside a string (only works on non-quotes) */
simdjson_really_inline uint64_t non_quote_inside_string(uint64_t mask) { return _string.non_quote_inside_string(mask); }
/** Whether the given characters are outside a string (only works on non-quotes) */
simdjson_really_inline uint64_t non_quote_outside_string(uint64_t mask) { return _string.non_quote_outside_string(mask); }
// string and escape characters
json_string_block _string;
// whitespace, structural characters ('operators'), scalars
json_character_block _characters;
// whether the previous character was a scalar
uint64_t _follows_potential_nonquote_scalar;
private:
// Potential structurals (i.e. disregarding strings)
/**
* structural elements ([,],{,},:, comma) plus scalar starts like 123, true and "abc".
* They may reside inside a string.
**/
simdjson_really_inline uint64_t potential_structural_start() { return _characters.op() | potential_scalar_start(); }
/**
* The start of non-operator runs, like 123, true and "abc".
* It main reside inside a string.
**/
simdjson_really_inline uint64_t potential_scalar_start() {
// The term "scalar" refers to anything except structural characters and white space
// (so letters, numbers, quotes).
// Whenever it is preceded by something that is not a structural element ({,},[,],:, ") nor a white-space
// then we know that it is irrelevant structurally.
return _characters.scalar() & ~follows_potential_scalar();
}
/**
* Whether the given character is immediately after a non-operator like 123, true.
* The characters following a quote are not included.
*/
simdjson_really_inline uint64_t follows_potential_scalar() {
// _follows_potential_nonquote_scalar: is defined as marking any character that follows a character
// that is not a structural element ({,},[,],:, comma) nor a quote (") and that is not a
// white space.
// It is understood that within quoted region, anything at all could be marked (irrelevant).
return _follows_potential_nonquote_scalar;
}
};
/**
* Scans JSON for important bits: structural characters or 'operators', strings, and scalars.
*
* The scanner starts by calculating two distinct things:
* - string characters (taking \" into account)
* - structural characters or 'operators' ([]{},:, comma)
* and scalars (runs of non-operators like 123, true and "abc")
*
* To minimize data dependency (a key component of the scanner's speed), it finds these in parallel:
* in particular, the operator/scalar bit will find plenty of things that are actually part of
* strings. When we're done, json_block will fuse the two together by masking out tokens that are
* part of a string.
*/
class json_scanner {
public:
json_scanner() {}
simdjson_really_inline json_block next(const simd::simd8x64<uint8_t>& in);
// Returns either UNCLOSED_STRING or SUCCESS
simdjson_really_inline error_code finish();
private:
// Whether the last character of the previous iteration is part of a scalar token
// (anything except whitespace or a structural character/'operator').
uint64_t prev_scalar = 0ULL;
json_string_scanner string_scanner{};
};
//
// Check if the current character immediately follows a matching character.
//
// For example, this checks for quotes with backslashes in front of them:
//
// const uint64_t backslashed_quote = in.eq('"') & immediately_follows(in.eq('\'), prev_backslash);
//
simdjson_really_inline uint64_t follows(const uint64_t match, uint64_t &overflow) {
const uint64_t result = match << 1 | overflow;
overflow = match >> 63;
return result;
}
simdjson_really_inline json_block json_scanner::next(const simd::simd8x64<uint8_t>& in) {
json_string_block strings = string_scanner.next(in);
// identifies the white-space and the structurat characters
json_character_block characters = json_character_block::classify(in);
// The term "scalar" refers to anything except structural characters and white space
// (so letters, numbers, quotes).
// We want follows_scalar to mark anything that follows a non-quote scalar (so letters and numbers).
//
// A terminal quote should either be followed by a structural character (comma, brace, bracket, colon)
// or nothing. However, we still want ' "a string"true ' to mark the 't' of 'true' as a potential
// pseudo-structural character just like we would if we had ' "a string" true '; otherwise we
// may need to add an extra check when parsing strings.
//
// Performance: there are many ways to skin this cat.
const uint64_t nonquote_scalar = characters.scalar() & ~strings.quote();
uint64_t follows_nonquote_scalar = follows(nonquote_scalar, prev_scalar);
return {
strings,
characters,
follows_nonquote_scalar
};
}
simdjson_really_inline error_code json_scanner::finish() {
return string_scanner.finish();
}
} // namespace stage1
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* end file src/generic/stage1/json_scanner.h */
/* begin file src/generic/stage1/json_minifier.h */
// This file contains the common code every implementation uses in stage1
// It is intended to be included multiple times and compiled multiple times
// We assume the file in which it is included already includes
// "simdjson/stage1.h" (this simplifies amalgation)
namespace simdjson {
namespace westmere {
namespace {
namespace stage1 {
class json_minifier {
public:
template<size_t STEP_SIZE>
static error_code minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) noexcept;
private:
simdjson_really_inline json_minifier(uint8_t *_dst)
: dst{_dst}
{}
template<size_t STEP_SIZE>
simdjson_really_inline void step(const uint8_t *block_buf, buf_block_reader<STEP_SIZE> &reader) noexcept;
simdjson_really_inline void next(const simd::simd8x64<uint8_t>& in, json_block block);
simdjson_really_inline error_code finish(uint8_t *dst_start, size_t &dst_len);
json_scanner scanner{};
uint8_t *dst;
};
simdjson_really_inline void json_minifier::next(const simd::simd8x64<uint8_t>& in, json_block block) {
uint64_t mask = block.whitespace();
in.compress(mask, dst);
dst += 64 - count_ones(mask);
}
simdjson_really_inline error_code json_minifier::finish(uint8_t *dst_start, size_t &dst_len) {
error_code error = scanner.finish();
if (error) { dst_len = 0; return error; }
dst_len = dst - dst_start;
return SUCCESS;
}
template<>
simdjson_really_inline void json_minifier::step<128>(const uint8_t *block_buf, buf_block_reader<128> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block_buf);
simd::simd8x64<uint8_t> in_2(block_buf+64);
json_block block_1 = scanner.next(in_1);
json_block block_2 = scanner.next(in_2);
this->next(in_1, block_1);
this->next(in_2, block_2);
reader.advance();
}
template<>
simdjson_really_inline void json_minifier::step<64>(const uint8_t *block_buf, buf_block_reader<64> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block_buf);
json_block block_1 = scanner.next(in_1);
this->next(block_buf, block_1);
reader.advance();
}
template<size_t STEP_SIZE>
error_code json_minifier::minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) noexcept {
buf_block_reader<STEP_SIZE> reader(buf, len);
json_minifier minifier(dst);
// Index the first n-1 blocks
while (reader.has_full_block()) {
minifier.step<STEP_SIZE>(reader.full_block(), reader);
}
// Index the last (remainder) block, padded with spaces
uint8_t block[STEP_SIZE];
size_t remaining_bytes = reader.get_remainder(block);
if (remaining_bytes > 0) {
// We do not want to write directly to the output stream. Rather, we write
// to a local buffer (for safety).
