core/fxcrt/fx_system_unittest.cpp - pdfium - Git at Google

 // Copyright 2015 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.

 #include <limits>

 #include "build/build_config.h"
 #include "core/fxcrt/fx_string.h"
 #include "core/fxcrt/fx_system.h"
 #include "testing/gtest/include/gtest/gtest.h"
 #include "third_party/base/stl_util.h"

 // Unit test covering cases where PDFium replaces well-known library
 // functionality on any given platformn.

 #if !defined(OS_WIN)

 namespace {

 const char kSentinel = 0x7f;

 void Check32BitBase16Itoa(int32_t input, const char* expected_output) {
   const size_t kBufLen = 11;  // "-" + 8 digits + NUL + sentinel.
   char buf[kBufLen];
   buf[kBufLen - 1] = kSentinel;
   FXSYS_itoa(input, buf, 16);
   EXPECT_STREQ(expected_output, buf);
   EXPECT_EQ(kSentinel, buf[kBufLen - 1]);
 }

 void Check32BitBase10Itoa(int32_t input, const char* expected_output) {
   const size_t kBufLen = 13;  // "-" + 10 digits + NUL + sentinel.
   char buf[kBufLen];
   buf[kBufLen - 1] = kSentinel;
   FXSYS_itoa(input, buf, 10);
   EXPECT_STREQ(expected_output, buf);
   EXPECT_EQ(kSentinel, buf[kBufLen - 1]);
 }

 void Check32BitBase2Itoa(int32_t input, const char* expected_output) {
   const size_t kBufLen = 35;  // "-" + 32 digits + NUL + sentinel.
   char buf[kBufLen];
   buf[kBufLen - 1] = kSentinel;
   FXSYS_itoa(input, buf, 2);
   EXPECT_STREQ(expected_output, buf);
   EXPECT_EQ(kSentinel, buf[kBufLen - 1]);
 }

 void Check64BitBase16Itoa(int64_t input, const char* expected_output) {
   const size_t kBufLen = 19;  // "-" + 16 digits + NUL + sentinel.
   char buf[kBufLen];
   buf[kBufLen - 1] = kSentinel;
   FXSYS_i64toa(input, buf, 16);
   EXPECT_STREQ(expected_output, buf);
   EXPECT_EQ(kSentinel, buf[kBufLen - 1]);
 }

 void Check64BitBase10Itoa(int64_t input, const char* expected_output) {
   const size_t kBufLen = 22;  // "-" + 19 digits + NUL + sentinel.
   char buf[kBufLen];
   buf[kBufLen - 1] = kSentinel;
   FXSYS_i64toa(input, buf, 10);
   EXPECT_STREQ(expected_output, buf);
   EXPECT_EQ(kSentinel, buf[kBufLen - 1]);
 }

 void Check64BitBase2Itoa(int64_t input, const char* expected_output) {
   const size_t kBufLen = 67;  // "-" + 64 digits + NUL + sentinel.
   char buf[kBufLen];
   buf[kBufLen - 1] = kSentinel;
   FXSYS_i64toa(input, buf, 2);
   EXPECT_STREQ(expected_output, buf);
   EXPECT_EQ(kSentinel, buf[kBufLen - 1]);
 }

 }  // namespace

 TEST(fxcrt, FXSYS_roundf) {
   EXPECT_EQ(0, FXSYS_roundf(0.0f));
   EXPECT_EQ(0, FXSYS_roundf(-0.0f));
   EXPECT_EQ(0, FXSYS_roundf(0.00001f));
   EXPECT_EQ(0, FXSYS_roundf(-0.00001f));
   EXPECT_EQ(3, FXSYS_roundf(3.14159f));
   EXPECT_EQ(4, FXSYS_roundf(3.5f));

   // Check for smallest non-zero float values.
   EXPECT_EQ(0, FXSYS_roundf(std::numeric_limits<float>::min()));
   EXPECT_EQ(0, FXSYS_roundf(-std::numeric_limits<float>::min()));

   // Function is a wrapper around standard C library function round(), so
   // returns the integral value that is nearest to x, with halfway cases
   // rounded away from zero.
   EXPECT_EQ(-3, FXSYS_roundf(-3.14159f));
   EXPECT_EQ(-4, FXSYS_roundf(-3.5f));

   // Positive rounding stops at maximum int.
   // MAX_INT=0x7FFFFFFF=2147483647=2.147483647e+9
   // In IEEE-754 format, 2^31 yields exponent of 0x9E with mantissa of all
   // zeroes which is 0x4f000000=2.14748365e+9, which is beyond max integer.
   // Going to next smallest float by minus one from exponent and mantissa of
   // all ones yields binary float representation of 0x4EFFFFFF=2.14748352e+9,
   // which is 2147483520.
   EXPECT_EQ(2147483520, FXSYS_roundf(2.14748352e+9f));

   // Using a slightly larger value, expect to see it be capped at MAX_INT.
   EXPECT_EQ(2147483647, FXSYS_roundf(2.14748365e+9f));

