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Export of internal Abseil changes

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--
d447fdcb801036cf08197eece193a5a706661120 by Gennadiy Rozental <rogeeff@google.com>:

Eliminate the need for static function holding help message. This decreases the cost of ABSL_FLAG abstraction by 120 bytes under clang.

PiperOrigin-RevId: 281107806

--
0aa6b91189f0e8b2381438c33465673a7ae02487 by Derek Mauro <dmauro@google.com>:

Disable the weak symbol CCTZ extension in the time test_util
on MinGW, which does not support it.

PiperOrigin-RevId: 280719769

--
67322c41c3e776eb541de90fa4526bdb49422eb6 by Abseil Team <absl-team@google.com>:

Tune PeriodicSampler implementation (for internal-use only)

PiperOrigin-RevId: 280708943

--
3a48c346340c7ed03816645cd327e1ff07729aa4 by Abseil Team <absl-team@google.com>:

Clean up public headers not to have warnings for "-Wcomma"

PiperOrigin-RevId: 280695373

--
981acd1ef3b13a83a84f04f11c8931f4ed4451c9 by Matthew Brown <matthewbr@google.com>:

Release absl::int128.

PiperOrigin-RevId: 280690817

--
d30fae9d2ec30b81322d2eb5afe7e13e45b4b422 by Derek Mauro <dmauro@google.com>:

Fix -Wundef warnings in random platform detection

PiperOrigin-RevId: 280669598
GitOrigin-RevId: d447fdcb801036cf08197eece193a5a706661120
Change-Id: Ie5e10e567c54b7de211833607689f233d4ddf734
This commit is contained in:
Abseil Team 2019-11-18 11:02:26 -08:00 committed by Gennadiy Civil
parent 3df7b52a6a
commit 2103fd9acd
23 changed files with 2800 additions and 136 deletions
Download patch file Download diff file Expand all files Collapse all files

35
absl/base/internal/bits.h
View file

@ -50,10 +50,22 @@ namespace base_internal {
ABSL_BASE_INTERNAL_FORCEINLINE int CountLeadingZeros64Slow(uint64_t n) {
int zeroes = 60;
if (n >> 32) zeroes -= 32, n >>= 32;
if (n >> 16) zeroes -= 16, n >>= 16;
if (n >> 8) zeroes -= 8, n >>= 8;
if (n >> 4) zeroes -= 4, n >>= 4;
if (n >> 32) {
zeroes -= 32;
n >>= 32;
}
if (n >> 16) {
zeroes -= 16;
n >>= 16;
}
if (n >> 8) {
zeroes -= 8;
n >>= 8;
}
if (n >> 4) {
zeroes -= 4;
n >>= 4;
}
return "\4\3\2\2\1\1\1\1\0\0\0\0\0\0\0"[n] + zeroes;
}
@ -95,9 +107,18 @@ ABSL_BASE_INTERNAL_FORCEINLINE int CountLeadingZeros64(uint64_t n) {
ABSL_BASE_INTERNAL_FORCEINLINE int CountLeadingZeros32Slow(uint64_t n) {
int zeroes = 28;
if (n >> 16) zeroes -= 16, n >>= 16;
if (n >> 8) zeroes -= 8, n >>= 8;
if (n >> 4) zeroes -= 4, n >>= 4;
if (n >> 16) {
zeroes -= 16;
n >>= 16;
}
if (n >> 8) {
zeroes -= 8;
n >>= 8;
}
if (n >> 4) {
zeroes -= 4;
n >>= 4;
}
return "\4\3\2\2\1\1\1\1\0\0\0\0\0\0\0"[n] + zeroes;
}

6
absl/base/internal/periodic_sampler.cc
View file

@ -36,13 +36,13 @@ bool PeriodicSamplerBase::SubtleConfirmSample() noexcept {
// Check if this is the first call to Sample()
if (ABSL_PREDICT_FALSE(stride_ == 1)) {
stride_ = -1 - GetExponentialBiased(current_period);
if (stride_ < -1) {
stride_ = static_cast<uint64_t>(-1 - GetExponentialBiased(current_period));
if (static_cast<int64_t>(stride_) < -1) {
++stride_;
return false;
}
}
stride_ = -1 - GetExponentialBiased(current_period);
stride_ = static_cast<uint64_t>(-1 - GetExponentialBiased(current_period));
return true;
}

