// Copyright 2006-2008 the V8 project authors. All rights reserved. // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following // disclaimer in the documentation and/or other materials provided // with the distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived // from this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. #include #include "src/base/numbers/bignum.h" #include "src/base/numbers/diy-fp.h" #include "src/base/numbers/double.h" #include "src/base/numbers/strtod.h" #include "src/base/utils/random-number-generator.h" #include "src/init/v8.h" #include "test/cctest/cctest.h" namespace v8 { namespace base { namespace test_strtod { static double StrtodChar(const char* str, int exponent) { return Strtod(CStrVector(str), exponent); } TEST(Strtod) { Vector vector; vector = CStrVector("0"); CHECK_EQ(0.0, Strtod(vector, 1)); CHECK_EQ(0.0, Strtod(vector, 2)); CHECK_EQ(0.0, Strtod(vector, -2)); CHECK_EQ(0.0, Strtod(vector, -999)); CHECK_EQ(0.0, Strtod(vector, +999)); vector = CStrVector("1"); CHECK_EQ(1.0, Strtod(vector, 0)); CHECK_EQ(10.0, Strtod(vector, 1)); CHECK_EQ(100.0, Strtod(vector, 2)); CHECK_EQ(1e20, Strtod(vector, 20)); CHECK_EQ(1e22, Strtod(vector, 22)); CHECK_EQ(1e23, Strtod(vector, 23)); CHECK_EQ(1e35, Strtod(vector, 35)); CHECK_EQ(1e36, Strtod(vector, 36)); CHECK_EQ(1e37, Strtod(vector, 37)); CHECK_EQ(1e-1, Strtod(vector, -1)); CHECK_EQ(1e-2, Strtod(vector, -2)); CHECK_EQ(1e-5, Strtod(vector, -5)); CHECK_EQ(1e-20, Strtod(vector, -20)); CHECK_EQ(1e-22, Strtod(vector, -22)); CHECK_EQ(1e-23, Strtod(vector, -23)); CHECK_EQ(1e-25, Strtod(vector, -25)); CHECK_EQ(1e-39, Strtod(vector, -39)); vector = CStrVector("2"); CHECK_EQ(2.0, Strtod(vector, 0)); CHECK_EQ(20.0, Strtod(vector, 1)); CHECK_EQ(200.0, Strtod(vector, 2)); CHECK_EQ(2e20, Strtod(vector, 20)); CHECK_EQ(2e22, Strtod(vector, 22)); CHECK_EQ(2e23, Strtod(vector, 23)); CHECK_EQ(2e35, Strtod(vector, 35)); CHECK_EQ(2e36, Strtod(vector, 36)); CHECK_EQ(2e37, Strtod(vector, 37)); CHECK_EQ(2e-1, Strtod(vector, -1)); CHECK_EQ(2e-2, Strtod(vector, -2)); CHECK_EQ(2e-5, Strtod(vector, -5)); CHECK_EQ(2e-20, Strtod(vector, -20)); CHECK_EQ(2e-22, Strtod(vector, -22)); CHECK_EQ(2e-23, Strtod(vector, -23)); CHECK_EQ(2e-25, Strtod(vector, -25)); CHECK_EQ(2e-39, Strtod(vector, -39)); vector = CStrVector("9"); CHECK_EQ(9.0, Strtod(vector, 0)); CHECK_EQ(90.0, Strtod(vector, 1)); CHECK_EQ(900.0, Strtod(vector, 2)); CHECK_EQ(9e20, Strtod(vector, 20)); CHECK_EQ(9e22, Strtod(vector, 22)); CHECK_EQ(9e23, Strtod(vector, 23)); CHECK_EQ(9e35, Strtod(vector, 35)); CHECK_EQ(9e36, Strtod(vector, 36)); CHECK_EQ(9e37, Strtod(vector, 37)); CHECK_EQ(9e-1, Strtod(vector, -1)); CHECK_EQ(9e-2, Strtod(vector, -2)); CHECK_EQ(9e-5, Strtod(vector, -5)); CHECK_EQ(9e-20, Strtod(vector, -20)); CHECK_EQ(9e-22, Strtod(vector, -22)); CHECK_EQ(9e-23, Strtod(vector, -23)); CHECK_EQ(9e-25, Strtod(vector, -25)); CHECK_EQ(9e-39, Strtod(vector, -39)); vector = CStrVector("12345"); CHECK_EQ(12345.0, Strtod(vector, 0)); CHECK_EQ(123450.0, Strtod(vector, 1)); CHECK_EQ(1234500.0, Strtod(vector, 