   EXPECT_EQ(2147483647, FXSYS_roundf(2.14748365e+10f));
   EXPECT_EQ(2147483647, FXSYS_roundf(std::numeric_limits<float>::max()));

   // Negative rounding stops at minimum int.
   // MIN_INT=0x80000000=-2147483648,=-2.147483648e+9
   // In IEEE-754 format, 2^31 yields exponent of 0x9E with mantissa of all
   // zeroes which is 0x4f000000=2.14748365e+9, and the sign bit set, which
   // is 0xCF000000 and exactly matches the minimum integer.  Going to next
   // smallest negative float by minus one from exponent and mantissa of all
   // ones yields binary float representation of 0xCEFFFFFF=-2.14748352e+9,
   // which is -2147483520.
   EXPECT_EQ(-2147483648, FXSYS_roundf(-2.147483648e+10f));
   EXPECT_EQ(-2147483648, FXSYS_roundf(-2.147483648e+9f));
   EXPECT_EQ(-2147483520, FXSYS_roundf(-2.14748352e+9f));
   EXPECT_EQ(-2147483648, FXSYS_roundf(-std::numeric_limits<float>::max()));

   // NaN should give zero.
   EXPECT_EQ(0, FXSYS_roundf(NAN));
 }

 TEST(fxcrt, FXSYS_round) {
   EXPECT_EQ(0, FXSYS_round(0.0));
   EXPECT_EQ(0, FXSYS_round(-0.0));
   EXPECT_EQ(0, FXSYS_round(0.00001));
   EXPECT_EQ(0, FXSYS_round(-0.00001));
   EXPECT_EQ(3, FXSYS_round(3.14159));
   EXPECT_EQ(4, FXSYS_round(3.5));

   // Check for smallest non-zero double values.
   EXPECT_EQ(0, FXSYS_round(std::numeric_limits<double>::min()));
   EXPECT_EQ(0, FXSYS_round(-std::numeric_limits<double>::min()));

   // Function is a wrapper around standard C library function round(), so
   // returns the integral value that is nearest to x, with halfway cases
   // rounded away from zero.
   EXPECT_EQ(-3, FXSYS_round(-3.14159));
   EXPECT_EQ(-4, FXSYS_round(-3.5));

   // Positive rounding stops at maximum int.
   // MAX_INT=0x7FFFFFFF=2147483647=2.147483647e+9
   // In IEEE-754 double precision format, 2^31 yields exponent of 0x41E with
   // mantissa of all zeroes which is 0x41E0000000000000=2.14748365e+9, which
   // is beyond max integer.
   // Going to next smallest float by minus one from exponent and mantissa of
   // all ones yields binary float representation of
   // 41DFFFFFFFC00000=2.147483647e+9, which matches the max integer.
   EXPECT_EQ(2147483647, FXSYS_round(2.147483647e+9));

   // Using a slightly larger value, expect to see it be capped at MAX_INT.
   EXPECT_EQ(2147483647, FXSYS_round(2.14748365e+9));

   EXPECT_EQ(2147483647, FXSYS_round(2.14748365e+10));
   EXPECT_EQ(2147483647, FXSYS_round(std::numeric_limits<double>::max()));

   // Negative rounding stops at minimum int.
   // MIN_INT=0x80000000=-2147483648,=-2.147483648e+9
   // In IEEE-754 double precision format, 2^31 yields exponent of 0x41E with
   // mantissa of all zeroes which is 0x41E0000000000000=2.14748365e+9, and the
   // sign bit set, which is 0xC1E0000000000000 and exactly matches the minimum
   // integer.  Going to next smallest negative double by minus one from
   // exponent and mantissa of all ones yields binary float representation of
   // 0xC1DFFFFFFFFFFFFF=-2.1474836479999998e+9, which is -2147483648.
   EXPECT_EQ(-2147483648, FXSYS_round(-2.1474836479999998e+9));
   EXPECT_EQ(-2147483648, FXSYS_round(-2.147483648e+9));
   EXPECT_EQ(-2147483648, FXSYS_round(-2.147483648e+10));
   EXPECT_EQ(-2147483648, FXSYS_round(-std::numeric_limits<double>::max()));

   // NaN should give zero.
   EXPECT_EQ(0, FXSYS_round(NAN));
 }

 TEST(fxcrt, FXSYS_itoa_InvalidRadix) {
   char buf[32];

   FXSYS_itoa(42, buf, 17);  // Ours stops at 16.
   EXPECT_STREQ("", buf);

   FXSYS_itoa(42, buf, 1);
   EXPECT_STREQ("", buf);

   FXSYS_itoa(42, buf, 0);
   EXPECT_STREQ("", buf);