uint8_t out_block[STEP_SIZE];
uint8_t * const guarded_dst{minifier.dst};
minifier.dst = out_block;
minifier.step<STEP_SIZE>(block, reader);
size_t to_write = minifier.dst - out_block;
// In some cases, we could be enticed to consider the padded spaces
// as part of the string. This is fine as long as we do not write more
// than we consumed.
if(to_write > remaining_bytes) { to_write = remaining_bytes; }
memcpy(guarded_dst, out_block, to_write);
minifier.dst = guarded_dst + to_write;
}
return minifier.finish(dst, dst_len);
}
} // namespace stage1
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* end file src/generic/stage1/json_minifier.h */
/* begin file src/generic/stage1/find_next_document_index.h */
namespace simdjson {
namespace westmere {
namespace {
/**
* This algorithm is used to quickly identify the last structural position that
* makes up a complete document.
*
* It does this by going backwards and finding the last *document boundary* (a
* place where one value follows another without a comma between them). If the
* last document (the characters after the boundary) has an equal number of
* start and end brackets, it is considered complete.
*
* Simply put, we iterate over the structural characters, starting from
* the end. We consider that we found the end of a JSON document when the
* first element of the pair is NOT one of these characters: '{' '[' ';' ','
* and when the second element is NOT one of these characters: '}' '}' ';' ','.
*
* This simple comparison works most of the time, but it does not cover cases
* where the batch's structural indexes contain a perfect amount of documents.
* In such a case, we do not have access to the structural index which follows
* the last document, therefore, we do not have access to the second element in
* the pair, and that means we cannot identify the last document. To fix this
* issue, we keep a count of the open and closed curly/square braces we found
* while searching for the pair. When we find a pair AND the count of open and
* closed curly/square braces is the same, we know that we just passed a
* complete document, therefore the last json buffer location is the end of the
* batch.
*/
simdjson_really_inline uint32_t find_next_document_index(dom_parser_implementation &parser) {
// TODO don't count separately, just figure out depth
auto arr_cnt = 0;
auto obj_cnt = 0;
for (auto i = parser.n_structural_indexes - 1; i > 0; i--) {
auto idxb = parser.structural_indexes[i];
switch (parser.buf[idxb]) {
case ':':
case ',':
continue;
case '}':
obj_cnt--;
continue;
case ']':
arr_cnt--;
continue;
case '{':
obj_cnt++;
break;
case '[':
arr_cnt++;
break;
}
auto idxa = parser.structural_indexes[i - 1];
switch (parser.buf[idxa]) {
case '{':
case '[':
case ':':
case ',':
continue;
}
// Last document is complete, so the next document will appear after!
if (!arr_cnt && !obj_cnt) {
return parser.n_structural_indexes;
}
// Last document is incomplete; mark the document at i + 1 as the next one
return i;
}
return 0;
}
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* end file src/generic/stage1/find_next_document_index.h */
namespace simdjson {
namespace westmere {
namespace {
namespace stage1 {
class bit_indexer {
public:
uint32_t *tail;
simdjson_really_inline bit_indexer(uint32_t *index_buf) : tail(index_buf) {}
// flatten out values in 'bits' assuming that they are are to have values of idx
// plus their position in the bitvector, and store these indexes at
// base_ptr[base] incrementing base as we go
// will potentially store extra values beyond end of valid bits, so base_ptr
// needs to be large enough to handle this
simdjson_really_inline void write(uint32_t idx, uint64_t bits) {
// In some instances, the next branch is expensive because it is mispredicted.
// Unfortunately, in other cases,
// it helps tremendously.
if (bits == 0)
return;
int cnt = static_cast<int>(count_ones(bits));
// Do the first 8 all together
for (int i=0; i<8; i++) {
this->tail[i] = idx + trailing_zeroes(bits);
bits = clear_lowest_bit(bits);
}
// Do the next 8 all together (we hope in most cases it won't happen at all
// and the branch is easily predicted).
if (simdjson_unlikely(cnt > 8)) {
for (int i=8; i<16; i++) {
this->tail[i] = idx + trailing_zeroes(bits);
bits = clear_lowest_bit(bits);
}
// Most files don't have 16+ structurals per block, so we take several basically guaranteed
// branch mispredictions here. 16+ structurals per block means either punctuation ({} [] , :)
// or the start of a value ("abc" true 123) every four characters.
if (simdjson_unlikely(cnt > 16)) {
int i = 16;
do {
this->tail[i] = idx + trailing_zeroes(bits);
bits = clear_lowest_bit(bits);
i++;
} while (i < cnt);
}
}
this->tail += cnt;
}
};
class json_structural_indexer {
public:
/**
* Find the important bits of JSON in a 128-byte chunk, and add them to structural_indexes.
*
* @param partial Setting the partial parameter to true allows the find_structural_bits to
* tolerate unclosed strings. The caller should still ensure that the input is valid UTF-8. If
* you are processing substrings, you may want to call on a function like trimmed_length_safe_utf8.