2)); CHECK_EQ(12345e20, Strtod(vector, 20)); CHECK_EQ(12345e22, Strtod(vector, 22)); CHECK_EQ(12345e23, Strtod(vector, 23)); CHECK_EQ(12345e30, Strtod(vector, 30)); CHECK_EQ(12345e31, Strtod(vector, 31)); CHECK_EQ(12345e32, Strtod(vector, 32)); CHECK_EQ(12345e35, Strtod(vector, 35)); CHECK_EQ(12345e36, Strtod(vector, 36)); CHECK_EQ(12345e37, Strtod(vector, 37)); CHECK_EQ(12345e-1, Strtod(vector, -1)); CHECK_EQ(12345e-2, Strtod(vector, -2)); CHECK_EQ(12345e-5, Strtod(vector, -5)); CHECK_EQ(12345e-20, Strtod(vector, -20)); CHECK_EQ(12345e-22, Strtod(vector, -22)); CHECK_EQ(12345e-23, Strtod(vector, -23)); CHECK_EQ(12345e-25, Strtod(vector, -25)); CHECK_EQ(12345e-39, Strtod(vector, -39)); vector = CStrVector("12345678901234"); CHECK_EQ(12345678901234.0, Strtod(vector, 0)); CHECK_EQ(123456789012340.0, Strtod(vector, 1)); CHECK_EQ(1234567890123400.0, Strtod(vector, 2)); CHECK_EQ(12345678901234e20, Strtod(vector, 20)); CHECK_EQ(12345678901234e22, Strtod(vector, 22)); CHECK_EQ(12345678901234e23, Strtod(vector, 23)); CHECK_EQ(12345678901234e30, Strtod(vector, 30)); CHECK_EQ(12345678901234e31, Strtod(vector, 31)); CHECK_EQ(12345678901234e32, Strtod(vector, 32)); CHECK_EQ(12345678901234e35, Strtod(vector, 35)); CHECK_EQ(12345678901234e36, Strtod(vector, 36)); CHECK_EQ(12345678901234e37, Strtod(vector, 37)); CHECK_EQ(12345678901234e-1, Strtod(vector, -1)); CHECK_EQ(12345678901234e-2, Strtod(vector, -2)); CHECK_EQ(12345678901234e-5, Strtod(vector, -5)); CHECK_EQ(12345678901234e-20, Strtod(vector, -20)); CHECK_EQ(12345678901234e-22, Strtod(vector, -22)); CHECK_EQ(12345678901234e-23, Strtod(vector, -23)); CHECK_EQ(12345678901234e-25, Strtod(vector, -25)); CHECK_EQ(12345678901234e-39, Strtod(vector, -39)); vector = CStrVector("123456789012345"); CHECK_EQ(123456789012345.0, Strtod(vector, 0)); CHECK_EQ(1234567890123450.0, Strtod(vector, 1)); CHECK_EQ(12345678901234500.0, Strtod(vector, 2)); CHECK_EQ(123456789012345e20, Strtod(vector, 20)); CHECK_EQ(123456789012345e22, Strtod(vector, 22)); CHECK_EQ(123456789012345e23, Strtod(vector, 23)); CHECK_EQ(123456789012345e35, Strtod(vector, 35)); CHECK_EQ(123456789012345e36, Strtod(vector, 36)); CHECK_EQ(123456789012345e37, Strtod(vector, 37)); CHECK_EQ(123456789012345e39, Strtod(vector, 39)); CHECK_EQ(123456789012345e-1, Strtod(vector, -1)); CHECK_EQ(123456789012345e-2, Strtod(vector, -2)); CHECK_EQ(123456789012345e-5, Strtod(vector, -5)); CHECK_EQ(123456789012345e-20, Strtod(vector, -20)); CHECK_EQ(123456789012345e-22, Strtod(vector, -22)); CHECK_EQ(123456789012345e-23, Strtod(vector, -23)); CHECK_EQ(123456789012345e-25, Strtod(vector, -25)); CHECK_EQ(123456789012345e-39, Strtod(vector, -39)); CHECK_EQ(0.0, StrtodChar("0", 12345)); CHECK_EQ(0.0, StrtodChar("", 1324)); CHECK_EQ(0.0, StrtodChar("000000000", 123)); CHECK_EQ(0.0, StrtodChar("2", -324)); CHECK_EQ(4e-324, StrtodChar("3", -324)); // It would be more readable to put non-zero literals on the left side (i.e. // CHECK_EQ(1e-325, StrtodChar("1", -325))), but then Gcc complains that // they are truncated