   FXSYS_itoa(42, buf, -1);
   EXPECT_STREQ("", buf);
 }

 TEST(fxcrt, FXSYS_itoa) {
   Check32BitBase16Itoa(std::numeric_limits<int32_t>::min(), "-80000000");
   Check32BitBase10Itoa(std::numeric_limits<int32_t>::min(), "-2147483648");
   Check32BitBase2Itoa(std::numeric_limits<int32_t>::min(),
                       "-10000000000000000000000000000000");

   Check32BitBase16Itoa(-1, "-1");
   Check32BitBase10Itoa(-1, "-1");
   Check32BitBase2Itoa(-1, "-1");

   Check32BitBase16Itoa(0, "0");
   Check32BitBase10Itoa(0, "0");
   Check32BitBase2Itoa(0, "0");

   Check32BitBase16Itoa(42, "2a");
   Check32BitBase10Itoa(42, "42");
   Check32BitBase2Itoa(42, "101010");

   Check32BitBase16Itoa(std::numeric_limits<int32_t>::max(), "7fffffff");
   Check32BitBase10Itoa(std::numeric_limits<int32_t>::max(), "2147483647");
   Check32BitBase2Itoa(std::numeric_limits<int32_t>::max(),
                       "1111111111111111111111111111111");
 }

 TEST(fxcrt, FXSYS_i64toa_InvalidRadix) {
   char buf[32];

   FXSYS_i64toa(42, buf, 17);  // Ours stops at 16.
   EXPECT_STREQ("", buf);

   FXSYS_i64toa(42, buf, 1);
   EXPECT_STREQ("", buf);

   FXSYS_i64toa(42, buf, 0);
   EXPECT_STREQ("", buf);

   FXSYS_i64toa(42, buf, -1);
   EXPECT_STREQ("", buf);
 }

 TEST(fxcrt, FXSYS_i64toa) {
   Check64BitBase16Itoa(std::numeric_limits<int64_t>::min(),
                        "-8000000000000000");
   Check64BitBase10Itoa(std::numeric_limits<int64_t>::min(),
                        "-9223372036854775808");
   Check64BitBase2Itoa(
       std::numeric_limits<int64_t>::min(),
       "-1000000000000000000000000000000000000000000000000000000000000000");

   Check64BitBase16Itoa(-1, "-1");
   Check64BitBase10Itoa(-1, "-1");
   Check64BitBase2Itoa(-1, "-1");

   Check64BitBase16Itoa(0, "0");
   Check64BitBase10Itoa(0, "0");
   Check64BitBase2Itoa(0, "0");

   Check64BitBase16Itoa(42, "2a");
   Check64BitBase10Itoa(42, "42");
   Check64BitBase2Itoa(42, "101010");

   Check64BitBase16Itoa(std::numeric_limits<int64_t>::max(), "7fffffffffffffff");
   Check64BitBase10Itoa(std::numeric_limits<int64_t>::max(),
                        "9223372036854775807");
   Check64BitBase2Itoa(
       std::numeric_limits<int64_t>::max(),
       "111111111111111111111111111111111111111111111111111111111111111");
 }

 #endif  // !defined(OS_WIN)

 TEST(fxcrt, FXSYS_wcsftime) {
   struct tm good_time = {};
   good_time.tm_year = 74;  // 1900-based.
   good_time.tm_mon = 7;    // 0-based.
   good_time.tm_mday = 9;   // 1-based.
   good_time.tm_hour = 11;
   good_time.tm_min = 59;
   good_time.tm_sec = 59;

   wchar_t buf[100] = {};
   EXPECT_EQ(19u, FXSYS_wcsftime(buf, pdfium::size(buf), L"%Y-%m-%dT%H:%M:%S",
                                 &good_time));
   EXPECT_STREQ(L"1974-08-09T11:59:59", buf);

   // Ensure wcsftime handles a wide range of years without crashing.
   struct tm year_time = {};
   year_time.tm_mon = 7;   // 0-based.
   year_time.tm_mday = 9;  // 1-based.
   year_time.tm_hour = 11;
   year_time.tm_min = 59;
   year_time.tm_sec = 59;

   for (int year = -2500; year <= 8500; ++year) {
     year_time.tm_year = year;
     wchar_t year_buf[100] = {};
     FXSYS_wcsftime(year_buf, pdfium::size(year_buf), L"%Y-%m-%dT%H:%M:%S",
                    &year_time);
   }

   // Ensure wcsftime handles bad years, etc. without crashing.
   struct tm bad_time = {};
   bad_time.tm_year = -1;
   bad_time.tm_mon = -1;
   bad_time.tm_mday = -1;
   bad_time.tm_hour = -1;
   bad_time.tm_min = -1;
   bad_time.tm_sec = -1;

   FXSYS_wcsftime(buf, pdfium::size(buf), L"%y-%m-%dT%H:%M:%S", &bad_time);

   // Ensure wcsftime handles bad-ish day without crashing (Feb 30).
   struct tm feb_time = {};
   feb_time.tm_year = 115;  // 1900-based.
   feb_time.tm_mon = 1;     // 0-based.
   feb_time.tm_mday = 30;   // 1-based.
   feb_time.tm_hour = 12;
   feb_time.tm_min = 00;
   feb_time.tm_sec = 00;