62
absl/base/internal/periodic_sampler.h
View file

@ -111,33 +111,49 @@ class PeriodicSamplerBase {
// Returns the current period of this sampler. Thread-safe.
virtual int period() const noexcept = 0;
int64_t stride_ = 0;
// Keep and decrement stride_ as an unsigned integer, but compare the value
// to zero casted as a signed int. clang and msvc do not create optimum code
// if we use signed for the combined decrement and sign comparison.
//
// Below 3 alternative options, all compiles generate the best code
// using the unsigned increment <---> signed int comparison option.
//
// Option 1:
// int64_t stride_;
// if (ABSL_PREDICT_TRUE(++stride_ < 0)) { ... }
//
// GCC x64 (OK) : https://gcc.godbolt.org/z/R5MzzA
// GCC ppc (OK) : https://gcc.godbolt.org/z/z7NZAt
// Clang x64 (BAD): https://gcc.godbolt.org/z/t4gPsd
// ICC x64 (OK) : https://gcc.godbolt.org/z/rE6s8W
// MSVC x64 (OK) : https://gcc.godbolt.org/z/ARMXqS
//
// Option 2:
// int64_t stride_ = 0;
// if (ABSL_PREDICT_TRUE(--stride_ >= 0)) { ... }
//
// GCC x64 (OK) : https://gcc.godbolt.org/z/jSQxYK
// GCC ppc (OK) : https://gcc.godbolt.org/z/VJdYaA
// Clang x64 (BAD): https://gcc.godbolt.org/z/Xm4NjX
// ICC x64 (OK) : https://gcc.godbolt.org/z/4snaFd
// MSVC x64 (BAD): https://gcc.godbolt.org/z/BgnEKE
//
// Option 3:
// uint64_t stride_;
// if (ABSL_PREDICT_TRUE(static_cast<int64_t>(++stride_) < 0)) { ... }
//
// GCC x64 (OK) : https://gcc.godbolt.org/z/bFbfPy
// GCC ppc (OK) : https://gcc.godbolt.org/z/S9KkUE
// Clang x64 (OK) : https://gcc.godbolt.org/z/UYzRb4
// ICC x64 (OK) : https://gcc.godbolt.org/z/ptTNfD
// MSVC x64 (OK) : https://gcc.godbolt.org/z/76j4-5
uint64_t stride_ = 0;
ExponentialBiased rng_;
};
inline bool PeriodicSamplerBase::SubtleMaybeSample() noexcept {
// We explicitly count up and not down, as the compiler does not generate
// ideal code for counting down. See also https://gcc.godbolt.org/z/FTPDSM
//
// With `if (ABSL_PREDICT_FALSE(++stride_ < 0))`
// add QWORD PTR fs:sampler@tpoff+8, 1
// jns .L15
// ret
//
// With `if (ABSL_PREDICT_FALSE(--stride_ > 0))`
// mov rax, QWORD PTR fs:sampler@tpoff+8
// sub rax, 1
// mov QWORD PTR fs:sampler@tpoff+8, rax
// test rax, rax
// jle .L15
// ret
// add QWORD PTR fs:sampler@tpoff+8, 1
// jns .L15
// ret
//
// --stride >= 0 does work, but makes our logic slightly harder as in that
// case we have less convenient zero-init and over-run values.
if (ABSL_PREDICT_FALSE(++stride_ < 0)) {
// See comments on `stride_` for the unsigned increment / signed compare.
if (ABSL_PREDICT_TRUE(static_cast<int64_t>(++stride_) < 0)) {
return false;
}
return true;

