// Copyright 2017 PDFium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // Original code copyright 2014 Foxit Software Inc. http://www.foxitsoftware.com #include "core/fxcrt/cfx_decimal.h" #include #include #include "core/fxcrt/fx_extension.h" #define FXMATH_DECIMAL_SCALELIMIT 0x1c #define FXMATH_DECIMAL_NEGMASK (0x80000000L) #define FXMATH_DECIMAL_FORCEBOOL(x) (!!(x)) #define FXMATH_DECIMAL_MAKEFLAGS(NEG, SCALE) \ (((SCALE) << 0x10) | ((NEG) ? FXMATH_DECIMAL_NEGMASK : 0)) #define FXMATH_DECIMAL_FLAGS2NEG(FLAGS) \ FXMATH_DECIMAL_FORCEBOOL((FLAGS)&FXMATH_DECIMAL_NEGMASK) #define FXMATH_DECIMAL_FLAGS2SCALE(FLAGS) \ ((uint8_t)(((FLAGS) & ~FXMATH_DECIMAL_NEGMASK) >> 0x10)) #define FXMATH_DECIMAL_RSHIFT32BIT(x) ((x) >> 0x10 >> 0x10) #define FXMATH_DECIMAL_LSHIFT32BIT(x) ((x) << 0x10 << 0x10) namespace { inline uint8_t decimal_helper_div10(uint64_t& phi, uint64_t& pmid, uint64_t& plo) { uint8_t retVal; pmid += FXMATH_DECIMAL_LSHIFT32BIT(phi % 0xA); phi /= 0xA; plo += FXMATH_DECIMAL_LSHIFT32BIT(pmid % 0xA); pmid /= 0xA; retVal = plo % 0xA; plo /= 0xA; return retVal; } inline uint8_t decimal_helper_div10_any(uint64_t nums[], uint8_t numcount) { uint8_t retVal = 0; for (int i = numcount - 1; i > 0; i--) { nums[i - 1] += FXMATH_DECIMAL_LSHIFT32BIT(nums[i] % 0xA); nums[i] /= 0xA; } if (numcount) { retVal = nums[0] % 0xA; nums[0] /= 0xA; } return retVal; } inline void decimal_helper_mul10(uint64_t& phi, uint64_t& pmid, uint64_t& plo) { plo *= 0xA; pmid = pmid * 0xA + FXMATH_DECIMAL_RSHIFT32BIT(plo); plo = (uint32_t)plo; phi = phi * 0xA + FXMATH_DECIMAL_RSHIFT32BIT(pmid); pmid = (uint32_t)pmid; } inline void decimal_helper_mul10_any(uint64_t nums[], uint8_t numcount) { nums[0] *= 0xA; for (int i = 1; i < numcount; i++) { nums[i] = nums[i] * 0xA + FXMATH_DECIMAL_RSHIFT32BIT(nums[i - 1]); nums[i - 1] = (uint32_t)nums[i - 1]; } } inline void decimal_helper_normalize(uint64_t& phi, uint64_t& pmid, uint64_t& plo) { phi += FXMATH_DECIMAL_RSHIFT32BIT(pmid); pmid = (uint32_t)pmid; pmid += FXMATH_DECIMAL_RSHIFT32BIT(plo); plo = (uint32_t)plo; phi += FXMATH_DECIMAL_RSHIFT32BIT(pmid); pmid = (uint32_t)pmid; } inline void decimal_helper_normalize_any(uint64_t nums[], uint8_t len) { for (int i = len - 2; i > 0; i--) { nums[i + 1] += FXMATH_DECIMAL_RSHIFT32BIT(nums[i]); nums[i] = (uint32_t)nums[i]; } for (int i = 0; i < len - 1; i++) { nums[i + 1] += FXMATH_DECIMAL_RSHIFT32BIT(nums[i]); nums[i] = (uint32_t)nums[i]; } } inline int8_t decimal_helper_raw_compare_any(uint64_t a[], uint8_t al, uint64_t b[], uint8_t bl) { int8_t retVal = 0; for (int i = std::max(al - 1, bl - 1); i >= 0; i--) { uint64_t l = (i >= al ? 0 : a[i]), r = (i >= bl ? 0 : b[i]); retVal += (l > r ? 