*/
template<size_t STEP_SIZE>
static error_code index(const uint8_t *buf, size_t len, dom_parser_implementation &parser, bool partial) noexcept;
private:
simdjson_really_inline json_structural_indexer(uint32_t *structural_indexes);
template<size_t STEP_SIZE>
simdjson_really_inline void step(const uint8_t *block, buf_block_reader<STEP_SIZE> &reader) noexcept;
simdjson_really_inline void next(const simd::simd8x64<uint8_t>& in, json_block block, size_t idx);
simdjson_really_inline error_code finish(dom_parser_implementation &parser, size_t idx, size_t len, bool partial);
json_scanner scanner{};
utf8_checker checker{};
bit_indexer indexer;
uint64_t prev_structurals = 0;
uint64_t unescaped_chars_error = 0;
};
simdjson_really_inline json_structural_indexer::json_structural_indexer(uint32_t *structural_indexes) : indexer{structural_indexes} {}
// Skip the last character if it is partial
simdjson_really_inline size_t trim_partial_utf8(const uint8_t *buf, size_t len) {
if (simdjson_unlikely(len < 3)) {
switch (len) {
case 2:
if (buf[len-1] >= 0b11000000) { return len-1; } // 2-, 3- and 4-byte characters with only 1 byte left
if (buf[len-2] >= 0b11100000) { return len-2; } // 3- and 4-byte characters with only 2 bytes left
return len;
case 1:
if (buf[len-1] >= 0b11000000) { return len-1; } // 2-, 3- and 4-byte characters with only 1 byte left
return len;
case 0:
return len;
}
}
if (buf[len-1] >= 0b11000000) { return len-1; } // 2-, 3- and 4-byte characters with only 1 byte left
if (buf[len-2] >= 0b11100000) { return len-2; } // 3- and 4-byte characters with only 1 byte left
if (buf[len-3] >= 0b11110000) { return len-3; } // 4-byte characters with only 3 bytes left
return len;
}
//
// PERF NOTES:
// We pipe 2 inputs through these stages:
// 1. Load JSON into registers. This takes a long time and is highly parallelizable, so we load
// 2 inputs' worth at once so that by the time step 2 is looking for them input, it's available.
// 2. Scan the JSON for critical data: strings, scalars and operators. This is the critical path.
// The output of step 1 depends entirely on this information. These functions don't quite use
// up enough CPU: the second half of the functions is highly serial, only using 1 execution core
// at a time. The second input's scans has some dependency on the first ones finishing it, but
// they can make a lot of progress before they need that information.
// 3. Step 1 doesn't use enough capacity, so we run some extra stuff while we're waiting for that
// to finish: utf-8 checks and generating the output from the last iteration.
//
// The reason we run 2 inputs at a time, is steps 2 and 3 are *still* not enough to soak up all
// available capacity with just one input. Running 2 at a time seems to give the CPU a good enough
// workout.
//
template<size_t STEP_SIZE>
error_code json_structural_indexer::index(const uint8_t *buf, size_t len, dom_parser_implementation &parser, bool partial) noexcept {
if (simdjson_unlikely(len > parser.capacity())) { return CAPACITY; }
if (partial) { len = trim_partial_utf8(buf, len); }
buf_block_reader<STEP_SIZE> reader(buf, len);
json_structural_indexer indexer(parser.structural_indexes.get());
// Read all but the last block
while (reader.has_full_block()) {
indexer.step<STEP_SIZE>(reader.full_block(), reader);
}
// Take care of the last block (will always be there unless file is empty)
uint8_t block[STEP_SIZE];
if (simdjson_unlikely(reader.get_remainder(block) == 0)) { return EMPTY; }
indexer.step<STEP_SIZE>(block, reader);
return indexer.finish(parser, reader.block_index(), len, partial);
}
template<>
simdjson_really_inline void json_structural_indexer::step<128>(const uint8_t *block, buf_block_reader<128> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block);
simd::simd8x64<uint8_t> in_2(block+64);
json_block block_1 = scanner.next(in_1);
json_block block_2 = scanner.next(in_2);
this->next(in_1, block_1, reader.block_index());
this->next(in_2, block_2, reader.block_index()+64);
reader.advance();
}
template<>
simdjson_really_inline void json_structural_indexer::step<64>(const uint8_t *block, buf_block_reader<64> &reader) noexcept {
simd::simd8x64<uint8_t> in_1(block);
json_block block_1 = scanner.next(in_1);
this->next(in_1, block_1, reader.block_index());
reader.advance();
}
simdjson_really_inline void json_structural_indexer::next(const simd::simd8x64<uint8_t>& in, json_block block, size_t idx) {
uint64_t unescaped = in.lteq(0x1F);
checker.check_next_input(in);
indexer.write(uint32_t(idx-64), prev_structurals); // Output *last* iteration's structurals to the parser
prev_structurals = block.structural_start();
unescaped_chars_error |= block.non_quote_inside_string(unescaped);
}
simdjson_really_inline error_code json_structural_indexer::finish(dom_parser_implementation &parser, size_t idx, size_t len, bool partial) {
// Write out the final iteration's structurals
indexer.write(uint32_t(idx-64), prev_structurals);
error_code error = scanner.finish();
// We deliberately break down the next expression so that it is
// human readable.
const bool should_we_exit = partial ?
((error != SUCCESS) && (error != UNCLOSED_STRING)) // when partial we tolerate UNCLOSED_STRING
: (error != SUCCESS); // if partial is false, we must have SUCCESS
const bool have_unclosed_string = (error == UNCLOSED_STRING);
if (simdjson_unlikely(should_we_exit)) { return error; }
if (unescaped_chars_error) {
return UNESCAPED_CHARS;
}
parser.n_structural_indexes = uint32_t(indexer.tail - parser.structural_indexes.get());
/***
* This is related to https://github.com/simdjson/simdjson/issues/906
* Basically, we want to make sure that if the parsing continues beyond the last (valid)
* structural character, it quickly stops.
* Only three structural characters can be repeated without triggering an error in JSON: [,] and }.
* We repeat the padding character (at 'len'). We don't know what it is, but if the parsing
* continues, then it must be [,] or }.
* Suppose it is ] or }. We backtrack to the first character, what could it be that would
* not trigger an error? It could be ] or } but no, because you can't start a document that way.
* It can't be a comma, a colon or any simple value. So the only way we could continue is
* if the repeated character is [. But if so, the document must start with [. But if the document
* starts with [, it should end with ]. If we enforce that rule, then we would get
* ][[ which is invalid.