41
absl/flags/flag.h
View file

@ -96,8 +96,7 @@ class Flag {
constexpr Flag(const char* name, const flags_internal::HelpGenFunc help_gen,
const char* filename,
const flags_internal::FlagMarshallingOpFn marshalling_op,
const flags_internal::InitialValGenFunc initial_value_gen,
bool, void*)
const flags_internal::InitialValGenFunc initial_value_gen)
: name_(name),
help_gen_(help_gen),
filename_(filename),
@ -115,8 +114,11 @@ class Flag {
return impl_;
}
impl_ = new flags_internal::Flag<T>(name_, help_gen_, filename_,
marshalling_op_, initial_value_gen_);
impl_ = new flags_internal::Flag<T>(
name_,
{flags_internal::FlagHelpSrc(help_gen_),
flags_internal::FlagHelpSrcKind::kGenFunc},
filename_, marshalling_op_, initial_value_gen_);
inited_.store(true, std::memory_order_release);
}
@ -307,9 +309,19 @@ void SetFlag(absl::Flag<T>* flag, const V& v) {
#define ABSL_FLAG_IMPL_FLAGHELP(txt) txt
#endif
// AbslFlagHelpGenFor##name is used to encapsulate both immediate (method Const)
// and lazy (method NonConst) evaluation of help message expression. We choose
// between the two via the call to HelpArg in absl::Flag instantiation below.
// If help message expression is constexpr evaluable compiler will optimize
// away this whole struct.
#define ABSL_FLAG_IMPL_DECLARE_HELP_WRAPPER(name, txt) \
static std::string AbslFlagsWrapHelp##name() { \
return ABSL_FLAG_IMPL_FLAGHELP(txt); \
struct AbslFlagHelpGenFor##name { \
template <typename T = void> \
static constexpr const char* Const() { \
return absl::flags_internal::HelpConstexprWrap( \
ABSL_FLAG_IMPL_FLAGHELP(txt)); \
} \
static std::string NonConst() { return ABSL_FLAG_IMPL_FLAGHELP(txt); } \
}
#define ABSL_FLAG_IMPL_DECLARE_DEF_VAL_WRAPPER(name, Type, default_value) \
@ -326,28 +338,27 @@ void SetFlag(absl::Flag<T>* flag, const V& v) {
#define ABSL_FLAG_IMPL(Type, name, default_value, help) \
namespace absl /* block flags in namespaces */ {} \
ABSL_FLAG_IMPL_DECLARE_DEF_VAL_WRAPPER(name, Type, default_value) \
ABSL_FLAG_IMPL_DECLARE_HELP_WRAPPER(name, help) \
ABSL_FLAG_IMPL_DECLARE_HELP_WRAPPER(name, help); \
ABSL_CONST_INIT absl::Flag<Type> FLAGS_##name{ \
ABSL_FLAG_IMPL_FLAGNAME(#name), &AbslFlagsWrapHelp##name, \
ABSL_FLAG_IMPL_FLAGNAME(#name), \
absl::flags_internal::HelpArg<AbslFlagHelpGenFor##name>(0), \
ABSL_FLAG_IMPL_FILENAME(), \
&absl::flags_internal::FlagMarshallingOps<Type>, \
&AbslFlagsInitFlag##name}; \
extern bool FLAGS_no##name; \
bool FLAGS_no##name = ABSL_FLAG_IMPL_REGISTRAR(Type, FLAGS_##name)
#else
// MSVC version uses aggregate initialization.
// MSVC version uses aggregate initialization. We also do not try to
// optimize away help wrapper.
#define ABSL_FLAG_IMPL(Type, name, default_value, help) \
namespace absl /* block flags in namespaces */ {} \
ABSL_FLAG_IMPL_DECLARE_DEF_VAL_WRAPPER(name, Type, default_value) \
ABSL_FLAG_IMPL_DECLARE_HELP_WRAPPER(name, help) \
ABSL_FLAG_IMPL_DECLARE_HELP_WRAPPER(name, help); \
ABSL_CONST_INIT absl::Flag<Type> FLAGS_##name{ \
ABSL_FLAG_IMPL_FLAGNAME(#name), \
&AbslFlagsWrapHelp##name, \
ABSL_FLAG_IMPL_FLAGNAME(#name), &AbslFlagHelpGenFor##name::NonConst, \
ABSL_FLAG_IMPL_FILENAME(), \
&absl::flags_internal::FlagMarshallingOps<Type>, \
&AbslFlagsInitFlag##name, \
false, \
nullptr}; \
&AbslFlagsInitFlag##name}; \
extern bool FLAGS_no##name; \
bool FLAGS_no##name = ABSL_FLAG_IMPL_REGISTRAR(Type, FLAGS_##name)
#endif

17
absl/flags/flag_test.cc
View file

@ -32,7 +32,7 @@ namespace {
namespace flags = absl::flags_internal;
std::string TestHelpMsg() { return "help"; }
std::string TestHelpMsg() { return "dynamic help"; }
template <typename T>
void* TestMakeDflt() {
return new T{};
@ -41,19 +41,22 @@ void TestCallback() {}
template <typename T>
bool TestConstructionFor() {
constexpr flags::Flag<T> f1("f1", &TestHelpMsg, "file",
constexpr flags::HelpInitArg help_arg{flags::FlagHelpSrc("literal help"),
flags::FlagHelpSrcKind::kLiteral};
constexpr flags::Flag<T> f1("f1", help_arg, "file",
&flags::FlagMarshallingOps<T>, &TestMakeDflt<T>);
EXPECT_EQ(f1.Name(), "f1");
EXPECT_EQ(f1.Help(), "help");
EXPECT_EQ(f1.Help(), "literal help");
EXPECT_EQ(f1.Filename(), "file");
ABSL_CONST_INIT static flags::Flag<T> f2("f2", &TestHelpMsg, "file",
&flags::FlagMarshallingOps<T>,
&TestMakeDflt<T>);
ABSL_CONST_INIT static flags::Flag<T> f2(
"f2",
{flags::FlagHelpSrc(&TestHelpMsg), flags::FlagHelpSrcKind::kGenFunc},
"file", &flags::FlagMarshallingOps<T>, &TestMakeDflt<T>);
flags::FlagRegistrar<T, false>(&f2).OnUpdate(TestCallback);
EXPECT_EQ(f2.Name(), "f2");
EXPECT_EQ(f2.Help(), "help");
EXPECT_EQ(f2.Help(), "dynamic help");
EXPECT_EQ(f2.Filename(), "file");
return true;