1 : (l < r ? -1 : 0)); if (retVal) return retVal; } return retVal; } inline void decimal_helper_dec_any(uint64_t a[], uint8_t al) { for (int i = 0; i < al; i++) { if (a[i]--) return; } } inline void decimal_helper_inc_any(uint64_t a[], uint8_t al) { for (int i = 0; i < al; i++) { a[i]++; if ((uint32_t)a[i] == a[i]) return; a[i] = 0; } } inline void decimal_helper_raw_mul(uint64_t a[], uint8_t al, uint64_t b[], uint8_t bl, uint64_t c[], uint8_t cl) { ASSERT(al + bl <= cl); for (int i = 0; i < cl; i++) c[i] = 0; for (int i = 0; i < al; i++) { for (int j = 0; j < bl; j++) { uint64_t m = (uint64_t)a[i] * b[j]; c[i + j] += (uint32_t)m; c[i + j + 1] += FXMATH_DECIMAL_RSHIFT32BIT(m); } } for (int i = 0; i < cl - 1; i++) { c[i + 1] += FXMATH_DECIMAL_RSHIFT32BIT(c[i]); c[i] = (uint32_t)c[i]; } for (int i = 0; i < cl; i++) c[i] = (uint32_t)c[i]; } inline void decimal_helper_raw_div(uint64_t a[], uint8_t al, uint64_t b[], uint8_t bl, uint64_t c[], uint8_t cl) { for (int i = 0; i < cl; i++) c[i] = 0; uint64_t left[16] = {0}; uint64_t right[16] = {0}; left[0] = 0; for (int i = 0; i < al; i++) right[i] = a[i]; uint64_t tmp[16]; while (decimal_helper_raw_compare_any(left, al, right, al) <= 0) { uint64_t cur[16]; for (int i = 0; i < al; i++) cur[i] = left[i] + right[i]; for (int i = al - 1; i >= 0; i--) { if (i) cur[i - 1] += FXMATH_DECIMAL_LSHIFT32BIT(cur[i] % 2); cur[i] /= 2; } decimal_helper_raw_mul(cur, al, b, bl, tmp, 16); switch (decimal_helper_raw_compare_any(tmp, 16, a, al)) { case -1: for (int i = 0; i < 16; i++) left[i] = cur[i]; left[0]++; decimal_helper_normalize_any(left, al); break; case 1: for (int i = 0; i < 16; i++) right[i] = cur[i]; decimal_helper_dec_any(right, al); break; case 0: for (int i = 0; i < std::min(al, cl); i++) c[i] = cur[i]; return; } } for (int i = 0; i < std::min(al, cl); i++) c[i] = left[i]; } inline bool decimal_helper_outofrange(uint64_t a[], uint8_t al, uint8_t goal) { for (int i = goal; i < al; i++) { if (a[i]) return true; } return false; } inline void decimal_helper_shrinkintorange(uint64_t a[], uint8_t al, uint8_t goal, uint8_t& scale) { bool bRoundUp = false; while (scale != 0 && (scale > FXMATH_DECIMAL_SCALELIMIT || decimal_helper_outofrange(a, al, goal))) { bRoundUp = decimal_helper_div10_any(a, al) >= 5; scale--; } if (bRoundUp) { decimal_helper_normalize_any(a, goal); decimal_helper_inc_any(a, goal); } } inline void decimal_helper_truncate(uint64_t& phi, uint64_t& pmid, uint64_t& plo, uint8_t& scale, uint8_t minscale = 0) { while (scale > minscale) { uint64_t thi = phi, tmid = pmid, tlo = plo; if (decimal_helper_div10(thi, tmid, tlo) != 0) break; phi = thi; pmid = tmid; plo = tlo; scale--; } } } // namespace CFX_Decimal::CFX_Decimal() : m_uHi(0), m_uLo(0), m_uMid(0), m_uFlags(0) {} CFX_Decimal::CFX_Decimal(uint64_t val) : m_uHi(0), m_uLo(static_cast(val)), m_uMid(static_cast(FXMATH_DECIMAL_RSHIFT32BIT(val))), m_uFlags(0) {} CFX_Decimal::CFX_Decimal(uint32_t val) : m_uHi(0), m_uLo(static_cast(val)), m_uMid(0), m_uFlags(0) {} CFX_Decimal::CFX_Decimal(uint32_t lo, uint32_t mid, uint32_t hi, bool neg, uint8_t scale) : m_uHi(hi), m_uLo(lo), m_uMid(mid), m_uFlags(FXMATH_DECIMAL_MAKEFLAGS( neg && IsNotZero(), (scale > FXMATH_DECIMAL_SCALELIMIT ? 