**/
parser.structural_indexes[parser.n_structural_indexes] = uint32_t(len);
parser.structural_indexes[parser.n_structural_indexes + 1] = uint32_t(len);
parser.structural_indexes[parser.n_structural_indexes + 2] = 0;
parser.next_structural_index = 0;
// a valid JSON file cannot have zero structural indexes - we should have found something
if (simdjson_unlikely(parser.n_structural_indexes == 0u)) {
return EMPTY;
}
if (simdjson_unlikely(parser.structural_indexes[parser.n_structural_indexes - 1] > len)) {
return UNEXPECTED_ERROR;
}
if (partial) {
// If we have an unclosed string, then the last structural
// will be the quote and we want to make sure to omit it.
if(have_unclosed_string) {
parser.n_structural_indexes--;
// a valid JSON file cannot have zero structural indexes - we should have found something
if (simdjson_unlikely(parser.n_structural_indexes == 0u)) { return CAPACITY; }
}
auto new_structural_indexes = find_next_document_index(parser);
if (new_structural_indexes == 0 && parser.n_structural_indexes > 0) {
return CAPACITY; // If the buffer is partial but the document is incomplete, it's too big to parse.
}
parser.n_structural_indexes = new_structural_indexes;
}
checker.check_eof();
return checker.errors();
}
} // namespace stage1
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* end file src/generic/stage1/json_structural_indexer.h */
/* begin file src/generic/stage1/utf8_validator.h */
namespace simdjson {
namespace westmere {
namespace {
namespace stage1 {
/**
* Validates that the string is actual UTF-8.
*/
template<class checker>
bool generic_validate_utf8(const uint8_t * input, size_t length) {
checker c{};
buf_block_reader<64> reader(input, length);
while (reader.has_full_block()) {
simd::simd8x64<uint8_t> in(reader.full_block());
c.check_next_input(in);
reader.advance();
}
uint8_t block[64]{};
reader.get_remainder(block);
simd::simd8x64<uint8_t> in(block);
c.check_next_input(in);
reader.advance();
c.check_eof();
return c.errors() == error_code::SUCCESS;
}
bool generic_validate_utf8(const char * input, size_t length) {
return generic_validate_utf8<utf8_checker>((const uint8_t *)input,length);
}
} // namespace stage1
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* end file src/generic/stage1/utf8_validator.h */
//
// Stage 2
//
/* begin file src/generic/stage2/tape_builder.h */
/* begin file src/generic/stage2/json_iterator.h */
/* begin file src/generic/stage2/logger.h */
// This is for an internal-only stage 2 specific logger.
// Set LOG_ENABLED = true to log what stage 2 is doing!
namespace simdjson {
namespace westmere {
namespace {
namespace logger {
static constexpr const char * DASHES = "----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------";
#if SIMDJSON_VERBOSE_LOGGING
static constexpr const bool LOG_ENABLED = true;
#else
static constexpr const bool LOG_ENABLED = false;
#endif
static constexpr const int LOG_EVENT_LEN = 20;
static constexpr const int LOG_BUFFER_LEN = 30;
static constexpr const int LOG_SMALL_BUFFER_LEN = 10;
static constexpr const int LOG_INDEX_LEN = 5;
static int log_depth; // Not threadsafe. Log only.
// Helper to turn unprintable or newline characters into spaces
static simdjson_really_inline char printable_char(char c) {
if (c >= 0x20) {
return c;
} else {
return ' ';
}
}
// Print the header and set up log_start
static simdjson_really_inline void log_start() {
if (LOG_ENABLED) {
log_depth = 0;
printf("\n");
printf("| %-*s | %-*s | %-*s | %-*s | Detail |\n", LOG_EVENT_LEN, "Event", LOG_BUFFER_LEN, "Buffer", LOG_SMALL_BUFFER_LEN, "Next", 5, "Next#");
printf("|%.*s|%.*s|%.*s|%.*s|--------|\n", LOG_EVENT_LEN+2, DASHES, LOG_BUFFER_LEN+2, DASHES, LOG_SMALL_BUFFER_LEN+2, DASHES, 5+2, DASHES);
}
}
simdjson_unused static simdjson_really_inline void log_string(const char *message) {
if (LOG_ENABLED) {
printf("%s\n", message);
}
}
// Logs a single line from the stage 2 DOM parser
template<typename S>
static simdjson_really_inline void log_line(S &structurals, const char *title_prefix, const char *title, const char *detail) {
if (LOG_ENABLED) {
printf("| %*s%s%-*s ", log_depth*2, "", title_prefix, LOG_EVENT_LEN - log_depth*2 - int(strlen(title_prefix)), title);
auto current_index = structurals.at_beginning() ? nullptr : structurals.next_structural-1;
auto next_index = structurals.next_structural;
auto current = current_index ? &structurals.buf[*current_index] : (const uint8_t*)" ";
auto next = &structurals.buf[*next_index];
{
// Print the next N characters in the buffer.
printf("| ");
// Otherwise, print the characters starting from the buffer position.
// Print spaces for unprintable or newline characters.
for (int i=0;i<LOG_BUFFER_LEN;i++) {
printf("%c", printable_char(current[i]));
}
printf(" ");
// Print the next N characters in the buffer.
printf("| ");
// Otherwise, print the characters starting from the buffer position.
// Print spaces for unprintable or newline characters.
for (int i=0;i<LOG_SMALL_BUFFER_LEN;i++) {
printf("%c", printable_char(next[i]));
}
printf(" ");
}
if (current_index) {
printf("| %*u ", LOG_INDEX_LEN, *current_index);
} else {
printf("| %-*s ", LOG_INDEX_LEN, "");
}
// printf("| %*u ", LOG_INDEX_LEN, structurals.next_tape_index());
printf("| %-s ", detail);
printf("|\n");
}
}
} // namespace logger
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* end file src/generic/stage2/logger.h */
namespace simdjson {
namespace westmere {
namespace {
namespace stage2 {
class json_iterator {
public:
const uint8_t* const buf;
uint32_t *next_structural;
dom_parser_implementation &dom_parser;
uint32_t depth{0};
/**
* Walk the JSON document.
*
* The visitor receives callbacks when values are encountered. All callbacks pass the iterator as
* the first parameter; some callbacks have other parameters as well:
*
* - visit_document_start() - at the beginning.
* - visit_document_end() - at the end (if things were successful).
*
* - visit_array_start() - at the start `[` of a non-empty array.
* - visit_array_end() - at the end `]` of a non-empty array.
* - visit_empty_array() - when an empty array is encountered.
*
* - visit_object_end() - at the start `]` of a non-empty object.
* - visit_object_start() - at the end `]` of a non-empty object.