   FXSYS_wcsftime(buf, pdfium::size(buf), L"%y-%m-%dT%H:%M:%S", &feb_time);
 }

 TEST(fxcrt, FXSYS_atoi) {
   EXPECT_EQ(0, FXSYS_atoi(""));
   EXPECT_EQ(0, FXSYS_atoi("0"));
   EXPECT_EQ(-1, FXSYS_atoi("-1"));
   EXPECT_EQ(2345, FXSYS_atoi("2345"));
   EXPECT_EQ(-2147483647, FXSYS_atoi("-2147483647"));
   // Handle the sign.
   EXPECT_EQ(-2345, FXSYS_atoi("-2345"));
   EXPECT_EQ(2345, FXSYS_atoi("+2345"));
   // The max value.
   EXPECT_EQ(2147483647, FXSYS_atoi("2147483647"));
   // The min value. Written in -1 format to avoid "unary minus operator applied
   // to unsigned type" warning.
   EXPECT_EQ(-2147483647 - 1, FXSYS_atoi("-2147483648"));
   // With invalid char.
   EXPECT_EQ(9, FXSYS_atoi("9x9"));

   // Out of range values.
   EXPECT_EQ(2147483647, FXSYS_atoi("2147483623423412348"));
   EXPECT_EQ(2147483647, FXSYS_atoi("2147483648"));
   EXPECT_EQ(-2147483647 - 1, FXSYS_atoi("-2147483650"));
 }

 TEST(fxcrt, FXSYS_atoi64) {
   EXPECT_EQ(0, FXSYS_atoi64(""));
   EXPECT_EQ(0, FXSYS_atoi64("0"));
   EXPECT_EQ(-1, FXSYS_atoi64("-1"));
   EXPECT_EQ(2345, FXSYS_atoi64("2345"));
   EXPECT_EQ(-9223372036854775807LL, FXSYS_atoi64("-9223372036854775807"));
   // Handle the sign.
   EXPECT_EQ(-2345, FXSYS_atoi64("-2345"));
   EXPECT_EQ(2345, FXSYS_atoi64("+2345"));
   // The max value.
   EXPECT_EQ(9223372036854775807LL, FXSYS_atoi64("9223372036854775807"));
   // The min value. Written in -1 format to avoid implicit unsigned warning.
   EXPECT_EQ(-9223372036854775807LL - 1LL, FXSYS_atoi64("-9223372036854775808"));
   // With invalid char.
   EXPECT_EQ(9, FXSYS_atoi64("9x9"));

   // Out of range values.
   EXPECT_EQ(9223372036854775807LL, FXSYS_atoi64("922337203685471234123475807"));
   EXPECT_EQ(9223372036854775807LL, FXSYS_atoi64("9223372036854775808"));
   EXPECT_EQ(-9223372036854775807LL - 1LL, FXSYS_atoi64("-9223372036854775810"));
 }

 TEST(fxcrt, FXSYS_wtoi) {
   EXPECT_EQ(0, FXSYS_wtoi(L""));
   EXPECT_EQ(0, FXSYS_wtoi(L"0"));
   EXPECT_EQ(-1, FXSYS_wtoi(L"-1"));
   EXPECT_EQ(2345, FXSYS_wtoi(L"2345"));
   EXPECT_EQ(-2147483647, FXSYS_wtoi(L"-2147483647"));
   // The max value.
   EXPECT_EQ(2147483647, FXSYS_wtoi(L"2147483647"));
   // The min value.
   EXPECT_EQ(-2147483647 - 1, FXSYS_wtoi(L"-2147483648"));

   // Out of range values.
   EXPECT_EQ(2147483647, FXSYS_wtoi(L"2147483623423412348"));
   EXPECT_EQ(2147483647, FXSYS_wtoi(L"2147483648"));
   EXPECT_EQ(-2147483647 - 1, FXSYS_wtoi(L"-2147483652"));
 }

 TEST(fxcrt, FXSYS_atoui) {
   EXPECT_EQ(0u, FXSYS_atoui(""));
   EXPECT_EQ(0u, FXSYS_atoui("0"));
   EXPECT_EQ(4294967295, FXSYS_atoui("-1"));
   EXPECT_EQ(2345u, FXSYS_atoui("2345"));
   // Handle the sign.
   EXPECT_EQ(4294964951, FXSYS_atoui("-2345"));
   EXPECT_EQ(2345u, FXSYS_atoui("+2345"));
   // The max value.
   EXPECT_EQ(4294967295, FXSYS_atoui("4294967295"));
   EXPECT_EQ(9u, FXSYS_atoui("9x9"));

   // Out of range values.
   EXPECT_EQ(4294967295, FXSYS_atoui("2147483623423412348"));
   EXPECT_EQ(4294967295, FXSYS_atoui("4294967296"));
   EXPECT_EQ(4294967295, FXSYS_atoui("-4294967345"));
 }
	// Copyright 2015 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.