7
absl/flags/internal/commandlineflag.cc
View file

@ -56,12 +56,5 @@ std::string CommandLineFlag::Filename() const {
return flags_internal::GetUsageConfig().normalize_filename(filename_);
}
std::string HelpText::GetHelpText() const {
if (help_function_) return help_function_();
if (help_message_) return help_message_;
return {};
}
} // namespace flags_internal
} // namespace absl

47
absl/flags/internal/commandlineflag.h
View file

@ -60,14 +60,6 @@ enum ValueSource {
kProgrammaticChange,
};
// Signature for the help generation function used as an argument for the
// absl::Flag constructor.
using HelpGenFunc = std::string (*)();
// Signature for the function generating the initial flag value based (usually
// based on default value supplied in flag's definition)
using InitialValGenFunc = void* (*)();
extern const char kStrippedFlagHelp[];
// The per-type function
@ -149,34 +141,6 @@ inline size_t Sizeof(FlagOpFn op) {
op(flags_internal::kSizeof, nullptr, nullptr)));
}
// Holds either a pointer to help text or a function which produces it. This is
// needed for supporting both static initialization of Flags while supporting
// the legacy registration framework. We can't use absl::variant<const char*,
// const char*(*)()> since anybody passing 0 or nullptr in to a CommandLineFlag
// would find an ambiguity.
class HelpText {
public:
static constexpr HelpText FromFunctionPointer(const HelpGenFunc fn) {
return HelpText(fn, nullptr);
}
static constexpr HelpText FromStaticCString(const char* msg) {
return HelpText(nullptr, msg);
}
std::string GetHelpText() const;
HelpText() = delete;
HelpText(const HelpText&) = default;
HelpText(HelpText&&) = default;
private:
explicit constexpr HelpText(const HelpGenFunc fn, const char* msg)
: help_function_(fn), help_message_(msg) {}
HelpGenFunc help_function_;
const char* help_message_;
};
// Handle to FlagState objects. Specific flag state objects will restore state
// of a flag produced this flag state from method CommandLineFlag::SaveState().
class FlagStateInterface {
@ -190,9 +154,8 @@ class FlagStateInterface {
// Holds all information for a flag.
class CommandLineFlag {
public:
constexpr CommandLineFlag(const char* name, HelpText help_text,
const char* filename)
: name_(name), help_(help_text), filename_(filename) {}
constexpr CommandLineFlag(const char* name, const char* filename)
: name_(name), filename_(filename) {}
// Virtual destructor
virtual void Destroy() const = 0;
@ -203,7 +166,6 @@ class CommandLineFlag {
// Non-polymorphic access methods.
absl::string_view Name() const { return name_; }
std::string Help() const { return help_.GetHelpText(); }
absl::string_view Typename() const;
std::string Filename() const;
@ -250,6 +212,8 @@ class CommandLineFlag {
// Polymorphic access methods
// Returns help message associated with this flag
virtual std::string Help() const = 0;
// Returns true iff this object corresponds to retired flag
virtual bool IsRetired() const { return false; }
// Returns true iff this is a handle to an Abseil Flag.
@ -285,12 +249,11 @@ class CommandLineFlag {
// flag's value type.
virtual void CheckDefaultValueParsingRoundtrip() const = 0;
// Constant configuration for a particular flag.
protected:
~CommandLineFlag() = default;
// Constant configuration for a particular flag.
const char* const name_; // Flags name passed to ABSL_FLAG as second arg.
const HelpText help_; // The function generating help message.
const char* const filename_; // The file name where ABSL_FLAG resides.
private:

5
absl/flags/internal/flag.cc
View file

@ -85,6 +85,11 @@ void FlagImpl::Destroy() const {
delete locks_;
}
std::string FlagImpl::Help() const {
return help_source_kind_ == FlagHelpSrcKind::kLiteral ? help_.literal
: help_.gen_func();
}
bool FlagImpl::IsModified() const {
absl::MutexLock l(DataGuard());
return modified_;