* - visit_empty_object() - when an empty object is encountered.
* - visit_key(const uint8_t *key) - when a key in an object field is encountered. key is
* guaranteed to point at the first quote of the string (`"key"`).
* - visit_primitive(const uint8_t *value) - when a value is a string, number, boolean or null.
* - visit_root_primitive(iter, uint8_t *value) - when the top-level value is a string, number, boolean or null.
*
* - increment_count(iter) - each time a value is found in an array or object.
*/
template<bool STREAMING, typename V>
simdjson_warn_unused simdjson_really_inline error_code walk_document(V &visitor) noexcept;
/**
* Create an iterator capable of walking a JSON document.
*
* The document must have already passed through stage 1.
*/
simdjson_really_inline json_iterator(dom_parser_implementation &_dom_parser, size_t start_structural_index);
/**
* Look at the next token.
*
* Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)).
*
* They may include invalid JSON as well (such as `1.2.3` or `ture`).
*/
simdjson_really_inline const uint8_t *peek() const noexcept;
/**
* Advance to the next token.
*
* Tokens can be strings, numbers, booleans, null, or operators (`[{]},:`)).
*
* They may include invalid JSON as well (such as `1.2.3` or `ture`).
*/
simdjson_really_inline const uint8_t *advance() noexcept;
/**
* Get the remaining length of the document, from the start of the current token.
*/
simdjson_really_inline size_t remaining_len() const noexcept;
/**
* Check if we are at the end of the document.
*
* If this is true, there are no more tokens.
*/
simdjson_really_inline bool at_eof() const noexcept;
/**
* Check if we are at the beginning of the document.
*/
simdjson_really_inline bool at_beginning() const noexcept;
simdjson_really_inline uint8_t last_structural() const noexcept;
/**
* Log that a value has been found.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_value(const char *type) const noexcept;
/**
* Log the start of a multipart value.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_start_value(const char *type) const noexcept;
/**
* Log the end of a multipart value.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_end_value(const char *type) const noexcept;
/**
* Log an error.
*
* Set ENABLE_LOGGING=true in logger.h to see logging.
*/
simdjson_really_inline void log_error(const char *error) const noexcept;
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code visit_root_primitive(V &visitor, const uint8_t *value) noexcept;
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code visit_primitive(V &visitor, const uint8_t *value) noexcept;
};
template<bool STREAMING, typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::walk_document(V &visitor) noexcept {
logger::log_start();
//
// Start the document
//
if (at_eof()) { return EMPTY; }
log_start_value("document");
SIMDJSON_TRY( visitor.visit_document_start(*this) );
//
// Read first value
//
{
auto value = advance();
// Make sure the outer hash or array is closed before continuing; otherwise, there are ways we
// could get into memory corruption. See https://github.com/simdjson/simdjson/issues/906
if (!STREAMING) {
switch (*value) {
case '{': if (last_structural() != '}') { return TAPE_ERROR; }; break;
case '[': if (last_structural() != ']') { return TAPE_ERROR; }; break;
}
}
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_root_primitive(*this, value) ); break;
}
}
goto document_end;
//
// Object parser states
//
object_begin:
log_start_value("object");
depth++;
if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; }
dom_parser.is_array[depth] = false;
SIMDJSON_TRY( visitor.visit_object_start(*this) );
{
auto key = advance();
if (*key != '"') { log_error("Object does not start with a key"); return TAPE_ERROR; }
SIMDJSON_TRY( visitor.increment_count(*this) );
SIMDJSON_TRY( visitor.visit_key(*this, key) );
}
object_field:
if (simdjson_unlikely( *advance() != ':' )) { log_error("Missing colon after key in object"); return TAPE_ERROR; }
{
auto value = advance();
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_primitive(*this, value) ); break;
}
}
object_continue:
switch (*advance()) {
case ',':
SIMDJSON_TRY( visitor.increment_count(*this) );
{
auto key = advance();
if (simdjson_unlikely( *key != '"' )) { log_error("Key string missing at beginning of field in object"); return TAPE_ERROR; }
SIMDJSON_TRY( visitor.visit_key(*this, key) );
}
goto object_field;
case '}': log_end_value("object"); SIMDJSON_TRY( visitor.visit_object_end(*this) ); goto scope_end;
default: log_error("No comma between object fields"); return TAPE_ERROR;
}
scope_end:
depth--;
if (depth == 0) { goto document_end; }
if (dom_parser.is_array[depth]) { goto array_continue; }
goto object_continue;
//
// Array parser states
//
array_begin:
log_start_value("array");
depth++;
if (depth >= dom_parser.max_depth()) { log_error("Exceeded max depth!"); return DEPTH_ERROR; }
dom_parser.is_array[depth] = true;
SIMDJSON_TRY( visitor.visit_array_start(*this) );
SIMDJSON_TRY( visitor.increment_count(*this) );
array_value:
{
auto value = advance();
switch (*value) {
case '{': if (*peek() == '}') { advance(); log_value("empty object"); SIMDJSON_TRY( visitor.visit_empty_object(*this) ); break; } goto object_begin;
case '[': if (*peek() == ']') { advance(); log_value("empty array"); SIMDJSON_TRY( visitor.visit_empty_array(*this) ); break; } goto array_begin;
default: SIMDJSON_TRY( visitor.visit_primitive(*this, value) ); break;
}
}
array_continue:
switch (*advance()) {
case ',': SIMDJSON_TRY( visitor.increment_count(*this) ); goto array_value;
case ']': log_end_value("array"); SIMDJSON_TRY( visitor.visit_array_end(*this) ); goto scope_end;
default: log_error("Missing comma between array values"); return TAPE_ERROR;
}
document_end:
log_end_value("document");
SIMDJSON_TRY( visitor.visit_document_end(*this) );
dom_parser.next_structural_index = uint32_t(next_structural - &dom_parser.structural_indexes[0]);
// If we didn't make it to the end, it's an error
if ( !STREAMING && dom_parser.next_structural_index != dom_parser.n_structural_indexes ) {
log_error("More than one JSON value at the root of the document, or extra characters at the end of the JSON!");
return TAPE_ERROR;
}
return SUCCESS;
} // walk_document()
simdjson_really_inline json_iterator::json_iterator(dom_parser_implementation &_dom_parser, size_t start_structural_index)
: buf{_dom_parser.buf},
next_structural{&_dom_parser.structural_indexes[start_structural_index]},
dom_parser{_dom_parser} {
}
simdjson_really_inline const uint8_t *json_iterator::peek() const noexcept {
return &buf[*(next_structural)];
}
simdjson_really_inline const uint8_t *json_iterator::advance() noexcept {
return &buf[*(next_structural++)];
}
simdjson_really_inline size_t json_iterator::remaining_len() const noexcept {