	#include <limits>

	#include "build/build_config.h"
	#include "core/fxcrt/fx_string.h"
	#include "core/fxcrt/fx_system.h"
	#include "testing/gtest/include/gtest/gtest.h"
	#include "third_party/base/stl_util.h"

	// Unit test covering cases where PDFium replaces well-known library
	// functionality on any given platformn.

	#if !defined(OS_WIN)

	namespace {

	const char kSentinel = 0x7f;

	void Check32BitBase16Itoa(int32_t input, const char* expected_output) {
	const size_t kBufLen = 11; // "-" + 8 digits + NUL + sentinel.
	char buf[kBufLen];
	buf[kBufLen - 1] = kSentinel;
	FXSYS_itoa(input, buf, 16);
	EXPECT_STREQ(expected_output, buf);
	EXPECT_EQ(kSentinel, buf[kBufLen - 1]);
	}

	void Check32BitBase10Itoa(int32_t input, const char* expected_output) {
	const size_t kBufLen = 13; // "-" + 10 digits + NUL + sentinel.
	char buf[kBufLen];
	buf[kBufLen - 1] = kSentinel;
	FXSYS_itoa(input, buf, 10);
	EXPECT_STREQ(expected_output, buf);
	EXPECT_EQ(kSentinel, buf[kBufLen - 1]);
	}

	void Check32BitBase2Itoa(int32_t input, const char* expected_output) {
	const size_t kBufLen = 35; // "-" + 32 digits + NUL + sentinel.
	char buf[kBufLen];
	buf[kBufLen - 1] = kSentinel;
	FXSYS_itoa(input, buf, 2);
	EXPECT_STREQ(expected_output, buf);
	EXPECT_EQ(kSentinel, buf[kBufLen - 1]);
	}

	void Check64BitBase16Itoa(int64_t input, const char* expected_output) {
	const size_t kBufLen = 19; // "-" + 16 digits + NUL + sentinel.
	char buf[kBufLen];
	buf[kBufLen - 1] = kSentinel;
	FXSYS_i64toa(input, buf, 16);
	EXPECT_STREQ(expected_output, buf);
	EXPECT_EQ(kSentinel, buf[kBufLen - 1]);
	}

	void Check64BitBase10Itoa(int64_t input, const char* expected_output) {
	const size_t kBufLen = 22; // "-" + 19 digits + NUL + sentinel.
	char buf[kBufLen];
	buf[kBufLen - 1] = kSentinel;
	FXSYS_i64toa(input, buf, 10);
	EXPECT_STREQ(expected_output, buf);
	EXPECT_EQ(kSentinel, buf[kBufLen - 1]);
	}

	void Check64BitBase2Itoa(int64_t input, const char* expected_output) {
	const size_t kBufLen = 67; // "-" + 64 digits + NUL + sentinel.
	char buf[kBufLen];
	buf[kBufLen - 1] = kSentinel;
	FXSYS_i64toa(input, buf, 2);
	EXPECT_STREQ(expected_output, buf);
	EXPECT_EQ(kSentinel, buf[kBufLen - 1]);
	}

	} // namespace

	TEST(fxcrt, FXSYS_roundf) {
	EXPECT_EQ(0, FXSYS_roundf(0.0f));
	EXPECT_EQ(0, FXSYS_roundf(-0.0f));
	EXPECT_EQ(0, FXSYS_roundf(0.00001f));
	EXPECT_EQ(0, FXSYS_roundf(-0.00001f));
	EXPECT_EQ(3, FXSYS_roundf(3.14159f));
	EXPECT_EQ(4, FXSYS_roundf(3.5f));

	// Check for smallest non-zero float values.
	EXPECT_EQ(0, FXSYS_roundf(std::numeric_limits<float>::min()));
	EXPECT_EQ(0, FXSYS_roundf(-std::numeric_limits<float>::min()));

	// Function is a wrapper around standard C library function round(), so
	// returns the integral value that is nearest to x, with halfway cases
	// rounded away from zero.
	EXPECT_EQ(-3, FXSYS_roundf(-3.14159f));
	EXPECT_EQ(-4, FXSYS_roundf(-3.5f));

	// Positive rounding stops at maximum int.
	// MAX_INT=0x7FFFFFFF=2147483647=2.147483647e+9
	// In IEEE-754 format, 2^31 yields exponent of 0x9E with mantissa of all
	// zeroes which is 0x4f000000=2.14748365e+9, which is beyond max integer.
	// Going to next smallest float by minus one from exponent and mantissa of
	// all ones yields binary float representation of 0x4EFFFFFF=2.14748352e+9,
	// which is 2147483520.
	EXPECT_EQ(2147483520, FXSYS_roundf(2.14748352e+9f));

	// Using a slightly larger value, expect to see it be capped at MAX_INT.
	EXPECT_EQ(2147483647, FXSYS_roundf(2.14748365e+9f));