89
absl/flags/internal/flag.h
View file

@ -61,6 +61,68 @@ class FlagState : public flags_internal::FlagStateInterface {
int64_t counter_;
};
// This is help argument for absl::Flag encapsulating the string literal pointer
// or pointer to function generating it as well as enum descriminating two
// cases.
using HelpGenFunc = std::string (*)();
union FlagHelpSrc {
constexpr explicit FlagHelpSrc(const char* help_msg) : literal(help_msg) {}
constexpr explicit FlagHelpSrc(HelpGenFunc help_gen) : gen_func(help_gen) {}
const char* literal;
HelpGenFunc gen_func;
};
enum class FlagHelpSrcKind : int8_t { kLiteral, kGenFunc };
struct HelpInitArg {
FlagHelpSrc source;
FlagHelpSrcKind kind;
};
// HelpConstexprWrap is used by struct AbslFlagHelpGenFor##name generated by
// ABSL_FLAG macro. It is only used to silence the compiler in the case where
// help message expression is not constexpr and does not have type const char*.
// If help message expression is indeed constexpr const char* HelpConstexprWrap
// is just a trivial identity function.
template <typename T>
const char* HelpConstexprWrap(const T&) {
return nullptr;
}
constexpr const char* HelpConstexprWrap(const char* p) { return p; }
constexpr const char* HelpConstexprWrap(char* p) { return p; }
// These two HelpArg overloads allows us to select at compile time one of two
// way to pass Help argument to absl::Flag. We'll be passing
// AbslFlagHelpGenFor##name as T and integer 0 as a single argument to prefer
// first overload if possible. If T::Const is evaluatable on constexpr
// context (see non template int parameter below) we'll choose first overload.
// In this case the help message expression is immediately evaluated and is used
// to construct the absl::Flag. No additionl code is generated by ABSL_FLAG.
// Otherwise SFINAE kicks in and first overload is dropped from the
// consideration, in which case the second overload will be used. The second
// overload does not attempt to evaluate the help message expression
// immediately and instead delays the evaluation by returing the function
// pointer (&T::NonConst) genering the help message when necessary. This is
// evaluatable in constexpr context, but the cost is an extra function being
// generated in the ABSL_FLAG code.
template <typename T, int = (T::Const(), 1)>
constexpr flags_internal::HelpInitArg HelpArg(int) {
return {flags_internal::FlagHelpSrc(T::Const()),
flags_internal::FlagHelpSrcKind::kLiteral};
}
template <typename T>
constexpr flags_internal::HelpInitArg HelpArg(char) {
return {flags_internal::FlagHelpSrc(&T::NonConst),
flags_internal::FlagHelpSrcKind::kGenFunc};
}
// Signature for the function generating the initial flag value based (usually
// based on default value supplied in flag's definition)
using InitialValGenFunc = void* (*)();
// Signature for the mutation callback used by watched Flags
// The callback is noexcept.
// TODO(rogeeff): add noexcept after C++17 support is added.
@ -74,15 +136,19 @@ class FlagImpl {
public:
constexpr FlagImpl(const flags_internal::FlagOpFn op,
const flags_internal::FlagMarshallingOpFn marshalling_op,
const flags_internal::InitialValGenFunc initial_value_gen)
const flags_internal::InitialValGenFunc initial_value_gen,
const HelpInitArg help)
: op_(op),
marshalling_op_(marshalling_op),
initial_value_gen_(initial_value_gen) {}
initial_value_gen_(initial_value_gen),
help_(help.source),
help_source_kind_(help.kind) {}
// Forces destruction of the Flag's data.
void Destroy() const;
// Constant access methods
std::string Help() const;
bool IsModified() const ABSL_LOCKS_EXCLUDED(locks_->primary_mu);
bool IsSpecifiedOnCommandLine() const ABSL_LOCKS_EXCLUDED(locks_->primary_mu);
std::string DefaultValue() const ABSL_LOCKS_EXCLUDED(locks_->primary_mu);
@ -149,9 +215,12 @@ class FlagImpl {
absl::Mutex* DataGuard() const ABSL_LOCK_RETURNED(locks_->primary_mu);
// Immutable Flag's data.
const FlagOpFn op_; // Type-specific handler
const FlagMarshallingOpFn marshalling_op_; // Marshalling ops handler
const InitialValGenFunc initial_value_gen_; // Makes flag's initial value
const FlagOpFn op_; // Type-specific handler.
const FlagMarshallingOpFn marshalling_op_; // Marshalling ops handler.
const InitialValGenFunc initial_value_gen_; // Makes flag's initial value.
const FlagHelpSrc help_; // Help message literal or function to generate it.
// Indicates if help message was supplied as literal or generator func.
const FlagHelpSrcKind help_source_kind_;
// Mutable Flag's data. (guarded by locks_->primary_mu).
// Indicates that locks_, cur_ and def_ fields have been lazily initialized.
@ -191,14 +260,13 @@ class FlagImpl {
template <typename T>
class Flag final : public flags_internal::CommandLineFlag {
public:
constexpr Flag(const char* name, const flags_internal::HelpGenFunc help_gen,
constexpr Flag(const char* name, const flags_internal::HelpInitArg help,
const char* filename,
const flags_internal::FlagMarshallingOpFn marshalling_op,
const flags_internal::InitialValGenFunc initial_value_gen)
: flags_internal::CommandLineFlag(
name, flags_internal::HelpText::FromFunctionPointer(help_gen),
filename),
impl_(&flags_internal::FlagOps<T>, marshalling_op, initial_value_gen) {}
: flags_internal::CommandLineFlag(name, filename),
impl_(&flags_internal::FlagOps<T>, marshalling_op, initial_value_gen,
help) {}
T Get() const {
// See implementation notes in CommandLineFlag::Get().
@ -222,6 +290,7 @@ class Flag final : public flags_internal::CommandLineFlag {
}
// CommandLineFlag interface
std::string Help() const override { return impl_.Help(); }
bool IsModified() const override { return impl_.IsModified(); }
bool IsSpecifiedOnCommandLine() const override {
return impl_.IsSpecifiedOnCommandLine();