0 : scale))) {} CFX_Decimal::CFX_Decimal(int32_t val) { if (val >= 0) { *this = CFX_Decimal(static_cast(val)); } else { *this = CFX_Decimal(static_cast(-val)); SetNegate(); } } CFX_Decimal::CFX_Decimal(float val, uint8_t scale) { float newval = fabs(val); uint64_t phi; uint64_t pmid; uint64_t plo; plo = static_cast(newval); pmid = static_cast(newval / 1e32); phi = static_cast(newval / 1e64); newval = fmod(newval, 1.0f); for (uint8_t iter = 0; iter < scale; iter++) { decimal_helper_mul10(phi, pmid, plo); newval *= 10; plo += static_cast(newval); newval = fmod(newval, 1.0f); } plo += FXSYS_round(newval); decimal_helper_normalize(phi, pmid, plo); m_uHi = static_cast(phi); m_uMid = static_cast(pmid); m_uLo = static_cast(plo); m_uFlags = FXMATH_DECIMAL_MAKEFLAGS(val < 0 && IsNotZero(), scale); } CFX_Decimal::CFX_Decimal(const WideStringView& strObj) { const wchar_t* str = strObj.unterminated_c_str(); const wchar_t* strBound = str + strObj.GetLength(); bool pointmet = false; bool negmet = false; uint8_t scale = 0; m_uHi = 0; m_uMid = 0; m_uLo = 0; while (str != strBound && *str == ' ') str++; if (str != strBound && *str == '-') { negmet = 1; str++; } else if (str != strBound && *str == '+') { str++; } while (str != strBound && (std::iswdigit(*str) || *str == '.') && scale < FXMATH_DECIMAL_SCALELIMIT) { if (*str == '.') { if (!pointmet) pointmet = 1; } else { m_uHi = m_uHi * 0xA + FXMATH_DECIMAL_RSHIFT32BIT((uint64_t)m_uMid * 0xA); m_uMid = m_uMid * 0xA + FXMATH_DECIMAL_RSHIFT32BIT((uint64_t)m_uLo * 0xA); m_uLo = m_uLo * 0xA + (*str - '0'); if (pointmet) scale++; } str++; } m_uFlags = FXMATH_DECIMAL_MAKEFLAGS(negmet && IsNotZero(), scale); } CFX_Decimal::operator WideString() const { WideString retString; WideString tmpbuf; uint64_t phi = m_uHi; uint64_t pmid = m_uMid; uint64_t plo = m_uLo; while (phi || pmid || plo) tmpbuf += decimal_helper_div10(phi, pmid, plo) + '0'; uint8_t outputlen = (uint8_t)tmpbuf.GetLength(); uint8_t scale = (uint8_t)FXMATH_DECIMAL_FLAGS2SCALE(m_uFlags); while (scale >= outputlen) { tmpbuf += '0'; outputlen++; } if (FXMATH_DECIMAL_FLAGS2NEG(m_uFlags) && IsNotZero()) retString += '-'; for (uint8_t idx = 0; idx < outputlen; idx++) { if (idx == (outputlen - scale) && scale != 0) retString += '.'; retString += tmpbuf[outputlen - 1 - idx]; } return retString; } CFX_Decimal::operator double() const { double pow = (double)(1 << 16) * (1 << 16); double base = static_cast(m_uHi) * pow * pow + static_cast(m_uMid) * pow + static_cast(m_uLo); int8_t scale = FXMATH_DECIMAL_FLAGS2SCALE(m_uFlags); bool bNeg = FXMATH_DECIMAL_FLAGS2NEG(m_uFlags); return (bNeg ? -1 : 1) * base * ::pow(10.0, -scale); } void CFX_Decimal::SetScale(uint8_t newscale) { uint8_t oldscale = FXMATH_DECIMAL_FLAGS2SCALE(m_uFlags); if (newscale > oldscale) { uint64_t phi = m_uHi; uint64_t pmid = m_uMid; uint64_t plo = m_uLo; for (uint8_t iter = 0; iter < newscale - oldscale; iter++) decimal_helper_mul10(phi, pmid, plo); m_uHi = static_cast(phi); m_uMid = static_cast(pmid); m_uLo = static_cast(plo); m_uFlags = FXMATH_DECIMAL_MAKEFLAGS( FXMATH_DECIMAL_FLAGS2NEG(m_uFlags) && IsNotZero(), newscale); } else if (newscale < oldscale) { uint64_t phi; uint64_t pmid; uint64_t plo; phi = 0; pmid = 0; plo = 5; for (uint8_t iter = 0; iter < oldscale - newscale - 1; iter++) decimal_helper_mul10(phi, pmid, plo); phi += m_uHi; pmid += m_uMid; plo += m_uLo; decimal_helper_normalize(phi, pmid, plo); for (uint8_t iter = 0; iter < oldscale - newscale; iter++) decimal_helper_div10(phi, pmid, plo); m_uHi = static_cast(phi); m_uMid = static_cast(pmid); m_uLo = static_cast(plo); m_uFlags = FXMATH_DECIMAL_MAKEFLAGS( FXMATH_DECIMAL_FLAGS2NEG(m_uFlags) && IsNotZero(), newscale); } } uint8_t CFX_Decimal::GetScale() { return FXMATH_DECIMAL_FLAGS2SCALE(m_uFlags); } void CFX_Decimal::SetNegate() { if (IsNotZero()) m_uFlags ^= FXMATH_DECIMAL_NEGMASK; } void CFX_Decimal::Swap(CFX_Decimal& val) { std::swap(m_uHi, val.m_uHi); std::swap(m_uMid, val.m_uMid); std::swap(m_uLo, val.m_uLo); std::swap(m_uFlags, val.m_uFlags); } CFX_Decimal CFX_Decimal::operator*(const CFX_Decimal& val) const { uint64_t a[3] = {m_uLo, m_uMid, m_uHi}, b[3] = {val.m_uLo, val.m_uMid, val.m_uHi}; uint64_t c[6]; decimal_helper_raw_mul(a, 3, b, 3, c, 6); bool neg = FXMATH_DECIMAL_FLAGS2NEG(m_uFlags) ^ FXMATH_DECIMAL_FLAGS2NEG(val.m_uFlags); uint8_t scale = FXMATH_DECIMAL_FLAGS2SCALE(m_uFlags) + FXMATH_DECIMAL_FLAGS2SCALE(val.m_uFlags); decimal_helper_shrinkintorange(c, 6, 3, scale); return CFX_Decimal(static_cast(c[0]), static_cast(c[1]), static_cast(c[2]), neg, scale); } CFX_Decimal CFX_Decimal::operator/(const CFX_Decimal& val) const { if (!val.IsNotZero()) return CFX_Decimal(); bool neg = FXMATH_DECIMAL_FLAGS2NEG(m_uFlags) ^ FXMATH_DECIMAL_FLAGS2NEG(val.m_uFlags); uint64_t a[7] = {m_uLo, m_uMid, m_uHi}, b[3] = {val.m_uLo, val.m_uMid, val.m_uHi}, c[7] = {0}; uint8_t scale = 0; if (FXMATH_DECIMAL_FLAGS2SCALE(m_uFlags) < FXMATH_DECIMAL_FLAGS2SCALE(val.m_uFlags)) { for (int i = FXMATH_DECIMAL_FLAGS2SCALE(val.m_uFlags) - FXMATH_DECIMAL_FLAGS2SCALE(m_uFlags); i > 0; i--) { decimal_helper_mul10_any(a, 7); } } else { scale = FXMATH_DECIMAL_FLAGS2SCALE(m_uFlags) - FXMATH_DECIMAL_FLAGS2SCALE(val.m_uFlags); } uint8_t minscale = scale; if (!IsNotZero()) return CFX_Decimal(0, 0, 0, 0, minscale); while (!a[6]) { decimal_helper_mul10_any(a, 7); scale++; } decimal_helper_div10_any(a, 7); scale--; decimal_helper_raw_div(a, 6, b, 3, c, 7); decimal_helper_shrinkintorange(c, 6, 3, scale); decimal_helper_truncate(c[2], c[1], c[0], scale, minscale); return CFX_Decimal(static_cast(c[0]), static_cast(c[1]), static_cast(c[2]), neg, scale); }