	EXPECT_EQ(2147483647, FXSYS_roundf(2.14748365e+10f));
	EXPECT_EQ(2147483647, FXSYS_roundf(std::numeric_limits<float>::max()));

	// Negative rounding stops at minimum int.
	// MIN_INT=0x80000000=-2147483648,=-2.147483648e+9
	// In IEEE-754 format, 2^31 yields exponent of 0x9E with mantissa of all
	// zeroes which is 0x4f000000=2.14748365e+9, and the sign bit set, which
	// is 0xCF000000 and exactly matches the minimum integer. Going to next
	// smallest negative float by minus one from exponent and mantissa of all
	// ones yields binary float representation of 0xCEFFFFFF=-2.14748352e+9,
	// which is -2147483520.
	EXPECT_EQ(-2147483648, FXSYS_roundf(-2.147483648e+10f));
	EXPECT_EQ(-2147483648, FXSYS_roundf(-2.147483648e+9f));
	EXPECT_EQ(-2147483520, FXSYS_roundf(-2.14748352e+9f));
	EXPECT_EQ(-2147483648, FXSYS_roundf(-std::numeric_limits<float>::max()));

	// NaN should give zero.
	EXPECT_EQ(0, FXSYS_roundf(NAN));
	}

	TEST(fxcrt, FXSYS_round) {
	EXPECT_EQ(0, FXSYS_round(0.0));
	EXPECT_EQ(0, FXSYS_round(-0.0));
	EXPECT_EQ(0, FXSYS_round(0.00001));
	EXPECT_EQ(0, FXSYS_round(-0.00001));
	EXPECT_EQ(3, FXSYS_round(3.14159));
	EXPECT_EQ(4, FXSYS_round(3.5));

	// Check for smallest non-zero double values.
	EXPECT_EQ(0, FXSYS_round(std::numeric_limits<double>::min()));
	EXPECT_EQ(0, FXSYS_round(-std::numeric_limits<double>::min()));

	// Function is a wrapper around standard C library function round(), so
	// returns the integral value that is nearest to x, with halfway cases
	// rounded away from zero.
	EXPECT_EQ(-3, FXSYS_round(-3.14159));
	EXPECT_EQ(-4, FXSYS_round(-3.5));

	// Positive rounding stops at maximum int.
	// MAX_INT=0x7FFFFFFF=2147483647=2.147483647e+9
	// In IEEE-754 double precision format, 2^31 yields exponent of 0x41E with
	// mantissa of all zeroes which is 0x41E0000000000000=2.14748365e+9, which
	// is beyond max integer.
	// Going to next smallest float by minus one from exponent and mantissa of
	// all ones yields binary float representation of
	// 41DFFFFFFFC00000=2.147483647e+9, which matches the max integer.
	EXPECT_EQ(2147483647, FXSYS_round(2.147483647e+9));

	// Using a slightly larger value, expect to see it be capped at MAX_INT.
	EXPECT_EQ(2147483647, FXSYS_round(2.14748365e+9));

	EXPECT_EQ(2147483647, FXSYS_round(2.14748365e+10));
	EXPECT_EQ(2147483647, FXSYS_round(std::numeric_limits<double>::max()));

	// Negative rounding stops at minimum int.
	// MIN_INT=0x80000000=-2147483648,=-2.147483648e+9
	// In IEEE-754 double precision format, 2^31 yields exponent of 0x41E with
	// mantissa of all zeroes which is 0x41E0000000000000=2.14748365e+9, and the
	// sign bit set, which is 0xC1E0000000000000 and exactly matches the minimum
	// integer. Going to next smallest negative double by minus one from
	// exponent and mantissa of all ones yields binary float representation of
	// 0xC1DFFFFFFFFFFFFF=-2.1474836479999998e+9, which is -2147483648.
	EXPECT_EQ(-2147483648, FXSYS_round(-2.1474836479999998e+9));
	EXPECT_EQ(-2147483648, FXSYS_round(-2.147483648e+9));
	EXPECT_EQ(-2147483648, FXSYS_round(-2.147483648e+10));
	EXPECT_EQ(-2147483648, FXSYS_round(-std::numeric_limits<double>::max()));

	// NaN should give zero.
	EXPECT_EQ(0, FXSYS_round(NAN));
	}

	TEST(fxcrt, FXSYS_itoa_InvalidRadix) {
	char buf[32];

	FXSYS_itoa(42, buf, 17); // Ours stops at 16.
	EXPECT_STREQ("", buf);

	FXSYS_itoa(42, buf, 1);
	EXPECT_STREQ("", buf);

	FXSYS_itoa(42, buf, 0);
	EXPECT_STREQ("", buf);