4
absl/flags/internal/registry.cc
View file

@ -276,8 +276,7 @@ namespace {
class RetiredFlagObj final : public flags_internal::CommandLineFlag {
public:
constexpr RetiredFlagObj(const char* name, FlagOpFn ops)
: flags_internal::CommandLineFlag(
name, flags_internal::HelpText::FromStaticCString(nullptr),
: flags_internal::CommandLineFlag(name,
/*filename=*/"RETIRED"),
op_(ops) {}
@ -288,6 +287,7 @@ class RetiredFlagObj final : public flags_internal::CommandLineFlag {
}
flags_internal::FlagOpFn TypeId() const override { return op_; }
std::string Help() const override { return ""; }
bool IsRetired() const override { return true; }
bool IsModified() const override { return false; }
bool IsSpecifiedOnCommandLine() const override { return false; }

129
absl/numeric/int128.cc
View file

@ -244,6 +244,111 @@ std::ostream& operator<<(std::ostream& os, uint128 v) {
return os << rep;
}
namespace {
uint128 UnsignedAbsoluteValue(int128 v) {
// Cast to uint128 before possibly negating because -Int128Min() is undefined.
return Int128High64(v) < 0 ? -uint128(v) : uint128(v);
}
} // namespace
#if !defined(ABSL_HAVE_INTRINSIC_INT128)
namespace {
template <typename T>
int128 MakeInt128FromFloat(T v) {
// Conversion when v is NaN or cannot fit into int128 would be undefined
// behavior if using an intrinsic 128-bit integer.
assert(std::isfinite(v) && (std::numeric_limits<T>::max_exponent <= 127 ||
(v >= -std::ldexp(static_cast<T>(1), 127) &&
v < std::ldexp(static_cast<T>(1), 127))));
// We must convert the absolute value and then negate as needed, because
// floating point types are typically sign-magnitude. Otherwise, the
// difference between the high and low 64 bits when interpreted as two's
// complement overwhelms the precision of the mantissa.
uint128 result = v < 0 ? -MakeUint128FromFloat(-v) : MakeUint128FromFloat(v);
return MakeInt128(int128_internal::BitCastToSigned(Uint128High64(result)),
Uint128Low64(result));
}
} // namespace
int128::int128(float v) : int128(MakeInt128FromFloat(v)) {}
int128::int128(double v) : int128(MakeInt128FromFloat(v)) {}
int128::int128(long double v) : int128(MakeInt128FromFloat(v)) {}
int128 operator/(int128 lhs, int128 rhs) {
assert(lhs != Int128Min() || rhs != -1); // UB on two's complement.
uint128 quotient = 0;
uint128 remainder = 0;
DivModImpl(UnsignedAbsoluteValue(lhs), UnsignedAbsoluteValue(rhs),
&quotient, &remainder);
if ((Int128High64(lhs) < 0) != (Int128High64(rhs) < 0)) quotient = -quotient;
return MakeInt128(int128_internal::BitCastToSigned(Uint128High64(quotient)),
Uint128Low64(quotient));
}
int128 operator%(int128 lhs, int128 rhs) {
assert(lhs != Int128Min() || rhs != -1); // UB on two's complement.
uint128 quotient = 0;
uint128 remainder = 0;
DivModImpl(UnsignedAbsoluteValue(lhs), UnsignedAbsoluteValue(rhs),
&quotient, &remainder);
if (Int128High64(lhs) < 0) remainder = -remainder;
return MakeInt128(int128_internal::BitCastToSigned(Uint128High64(remainder)),