return dom_parser.len - *(next_structural-1);
}
simdjson_really_inline bool json_iterator::at_eof() const noexcept {
return next_structural == &dom_parser.structural_indexes[dom_parser.n_structural_indexes];
}
simdjson_really_inline bool json_iterator::at_beginning() const noexcept {
return next_structural == dom_parser.structural_indexes.get();
}
simdjson_really_inline uint8_t json_iterator::last_structural() const noexcept {
return buf[dom_parser.structural_indexes[dom_parser.n_structural_indexes - 1]];
}
simdjson_really_inline void json_iterator::log_value(const char *type) const noexcept {
logger::log_line(*this, "", type, "");
}
simdjson_really_inline void json_iterator::log_start_value(const char *type) const noexcept {
logger::log_line(*this, "+", type, "");
if (logger::LOG_ENABLED) { logger::log_depth++; }
}
simdjson_really_inline void json_iterator::log_end_value(const char *type) const noexcept {
if (logger::LOG_ENABLED) { logger::log_depth--; }
logger::log_line(*this, "-", type, "");
}
simdjson_really_inline void json_iterator::log_error(const char *error) const noexcept {
logger::log_line(*this, "", "ERROR", error);
}
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::visit_root_primitive(V &visitor, const uint8_t *value) noexcept {
switch (*value) {
case '"': return visitor.visit_root_string(*this, value);
case 't': return visitor.visit_root_true_atom(*this, value);
case 'f': return visitor.visit_root_false_atom(*this, value);
case 'n': return visitor.visit_root_null_atom(*this, value);
case '-':
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
return visitor.visit_root_number(*this, value);
default:
log_error("Document starts with a non-value character");
return TAPE_ERROR;
}
}
template<typename V>
simdjson_warn_unused simdjson_really_inline error_code json_iterator::visit_primitive(V &visitor, const uint8_t *value) noexcept {
switch (*value) {
case '"': return visitor.visit_string(*this, value);
case 't': return visitor.visit_true_atom(*this, value);
case 'f': return visitor.visit_false_atom(*this, value);
case 'n': return visitor.visit_null_atom(*this, value);
case '-':
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
return visitor.visit_number(*this, value);
default:
log_error("Non-value found when value was expected!");
return TAPE_ERROR;
}
}
} // namespace stage2
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* end file src/generic/stage2/json_iterator.h */
/* begin file src/generic/stage2/tape_writer.h */
namespace simdjson {
namespace westmere {
namespace {
namespace stage2 {
struct tape_writer {
/** The next place to write to tape */
uint64_t *next_tape_loc;
/** Write a signed 64-bit value to tape. */
simdjson_really_inline void append_s64(int64_t value) noexcept;
/** Write an unsigned 64-bit value to tape. */
simdjson_really_inline void append_u64(uint64_t value) noexcept;
/** Write a double value to tape. */
simdjson_really_inline void append_double(double value) noexcept;
/**
* Append a tape entry (an 8-bit type,and 56 bits worth of value).
*/
simdjson_really_inline void append(uint64_t val, internal::tape_type t) noexcept;
/**
* Skip the current tape entry without writing.
*
* Used to skip the start of the container, since we'll come back later to fill it in when the
* container ends.
*/
simdjson_really_inline void skip() noexcept;
/**
* Skip the number of tape entries necessary to write a large u64 or i64.
*/
simdjson_really_inline void skip_large_integer() noexcept;
/**
* Skip the number of tape entries necessary to write a double.
*/
simdjson_really_inline void skip_double() noexcept;
/**
* Write a value to a known location on tape.
*
* Used to go back and write out the start of a container after the container ends.
*/
simdjson_really_inline static void write(uint64_t &tape_loc, uint64_t val, internal::tape_type t) noexcept;
private:
/**
* Append both the tape entry, and a supplementary value following it. Used for types that need
* all 64 bits, such as double and uint64_t.
*/
template<typename T>
simdjson_really_inline void append2(uint64_t val, T val2, internal::tape_type t) noexcept;
}; // struct number_writer
simdjson_really_inline void tape_writer::append_s64(int64_t value) noexcept {
append2(0, value, internal::tape_type::INT64);
}
simdjson_really_inline void tape_writer::append_u64(uint64_t value) noexcept {
append(0, internal::tape_type::UINT64);
*next_tape_loc = value;
next_tape_loc++;
}
/** Write a double value to tape. */
simdjson_really_inline void tape_writer::append_double(double value) noexcept {
append2(0, value, internal::tape_type::DOUBLE);
}
simdjson_really_inline void tape_writer::skip() noexcept {
next_tape_loc++;
}
simdjson_really_inline void tape_writer::skip_large_integer() noexcept {
next_tape_loc += 2;
}
simdjson_really_inline void tape_writer::skip_double() noexcept {
next_tape_loc += 2;
}
simdjson_really_inline void tape_writer::append(uint64_t val, internal::tape_type t) noexcept {
*next_tape_loc = val | ((uint64_t(char(t))) << 56);
next_tape_loc++;
}
template<typename T>
simdjson_really_inline void tape_writer::append2(uint64_t val, T val2, internal::tape_type t) noexcept {
append(val, t);
static_assert(sizeof(val2) == sizeof(*next_tape_loc), "Type is not 64 bits!");
memcpy(next_tape_loc, &val2, sizeof(val2));
next_tape_loc++;
}
simdjson_really_inline void tape_writer::write(uint64_t &tape_loc, uint64_t val, internal::tape_type t) noexcept {
tape_loc = val | ((uint64_t(char(t))) << 56);
}
} // namespace stage2
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* end file src/generic/stage2/tape_writer.h */
namespace simdjson {
namespace westmere {
namespace {
namespace stage2 {
struct tape_builder {
template<bool STREAMING>
simdjson_warn_unused static simdjson_really_inline error_code parse_document(
dom_parser_implementation &dom_parser,
dom::document &doc) noexcept;
/** Called when a non-empty document starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_document_start(json_iterator &iter) noexcept;
/** Called when a non-empty document ends without error. */
simdjson_warn_unused simdjson_really_inline error_code visit_document_end(json_iterator &iter) noexcept;
/** Called when a non-empty array starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_array_start(json_iterator &iter) noexcept;
/** Called when a non-empty array ends. */
simdjson_warn_unused simdjson_really_inline error_code visit_array_end(json_iterator &iter) noexcept;
/** Called when an empty array is found. */
simdjson_warn_unused simdjson_really_inline error_code visit_empty_array(json_iterator &iter) noexcept;
/** Called when a non-empty object starts. */
simdjson_warn_unused simdjson_really_inline error_code visit_object_start(json_iterator &iter) noexcept;
/**
* Called when a key in a field is encountered.