	FXSYS_itoa(42, buf, -1);
	EXPECT_STREQ("", buf);
	}

	TEST(fxcrt, FXSYS_itoa) {
	Check32BitBase16Itoa(std::numeric_limits<int32_t>::min(), "-80000000");
	Check32BitBase10Itoa(std::numeric_limits<int32_t>::min(), "-2147483648");
	Check32BitBase2Itoa(std::numeric_limits<int32_t>::min(),
	"-10000000000000000000000000000000");

	Check32BitBase16Itoa(-1, "-1");
	Check32BitBase10Itoa(-1, "-1");
	Check32BitBase2Itoa(-1, "-1");

	Check32BitBase16Itoa(0, "0");
	Check32BitBase10Itoa(0, "0");
	Check32BitBase2Itoa(0, "0");

	Check32BitBase16Itoa(42, "2a");
	Check32BitBase10Itoa(42, "42");
	Check32BitBase2Itoa(42, "101010");

	Check32BitBase16Itoa(std::numeric_limits<int32_t>::max(), "7fffffff");
	Check32BitBase10Itoa(std::numeric_limits<int32_t>::max(), "2147483647");
	Check32BitBase2Itoa(std::numeric_limits<int32_t>::max(),
	"1111111111111111111111111111111");
	}

	TEST(fxcrt, FXSYS_i64toa_InvalidRadix) {
	char buf[32];

	FXSYS_i64toa(42, buf, 17); // Ours stops at 16.
	EXPECT_STREQ("", buf);

	FXSYS_i64toa(42, buf, 1);
	EXPECT_STREQ("", buf);

	FXSYS_i64toa(42, buf, 0);
	EXPECT_STREQ("", buf);

	FXSYS_i64toa(42, buf, -1);
	EXPECT_STREQ("", buf);
	}

	TEST(fxcrt, FXSYS_i64toa) {
	Check64BitBase16Itoa(std::numeric_limits<int64_t>::min(),
	"-8000000000000000");
	Check64BitBase10Itoa(std::numeric_limits<int64_t>::min(),
	"-9223372036854775808");
	Check64BitBase2Itoa(
	std::numeric_limits<int64_t>::min(),
	"-1000000000000000000000000000000000000000000000000000000000000000");

	Check64BitBase16Itoa(-1, "-1");
	Check64BitBase10Itoa(-1, "-1");
	Check64BitBase2Itoa(-1, "-1");

	Check64BitBase16Itoa(0, "0");
	Check64BitBase10Itoa(0, "0");
	Check64BitBase2Itoa(0, "0");

	Check64BitBase16Itoa(42, "2a");
	Check64BitBase10Itoa(42, "42");
	Check64BitBase2Itoa(42, "101010");

	Check64BitBase16Itoa(std::numeric_limits<int64_t>::max(), "7fffffffffffffff");
	Check64BitBase10Itoa(std::numeric_limits<int64_t>::max(),
	"9223372036854775807");
	Check64BitBase2Itoa(
	std::numeric_limits<int64_t>::max(),
	"111111111111111111111111111111111111111111111111111111111111111");
	}

	#endif // !defined(OS_WIN)

	TEST(fxcrt, FXSYS_wcsftime) {
	struct tm good_time = {};
	good_time.tm_year = 74; // 1900-based.
	good_time.tm_mon = 7; // 0-based.
	good_time.tm_mday = 9; // 1-based.
	good_time.tm_hour = 11;
	good_time.tm_min = 59;
	good_time.tm_sec = 59;

	wchar_t buf[100] = {};
	EXPECT_EQ(19u, FXSYS_wcsftime(buf, pdfium::size(buf), L"%Y-%m-%dT%H:%M:%S",
	&good_time));
	EXPECT_STREQ(L"1974-08-09T11:59:59", buf);

	// Ensure wcsftime handles a wide range of years without crashing.
	struct tm year_time = {};
	year_time.tm_mon = 7; // 0-based.
	year_time.tm_mday = 9; // 1-based.
	year_time.tm_hour = 11;
	year_time.tm_min = 59;
	year_time.tm_sec = 59;

	for (int year = -2500; year <= 8500; ++year) {
	year_time.tm_year = year;
	wchar_t year_buf[100] = {};
	FXSYS_wcsftime(year_buf, pdfium::size(year_buf), L"%Y-%m-%dT%H:%M:%S",
	&year_time);
	}

	// Ensure wcsftime handles bad years, etc. without crashing.
	struct tm bad_time = {};
	bad_time.tm_year = -1;
	bad_time.tm_mon = -1;
	bad_time.tm_mday = -1;
	bad_time.tm_hour = -1;
	bad_time.tm_min = -1;
	bad_time.tm_sec = -1;

	FXSYS_wcsftime(buf, pdfium::size(buf), L"%y-%m-%dT%H:%M:%S", &bad_time);

	// Ensure wcsftime handles bad-ish day without crashing (Feb 30).
	struct tm feb_time = {};
	feb_time.tm_year = 115; // 1900-based.
	feb_time.tm_mon = 1; // 0-based.
	feb_time.tm_mday = 30; // 1-based.
	feb_time.tm_hour = 12;
	feb_time.tm_min = 00;
	feb_time.tm_sec = 00;