to zero. CHECK_EQ(0.0, StrtodChar("1", -325)); CHECK_EQ(0.0, StrtodChar("1", -325)); CHECK_EQ(0.0, StrtodChar("20000", -328)); CHECK_EQ(40000e-328, StrtodChar("30000", -328)); CHECK_EQ(0.0, StrtodChar("10000", -329)); CHECK_EQ(0.0, StrtodChar("90000", -329)); CHECK_EQ(0.0, StrtodChar("000000001", -325)); CHECK_EQ(0.0, StrtodChar("000000001", -325)); CHECK_EQ(0.0, StrtodChar("0000000020000", -328)); CHECK_EQ(40000e-328, StrtodChar("00000030000", -328)); CHECK_EQ(0.0, StrtodChar("0000000010000", -329)); CHECK_EQ(0.0, StrtodChar("0000000090000", -329)); // It would be more readable to put the literals (and not V8_INFINITY) on the // left side (i.e. CHECK_EQ(1e309, StrtodChar("1", 309))), but then Gcc // complains that the floating constant exceeds range of 'double'. CHECK_EQ(V8_INFINITY, StrtodChar("1", 309)); CHECK_EQ(1e308, StrtodChar("1", 308)); CHECK_EQ(1234e305, StrtodChar("1234", 305)); CHECK_EQ(1234e304, StrtodChar("1234", 304)); CHECK_EQ(V8_INFINITY, StrtodChar("18", 307)); CHECK_EQ(17e307, StrtodChar("17", 307)); CHECK_EQ(V8_INFINITY, StrtodChar("0000001", 309)); CHECK_EQ(1e308, StrtodChar("00000001", 308)); CHECK_EQ(1234e305, StrtodChar("00000001234", 305)); CHECK_EQ(1234e304, StrtodChar("000000001234", 304)); CHECK_EQ(V8_INFINITY, StrtodChar("0000000018", 307)); CHECK_EQ(17e307, StrtodChar("0000000017", 307)); CHECK_EQ(V8_INFINITY, StrtodChar("1000000", 303)); CHECK_EQ(1e308, StrtodChar("100000", 303)); CHECK_EQ(1234e305, StrtodChar("123400000", 300)); CHECK_EQ(1234e304, StrtodChar("123400000", 299)); CHECK_EQ(V8_INFINITY, StrtodChar("180000000", 300)); CHECK_EQ(17e307, StrtodChar("170000000", 300)); CHECK_EQ(V8_INFINITY, StrtodChar("00000001000000", 303)); CHECK_EQ(1e308, StrtodChar("000000000000100000", 303)); CHECK_EQ(1234e305, StrtodChar("00000000123400000", 300)); CHECK_EQ(1234e304, StrtodChar("0000000123400000", 299)); CHECK_EQ(V8_INFINITY, StrtodChar("00000000180000000", 300)); CHECK_EQ(17e307, StrtodChar("00000000170000000", 300)); CHECK_EQ(1.7976931348623157E+308, StrtodChar("17976931348623157", 292)); CHECK_EQ(1.7976931348623158E+308, StrtodChar("17976931348623158", 292)); CHECK_EQ(V8_INFINITY, StrtodChar("17976931348623159", 292)); // The following number is the result of 89255.0/1e22. Both floating-point // numbers can be accurately represented with doubles. However on Linux,x86 // the floating-point stack is set to 80bits and the double-rounding // introduces an error. CHECK_EQ(89255e-22, StrtodChar("89255", -22)); // Some random values. CHECK_EQ(358416272e-33, StrtodChar("358416272", -33)); CHECK_EQ(104110013277974872254e-225, StrtodChar("104110013277974872254", -225)); CHECK_EQ(123456789e108, StrtodChar("123456789", 108)); CHECK_EQ(123456789e109, StrtodChar("123456789", 109)); CHECK_EQ(123456789e110, StrtodChar("123456789", 110)); CHECK_EQ(123456789e111, StrtodChar("123456789", 111)); CHECK_EQ(123456789e112, StrtodChar("123456789", 112)); CHECK_EQ(123456789e113, StrtodChar("123456789", 113)); CHECK_EQ(123456789e114, StrtodChar("123456789", 114)); CHECK_EQ(123456789e115, StrtodChar("123456789", 