*
* primitive, visit_object_start, visit_empty_object, visit_array_start, or visit_empty_array
* will be called after this with the field value.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_key(json_iterator &iter, const uint8_t *key) noexcept;
/** Called when a non-empty object ends. */
simdjson_warn_unused simdjson_really_inline error_code visit_object_end(json_iterator &iter) noexcept;
/** Called when an empty object is found. */
simdjson_warn_unused simdjson_really_inline error_code visit_empty_object(json_iterator &iter) noexcept;
/**
* Called when a string, number, boolean or null is found.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_primitive(json_iterator &iter, const uint8_t *value) noexcept;
/**
* Called when a string, number, boolean or null is found at the top level of a document (i.e.
* when there is no array or object and the entire document is a single string, number, boolean or
* null.
*
* This is separate from primitive() because simdjson's normal primitive parsing routines assume
* there is at least one more token after the value, which is only true in an array or object.
*/
simdjson_warn_unused simdjson_really_inline error_code visit_root_primitive(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_string(json_iterator &iter, const uint8_t *value, bool key = false) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_number(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_true_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_false_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_null_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_string(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_number(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_true_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_false_atom(json_iterator &iter, const uint8_t *value) noexcept;
simdjson_warn_unused simdjson_really_inline error_code visit_root_null_atom(json_iterator &iter, const uint8_t *value) noexcept;
/** Called each time a new field or element in an array or object is found. */
simdjson_warn_unused simdjson_really_inline error_code increment_count(json_iterator &iter) noexcept;
/** Next location to write to tape */
tape_writer tape;
private:
/** Next write location in the string buf for stage 2 parsing */
uint8_t *current_string_buf_loc;
simdjson_really_inline tape_builder(dom::document &doc) noexcept;
simdjson_really_inline uint32_t next_tape_index(json_iterator &iter) const noexcept;
simdjson_really_inline void start_container(json_iterator &iter) noexcept;
simdjson_warn_unused simdjson_really_inline error_code end_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept;
simdjson_warn_unused simdjson_really_inline error_code empty_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept;
simdjson_really_inline uint8_t *on_start_string(json_iterator &iter) noexcept;
simdjson_really_inline void on_end_string(uint8_t *dst) noexcept;
}; // class tape_builder
template<bool STREAMING>
simdjson_warn_unused simdjson_really_inline error_code tape_builder::parse_document(
dom_parser_implementation &dom_parser,
dom::document &doc) noexcept {
dom_parser.doc = &doc;
json_iterator iter(dom_parser, STREAMING ? dom_parser.next_structural_index : 0);
tape_builder builder(doc);
return iter.walk_document<STREAMING>(builder);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_primitive(json_iterator &iter, const uint8_t *value) noexcept {
return iter.visit_root_primitive(*this, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_primitive(json_iterator &iter, const uint8_t *value) noexcept {
return iter.visit_primitive(*this, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_empty_object(json_iterator &iter) noexcept {
return empty_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_empty_array(json_iterator &iter) noexcept {
return empty_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_document_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_object_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_array_start(json_iterator &iter) noexcept {
start_container(iter);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_object_end(json_iterator &iter) noexcept {
return end_container(iter, internal::tape_type::START_OBJECT, internal::tape_type::END_OBJECT);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_array_end(json_iterator &iter) noexcept {
return end_container(iter, internal::tape_type::START_ARRAY, internal::tape_type::END_ARRAY);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_document_end(json_iterator &iter) noexcept {
constexpr uint32_t start_tape_index = 0;
tape.append(start_tape_index, internal::tape_type::ROOT);
tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter), internal::tape_type::ROOT);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_key(json_iterator &iter, const uint8_t *key) noexcept {
return visit_string(iter, key, true);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::increment_count(json_iterator &iter) noexcept {
iter.dom_parser.open_containers[iter.depth].count++; // we have a key value pair in the object at parser.dom_parser.depth - 1
return SUCCESS;
}
simdjson_really_inline tape_builder::tape_builder(dom::document &doc) noexcept : tape{doc.tape.get()}, current_string_buf_loc{doc.string_buf.get()} {}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_string(json_iterator &iter, const uint8_t *value, bool key) noexcept {
iter.log_value(key ? "key" : "string");
uint8_t *dst = on_start_string(iter);
dst = stringparsing::parse_string(value+1, dst);
if (dst == nullptr) {
iter.log_error("Invalid escape in string");
return STRING_ERROR;
}
on_end_string(dst);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_string(json_iterator &iter, const uint8_t *value) noexcept {
return visit_string(iter, value);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_number(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("number");
return numberparsing::parse_number(value, tape);
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_number(json_iterator &iter, const uint8_t *value) noexcept {
//
// We need to make a copy to make sure that the string is space terminated.
// This is not about padding the input, which should already padded up
// to len + SIMDJSON_PADDING. However, we have no control at this stage
// on how the padding was done. What if the input string was padded with nulls?
// It is quite common for an input string to have an extra null character (C string).
// We do not want to allow 9\0 (where \0 is the null character) inside a JSON
// document, but the string "9\0" by itself is fine. So we make a copy and
// pad the input with spaces when we know that there is just one input element.
// This copy is relatively expensive, but it will almost never be called in
// practice unless you are in the strange scenario where you have many JSON
// documents made of single atoms.