Uint128Low64(remainder));
}
#endif // ABSL_HAVE_INTRINSIC_INT128
std::ostream& operator<<(std::ostream& os, int128 v) {
std::ios_base::fmtflags flags = os.flags();
std::string rep;
// Add the sign if needed.
bool print_as_decimal =
(flags & std::ios::basefield) == std::ios::dec ||
(flags & std::ios::basefield) == std::ios_base::fmtflags();
if (print_as_decimal) {
if (Int128High64(v) < 0) {
rep = "-";
} else if (flags & std::ios::showpos) {
rep = "+";
}
}
rep.append(Uint128ToFormattedString(
print_as_decimal ? UnsignedAbsoluteValue(v) : uint128(v), os.flags()));
// Add the requisite padding.
std::streamsize width = os.width(0);
if (static_cast<size_t>(width) > rep.size()) {
switch (flags & std::ios::adjustfield) {
case std::ios::left:
rep.append(width - rep.size(), os.fill());
break;
case std::ios::internal:
if (print_as_decimal && (rep[0] == '+' || rep[0] == '-')) {
rep.insert(1, width - rep.size(), os.fill());
} else if ((flags & std::ios::basefield) == std::ios::hex &&
(flags & std::ios::showbase) && v != 0) {
rep.insert(2, width - rep.size(), os.fill());
} else {
rep.insert(0, width - rep.size(), os.fill());
}
break;
default: // std::ios::right
rep.insert(0, width - rep.size(), os.fill());
break;
}
}
return os << rep;
}
} // namespace absl
namespace std {
@ -270,4 +375,28 @@ constexpr int numeric_limits<absl::uint128>::max_exponent;
constexpr int numeric_limits<absl::uint128>::max_exponent10;
constexpr bool numeric_limits<absl::uint128>::traps;
constexpr bool numeric_limits<absl::uint128>::tinyness_before;
constexpr bool numeric_limits<absl::int128>::is_specialized;
constexpr bool numeric_limits<absl::int128>::is_signed;
constexpr bool numeric_limits<absl::int128>::is_integer;
constexpr bool numeric_limits<absl::int128>::is_exact;
constexpr bool numeric_limits<absl::int128>::has_infinity;
constexpr bool numeric_limits<absl::int128>::has_quiet_NaN;
constexpr bool numeric_limits<absl::int128>::has_signaling_NaN;
constexpr float_denorm_style numeric_limits<absl::int128>::has_denorm;
constexpr bool numeric_limits<absl::int128>::has_denorm_loss;
constexpr float_round_style numeric_limits<absl::int128>::round_style;
constexpr bool numeric_limits<absl::int128>::is_iec559;
constexpr bool numeric_limits<absl::int128>::is_bounded;
constexpr bool numeric_limits<absl::int128>::is_modulo;
constexpr int numeric_limits<absl::int128>::digits;
constexpr int numeric_limits<absl::int128>::digits10;
constexpr int numeric_limits<absl::int128>::max_digits10;
constexpr int numeric_limits<absl::int128>::radix;
constexpr int numeric_limits<absl::int128>::min_exponent;
constexpr int numeric_limits<absl::int128>::min_exponent10;
constexpr int numeric_limits<absl::int128>::max_exponent;
constexpr int numeric_limits<absl::int128>::max_exponent10;
constexpr bool numeric_limits<absl::int128>::traps;
constexpr bool numeric_limits<absl::int128>::tinyness_before;
} // namespace std