115)); CHECK_EQ(1234567890123456789012345e108, StrtodChar("1234567890123456789012345", 108)); CHECK_EQ(1234567890123456789012345e109, StrtodChar("1234567890123456789012345", 109)); CHECK_EQ(1234567890123456789012345e110, StrtodChar("1234567890123456789012345", 110)); CHECK_EQ(1234567890123456789012345e111, StrtodChar("1234567890123456789012345", 111)); CHECK_EQ(1234567890123456789012345e112, StrtodChar("1234567890123456789012345", 112)); CHECK_EQ(1234567890123456789012345e113, StrtodChar("1234567890123456789012345", 113)); CHECK_EQ(1234567890123456789012345e114, StrtodChar("1234567890123456789012345", 114)); CHECK_EQ(1234567890123456789012345e115, StrtodChar("1234567890123456789012345", 115)); CHECK_EQ(1234567890123456789052345e108, StrtodChar("1234567890123456789052345", 108)); CHECK_EQ(1234567890123456789052345e109, StrtodChar("1234567890123456789052345", 109)); CHECK_EQ(1234567890123456789052345e110, StrtodChar("1234567890123456789052345", 110)); CHECK_EQ(1234567890123456789052345e111, StrtodChar("1234567890123456789052345", 111)); CHECK_EQ(1234567890123456789052345e112, StrtodChar("1234567890123456789052345", 112)); CHECK_EQ(1234567890123456789052345e113, StrtodChar("1234567890123456789052345", 113)); CHECK_EQ(1234567890123456789052345e114, StrtodChar("1234567890123456789052345", 114)); CHECK_EQ(1234567890123456789052345e115, StrtodChar("1234567890123456789052345", 115)); CHECK_EQ(5.445618932859895e-255, StrtodChar("5445618932859895362967233318697132813618813095743952975" "4392982234069699615600475529427176366709107287468930197" "8628345413991790019316974825934906752493984055268219809" "5012176093045431437495773903922425632551857520884625114" "6241265881735209066709685420744388526014389929047617597" "0302268848374508109029268898695825171158085457567481507" "4162979705098246243690189880319928315307816832576838178" "2563074014542859888710209237525873301724479666744537857" "9026553346649664045621387124193095870305991178772256504" "4368663670643970181259143319016472430928902201239474588" "1392338901353291306607057623202353588698746085415097902" "6640064319118728664842287477491068264828851624402189317" "2769161449825765517353755844373640588822904791244190695" "2998382932630754670573838138825217065450843010498555058" "88186560731", -1035)); // Boundary cases. Boundaries themselves should round to even. // // 0x1FFFFFFFFFFFF * 2^3 = 72057594037927928 // next: 72057594037927936 // boundary: 72057594037927932 should round up. CHECK_EQ(72057594037927928.0, StrtodChar("72057594037927928", 0)); CHECK_EQ(72057594037927936.0, StrtodChar("72057594037927936", 0)); CHECK_EQ(72057594037927936.0, StrtodChar("72057594037927932", 0)); CHECK_EQ(72057594037927928.0, StrtodChar("7205759403792793199999", -5)); CHECK_EQ(72057594037927936.0, StrtodChar("7205759403792793200001", -5)); // 0x1FFFFFFFFFFFF * 2^10 = 9223372036854774784 // next: 9223372036854775808 // boundary: 9223372036854775296 should round up. CHECK_EQ(9223372036854774784.0, StrtodChar("9223372036854774784", 