//
uint8_t *copy = static_cast<uint8_t *>(malloc(iter.remaining_len() + SIMDJSON_PADDING));
if (copy == nullptr) { return MEMALLOC; }
std::memcpy(copy, value, iter.remaining_len());
std::memset(copy + iter.remaining_len(), ' ', SIMDJSON_PADDING);
error_code error = visit_number(iter, copy);
free(copy);
return error;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_true_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("true");
if (!atomparsing::is_valid_true_atom(value)) { return T_ATOM_ERROR; }
tape.append(0, internal::tape_type::TRUE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_true_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("true");
if (!atomparsing::is_valid_true_atom(value, iter.remaining_len())) { return T_ATOM_ERROR; }
tape.append(0, internal::tape_type::TRUE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_false_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("false");
if (!atomparsing::is_valid_false_atom(value)) { return F_ATOM_ERROR; }
tape.append(0, internal::tape_type::FALSE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_false_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("false");
if (!atomparsing::is_valid_false_atom(value, iter.remaining_len())) { return F_ATOM_ERROR; }
tape.append(0, internal::tape_type::FALSE_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_null_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("null");
if (!atomparsing::is_valid_null_atom(value)) { return N_ATOM_ERROR; }
tape.append(0, internal::tape_type::NULL_VALUE);
return SUCCESS;
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::visit_root_null_atom(json_iterator &iter, const uint8_t *value) noexcept {
iter.log_value("null");
if (!atomparsing::is_valid_null_atom(value, iter.remaining_len())) { return N_ATOM_ERROR; }
tape.append(0, internal::tape_type::NULL_VALUE);
return SUCCESS;
}
// private:
simdjson_really_inline uint32_t tape_builder::next_tape_index(json_iterator &iter) const noexcept {
return uint32_t(tape.next_tape_loc - iter.dom_parser.doc->tape.get());
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::empty_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept {
auto start_index = next_tape_index(iter);
tape.append(start_index+2, start);
tape.append(start_index, end);
return SUCCESS;
}
simdjson_really_inline void tape_builder::start_container(json_iterator &iter) noexcept {
iter.dom_parser.open_containers[iter.depth].tape_index = next_tape_index(iter);
iter.dom_parser.open_containers[iter.depth].count = 0;
tape.skip(); // We don't actually *write* the start element until the end.
}
simdjson_warn_unused simdjson_really_inline error_code tape_builder::end_container(json_iterator &iter, internal::tape_type start, internal::tape_type end) noexcept {
// Write the ending tape element, pointing at the start location
const uint32_t start_tape_index = iter.dom_parser.open_containers[iter.depth].tape_index;
tape.append(start_tape_index, end);
// Write the start tape element, pointing at the end location (and including count)
// count can overflow if it exceeds 24 bits... so we saturate
// the convention being that a cnt of 0xffffff or more is undetermined in value (>= 0xffffff).
const uint32_t count = iter.dom_parser.open_containers[iter.depth].count;
const uint32_t cntsat = count > 0xFFFFFF ? 0xFFFFFF : count;
tape_writer::write(iter.dom_parser.doc->tape[start_tape_index], next_tape_index(iter) | (uint64_t(cntsat) << 32), start);
return SUCCESS;
}
simdjson_really_inline uint8_t *tape_builder::on_start_string(json_iterator &iter) noexcept {
// we advance the point, accounting for the fact that we have a NULL termination
tape.append(current_string_buf_loc - iter.dom_parser.doc->string_buf.get(), internal::tape_type::STRING);
return current_string_buf_loc + sizeof(uint32_t);
}
simdjson_really_inline void tape_builder::on_end_string(uint8_t *dst) noexcept {
uint32_t str_length = uint32_t(dst - (current_string_buf_loc + sizeof(uint32_t)));
// TODO check for overflow in case someone has a crazy string (>=4GB?)
// But only add the overflow check when the document itself exceeds 4GB
// Currently unneeded because we refuse to parse docs larger or equal to 4GB.
memcpy(current_string_buf_loc, &str_length, sizeof(uint32_t));
// NULL termination is still handy if you expect all your strings to
// be NULL terminated? It comes at a small cost
*dst = 0;
current_string_buf_loc = dst + 1;
}
} // namespace stage2
} // unnamed namespace
} // namespace westmere
} // namespace simdjson
/* end file src/generic/stage2/tape_builder.h */
//
// Implementation-specific overrides
//
namespace simdjson {
namespace westmere {
namespace {
namespace stage1 {
simdjson_really_inline uint64_t json_string_scanner::find_escaped(uint64_t backslash) {
if (!backslash) { uint64_t escaped = prev_escaped; prev_escaped = 0; return escaped; }
return find_escaped_branchless(backslash);
}
} // namespace stage1
} // unnamed namespace
simdjson_warn_unused error_code implementation::minify(const uint8_t *buf, size_t len, uint8_t *dst, size_t &dst_len) const noexcept {
return westmere::stage1::json_minifier::minify<64>(buf, len, dst, dst_len);
}
simdjson_warn_unused error_code dom_parser_implementation::stage1(const uint8_t *_buf, size_t _len, bool streaming) noexcept {
this->buf = _buf;
this->len = _len;
return westmere::stage1::json_structural_indexer::index<64>(_buf, _len, *this, streaming);
}
simdjson_warn_unused bool implementation::validate_utf8(const char *buf, size_t len) const noexcept {
return westmere::stage1::generic_validate_utf8(buf,len);
}
simdjson_warn_unused error_code dom_parser_implementation::stage2(dom::document &_doc) noexcept {
return stage2::tape_builder::parse_document<false>(*this, _doc);
}
simdjson_warn_unused error_code dom_parser_implementation::stage2_next(dom::document &_doc) noexcept {
return stage2::tape_builder::parse_document<true>(*this, _doc);
}
simdjson_warn_unused error_code dom_parser_implementation::parse(const uint8_t *_buf, size_t _len, dom::document &_doc) noexcept {
auto error = stage1(_buf, _len, false);
if (error) { return error; }
return stage2(_doc);
}
} // namespace westmere
} // namespace simdjson
/* begin file include/simdjson/westmere/end.h */
SIMDJSON_UNTARGET_REGION
#undef westmere
/* end file include/simdjson/westmere/end.h */
/* end file src/westmere/dom_parser_implementation.cpp */
#endif
SIMDJSON_POP_DISABLE_WARNINGS
/* end file src/simdjson.cpp */
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