	FXSYS_wcsftime(buf, pdfium::size(buf), L"%y-%m-%dT%H:%M:%S", &feb_time);
	}

	TEST(fxcrt, FXSYS_atoi) {
	EXPECT_EQ(0, FXSYS_atoi(""));
	EXPECT_EQ(0, FXSYS_atoi("0"));
	EXPECT_EQ(-1, FXSYS_atoi("-1"));
	EXPECT_EQ(2345, FXSYS_atoi("2345"));
	EXPECT_EQ(-2147483647, FXSYS_atoi("-2147483647"));
	// Handle the sign.
	EXPECT_EQ(-2345, FXSYS_atoi("-2345"));
	EXPECT_EQ(2345, FXSYS_atoi("+2345"));
	// The max value.
	EXPECT_EQ(2147483647, FXSYS_atoi("2147483647"));
	// The min value. Written in -1 format to avoid "unary minus operator applied
	// to unsigned type" warning.
	EXPECT_EQ(-2147483647 - 1, FXSYS_atoi("-2147483648"));
	// With invalid char.
	EXPECT_EQ(9, FXSYS_atoi("9x9"));

	// Out of range values.
	EXPECT_EQ(2147483647, FXSYS_atoi("2147483623423412348"));
	EXPECT_EQ(2147483647, FXSYS_atoi("2147483648"));
	EXPECT_EQ(-2147483647 - 1, FXSYS_atoi("-2147483650"));
	}

	TEST(fxcrt, FXSYS_atoi64) {
	EXPECT_EQ(0, FXSYS_atoi64(""));
	EXPECT_EQ(0, FXSYS_atoi64("0"));
	EXPECT_EQ(-1, FXSYS_atoi64("-1"));
	EXPECT_EQ(2345, FXSYS_atoi64("2345"));
	EXPECT_EQ(-9223372036854775807LL, FXSYS_atoi64("-9223372036854775807"));
	// Handle the sign.
	EXPECT_EQ(-2345, FXSYS_atoi64("-2345"));
	EXPECT_EQ(2345, FXSYS_atoi64("+2345"));
	// The max value.
	EXPECT_EQ(9223372036854775807LL, FXSYS_atoi64("9223372036854775807"));
	// The min value. Written in -1 format to avoid implicit unsigned warning.
	EXPECT_EQ(-9223372036854775807LL - 1LL, FXSYS_atoi64("-9223372036854775808"));
	// With invalid char.
	EXPECT_EQ(9, FXSYS_atoi64("9x9"));

	// Out of range values.
	EXPECT_EQ(9223372036854775807LL, FXSYS_atoi64("922337203685471234123475807"));
	EXPECT_EQ(9223372036854775807LL, FXSYS_atoi64("9223372036854775808"));
	EXPECT_EQ(-9223372036854775807LL - 1LL, FXSYS_atoi64("-9223372036854775810"));
	}

	TEST(fxcrt, FXSYS_wtoi) {
	EXPECT_EQ(0, FXSYS_wtoi(L""));
	EXPECT_EQ(0, FXSYS_wtoi(L"0"));
	EXPECT_EQ(-1, FXSYS_wtoi(L"-1"));
	EXPECT_EQ(2345, FXSYS_wtoi(L"2345"));
	EXPECT_EQ(-2147483647, FXSYS_wtoi(L"-2147483647"));
	// The max value.
	EXPECT_EQ(2147483647, FXSYS_wtoi(L"2147483647"));
	// The min value.
	EXPECT_EQ(-2147483647 - 1, FXSYS_wtoi(L"-2147483648"));

	// Out of range values.
	EXPECT_EQ(2147483647, FXSYS_wtoi(L"2147483623423412348"));
	EXPECT_EQ(2147483647, FXSYS_wtoi(L"2147483648"));
	EXPECT_EQ(-2147483647 - 1, FXSYS_wtoi(L"-2147483652"));
	}

	TEST(fxcrt, FXSYS_atoui) {
	EXPECT_EQ(0u, FXSYS_atoui(""));
	EXPECT_EQ(0u, FXSYS_atoui("0"));
	EXPECT_EQ(4294967295, FXSYS_atoui("-1"));
	EXPECT_EQ(2345u, FXSYS_atoui("2345"));
	// Handle the sign.
	EXPECT_EQ(4294964951, FXSYS_atoui("-2345"));
	EXPECT_EQ(2345u, FXSYS_atoui("+2345"));
	// The max value.
	EXPECT_EQ(4294967295, FXSYS_atoui("4294967295"));
	EXPECT_EQ(9u, FXSYS_atoui("9x9"));

	// Out of range values.
	EXPECT_EQ(4294967295, FXSYS_atoui("2147483623423412348"));
	EXPECT_EQ(4294967295, FXSYS_atoui("4294967296"));
	EXPECT_EQ(4294967295, FXSYS_atoui("-4294967345"));
	}