0)); CHECK_EQ(9223372036854775808.0, StrtodChar("9223372036854775808", 0)); CHECK_EQ(9223372036854775808.0, StrtodChar("9223372036854775296", 0)); CHECK_EQ(9223372036854774784.0, StrtodChar("922337203685477529599999", -5)); CHECK_EQ(9223372036854775808.0, StrtodChar("922337203685477529600001", -5)); // 0x1FFFFFFFFFFFF * 2^50 = 10141204801825834086073718800384 // next: 10141204801825835211973625643008 // boundary: 10141204801825834649023672221696 should round up. CHECK_EQ(10141204801825834086073718800384.0, StrtodChar("10141204801825834086073718800384", 0)); CHECK_EQ(10141204801825835211973625643008.0, StrtodChar("10141204801825835211973625643008", 0)); CHECK_EQ(10141204801825835211973625643008.0, StrtodChar("10141204801825834649023672221696", 0)); CHECK_EQ(10141204801825834086073718800384.0, StrtodChar("1014120480182583464902367222169599999", -5)); CHECK_EQ(10141204801825835211973625643008.0, StrtodChar("1014120480182583464902367222169600001", -5)); // 0x1FFFFFFFFFFFF * 2^99 = 5708990770823838890407843763683279797179383808 // next: 5708990770823839524233143877797980545530986496 // boundary: 5708990770823839207320493820740630171355185152 // The boundary should round up. CHECK_EQ(5708990770823838890407843763683279797179383808.0, StrtodChar("5708990770823838890407843763683279797179383808", 0)); CHECK_EQ(5708990770823839524233143877797980545530986496.0, StrtodChar("5708990770823839524233143877797980545530986496", 0)); CHECK_EQ(5708990770823839524233143877797980545530986496.0, StrtodChar("5708990770823839207320493820740630171355185152", 0)); CHECK_EQ(5708990770823838890407843763683279797179383808.0, StrtodChar("5708990770823839207320493820740630171355185151999", -3)); CHECK_EQ(5708990770823839524233143877797980545530986496.0, StrtodChar("5708990770823839207320493820740630171355185152001", -3)); // The following test-cases got some public attention in early 2011 when they // sent Java and PHP into an infinite loop. CHECK_EQ(2.225073858507201e-308, StrtodChar("22250738585072011", -324)); CHECK_EQ(2.22507385850720138309e-308, StrtodChar("22250738585072011360574097967091319759348195463516456480" "23426109724822222021076945516529523908135087914149158913" "03962110687008643869459464552765720740782062174337998814" "10632673292535522868813721490129811224514518898490572223" "07285255133155755015914397476397983411801999323962548289" "01710708185069063066665599493827577257201576306269066333" "26475653000092458883164330377797918696120494973903778297" "04905051080609940730262937128958950003583799967207254304" "36028407889577179615094551674824347103070260914462157228" "98802581825451803257070188608721131280795122334262883686" "22321503775666622503982534335974568884423900265498198385" "48794829220689472168983109969836584681402285424333066033" "98508864458040010349339704275671864433837704860378616227" "71738545623065874679014086723327636718751", -1076)); } static int CompareBignumToDiyFp(const Bignum& bignum_digits, int bignum_exponent, DiyFp diy_fp) { Bignum bignum; bignum.AssignBignum(bignum_digits); Bignum other; other.AssignUInt64(diy_fp.f()); if (bignum_exponent >= 0) { bignum.MultiplyByPowerOfTen(bignum_exponent); } else { other.MultiplyByPowerOfTen(-bignum_exponent); } if (diy_fp.e() >= 0) { other.ShiftLeft(diy_fp.e()); } else { bignum.ShiftLeft(-diy_fp.e()); } return Bignum::Compare(bignum, other); } static bool CheckDouble(Vector buffer, int exponent, double to_check) { DiyFp lower_boundary; DiyFp upper_boundary; Bignum input_digits; input_digits.AssignDecimalString(buffer); if (to_check == 0.0) { const double kMinDouble = 4e-324; // Check that the buffer*10^exponent < (0 + kMinDouble)/2. Double d(kMinDouble); d.NormalizedBoundaries(&lower_boundary, &upper_boundary); return CompareBignumToDiyFp(input_digits, exponent, lower_boundary) <= 0; } if (to_check == V8_INFINITY) { const double kMaxDouble = 1.7976931348623157e308; // Check that the buffer*10^exponent >= boundary between kMaxDouble and inf. Double d(kMaxDouble); d.NormalizedBoundaries(&lower_boundary, &upper_boundary); return CompareBignumToDiyFp(input_digits, exponent, upper_boundary) >= 0; } Double d(to_check); d.NormalizedBoundaries(&lower_boundary, &upper_boundary); if ((d.Significand() & 1) == 0) { return CompareBignumToDiyFp(input_digits, exponent, lower_boundary) >= 0 && CompareBignumToDiyFp(input_digits, exponent, upper_boundary) <= 0; } else { return CompareBignumToDiyFp(input_digits, exponent, lower_boundary) > 0 && CompareBignumToDiyFp(input_digits, exponent, upper_boundary) < 0; } } // Copied from v8.cc and adapted to make the function deterministic. static uint32_t DeterministicRandom() { // Random number generator using George Marsaglia's MWC algorithm. static uint32_t hi = 0; static uint32_t lo = 0; // Initialization values don't have any special meaning. (They are the result // of two calls to rand().) if (hi == 0) hi = 0xBFE166E7; if (lo == 0) lo = 0x64D1C3C9; // Mix the bits. hi = 36969 * (hi & 0xFFFF) + (hi >> 16); lo = 18273 * (lo & 0xFFFF) + (lo >> 16); return (hi << 16) + (lo & 0xFFFF); } static const int kBufferSize = 1024; static const int kShortStrtodRandomCount = 2; static const int kLargeStrtodRandomCount = 2; TEST(RandomStrtod) { base::RandomNumberGenerator rng; char buffer[kBufferSize]; for (int length = 1; length < 15; length++) { for (int i = 0; i < kShortStrtodRandomCount; ++i) { int pos = 0; for (int j = 0; j < length; ++j) { buffer[pos++] = rng.NextInt(10) + '0'; } int exponent = DeterministicRandom() % (25*2 + 1) - 25 - length; buffer[pos] = '\0'; Vector vector(buffer, pos); double strtod_result = Strtod(vector, exponent); CHECK(CheckDouble(vector, exponent, strtod_result)); } } for (int length = 15; length < 800; length += 2) { for (int i = 0; i < kLargeStrtodRandomCount; ++i) { int pos = 0; for (int j = 0; j < length; ++j) { buffer[pos++] = rng.NextInt(10) + '0'; } int exponent = DeterministicRandom() % (308*2 + 1) - 308 - length; buffer[pos] = '\0'; Vector vector(buffer, pos); double strtod_result = Strtod(vector, exponent); CHECK(CheckDouble(vector, exponent, strtod_result)); } } } } // namespace test_strtod } // namespace base } // namespace v8