363
absl/numeric/int128.h
View file

@ -17,10 +17,7 @@
// File: int128.h
// -----------------------------------------------------------------------------
//
// This header file defines 128-bit integer types.
//
// Currently, this file defines `uint128`, an unsigned 128-bit integer;
// a signed 128-bit integer is forthcoming.
// This header file defines 128-bit integer types, `uint128` and `int128`.
#ifndef ABSL_NUMERIC_INT128_H_
#define ABSL_NUMERIC_INT128_H_
@ -53,6 +50,8 @@
namespace absl {
class int128;
// uint128
//
// An unsigned 128-bit integer type. The API is meant to mimic an intrinsic type
@ -116,6 +115,7 @@ class
constexpr uint128(__int128 v); // NOLINT(runtime/explicit)
constexpr uint128(unsigned __int128 v); // NOLINT(runtime/explicit)
#endif // ABSL_HAVE_INTRINSIC_INT128
constexpr uint128(int128 v); // NOLINT(runtime/explicit)
explicit uint128(float v);
explicit uint128(double v);
explicit uint128(long double v);
@ -131,6 +131,7 @@ class
uint128& operator=(__int128 v);
uint128& operator=(unsigned __int128 v);
#endif // ABSL_HAVE_INTRINSIC_INT128
uint128& operator=(int128 v);
// Conversion operators to other arithmetic types
constexpr explicit operator bool() const;
@ -291,7 +292,238 @@ class numeric_limits<absl::uint128> {
};
} // namespace std
// TODO(absl-team): Implement signed 128-bit type
namespace absl {
// int128
//
// A signed 128-bit integer type. The API is meant to mimic an intrinsic
// integral type as closely as is practical, including exhibiting undefined
// behavior in analogous cases (e.g. division by zero).
//
// An `int128` supports the following:
//
// * Implicit construction from integral types
// * Explicit conversion to integral types
//
// However, an `int128` differs from intrinsic integral types in the following
// ways:
//
// * It is not implicitly convertible to other integral types.
// * Requires explicit construction from and conversion to floating point
// types.
// Additionally, if your compiler supports `__int128`, `int128` is
// interoperable with that type. (Abseil checks for this compatibility through
// the `ABSL_HAVE_INTRINSIC_INT128` macro.)
//
// The design goal for `int128` is that it will be compatible with a future
// `int128_t`, if that type becomes a part of the standard.
//
// Example:
//
// float y = absl::int128(17); // Error. int128 cannot be implicitly
// // converted to float.
//
// absl::int128 v;
// int64_t i = v; // Error
// int64_t i = static_cast<int64_t>(v); // OK
//
class int128 {
public:
int128() = default;
// Constructors from arithmetic types
constexpr int128(int v); // NOLINT(runtime/explicit)
constexpr int128(unsigned int v); // NOLINT(runtime/explicit)
constexpr int128(long v); // NOLINT(runtime/int)
constexpr int128(unsigned long v); // NOLINT(runtime/int)
constexpr int128(long long v); // NOLINT(runtime/int)
constexpr int128(unsigned long long v); // NOLINT(runtime/int)
#ifdef ABSL_HAVE_INTRINSIC_INT128
constexpr int128(__int128 v); // NOLINT(runtime/explicit)
constexpr explicit int128(unsigned __int128 v);
#endif // ABSL_HAVE_INTRINSIC_INT128
constexpr explicit int128(uint128 v);
explicit int128(float v);
explicit int128(double v);
explicit int128(long double v);
// Assignment operators from arithmetic types
int128& operator=(int v);
int128& operator=(unsigned int v);
int128& operator=(long v); // NOLINT(runtime/int)
int128& operator=(unsigned long v); // NOLINT(runtime/int)
int128& operator=(long long v); // NOLINT(runtime/int)
int128& operator=(unsigned long long v); // NOLINT(runtime/int)
#ifdef ABSL_HAVE_INTRINSIC_INT128
int128& operator=(__int128 v);
#endif // ABSL_HAVE_INTRINSIC_INT128
// Conversion operators to other arithmetic types
constexpr explicit operator bool() const;
constexpr explicit operator char() const;
constexpr explicit operator signed char() const;
constexpr explicit operator unsigned char() const;
constexpr explicit operator char16_t() const;
constexpr explicit operator char32_t() const;
constexpr explicit operator ABSL_INTERNAL_WCHAR_T() const;
constexpr explicit operator short() const; // NOLINT(runtime/int)
// NOLINTNEXTLINE(runtime/int)
constexpr explicit operator unsigned short() const;
constexpr explicit operator int() const;
constexpr explicit operator unsigned int() const;
constexpr explicit operator long() const; // NOLINT(runtime/int)
// NOLINTNEXTLINE(runtime/int)
constexpr explicit operator unsigned long() const;
// NOLINTNEXTLINE(runtime/int)
constexpr explicit operator long long() const;
// NOLINTNEXTLINE(runtime/int)
constexpr explicit operator unsigned long long() const;
#ifdef ABSL_HAVE_INTRINSIC_INT128
constexpr explicit operator __int128() const;
constexpr explicit operator unsigned __int128() const;
#endif // ABSL_HAVE_INTRINSIC_INT128
explicit operator float() const;
explicit operator double() const;
explicit operator long double() const;
// Trivial copy constructor, assignment operator and destructor.
// Arithmetic operators
int128& operator+=(int128 other);
int128& operator-=(int128 other);
int128& operator*=(int128 other);
int128& operator/=(int128 other);
int128& operator%=(int128 other);
int128 operator++(int); // postfix increment: i++
int128 operator--(int); // postfix decrement: i--
int128& operator++(); // prefix increment: ++i
int128& operator--(); // prefix decrement: --i
int128& operator&=(int128 other);
int128& operator|=(int128 other);
int128& operator^=(int128 other);
int128& operator<<=(int amount);
int128& operator>>=(int amount);
// Int128Low64()
//
// Returns the lower 64-bit value of a `int128` value.
friend constexpr uint64_t Int128Low64(int128 v);
// Int128High64()
//
// Returns the higher 64-bit value of a `int128` value.
friend constexpr int64_t Int128High64(int128 v);
// MakeInt128()
//
// Constructs a `int128` numeric value from two 64-bit integers. Note that
// signedness is conveyed in the upper `high` value.
//
// (absl::int128(1) << 64) * high + low
//
// Note that this factory function is the only way to construct a `int128`
// from integer values greater than 2^64 or less than -2^64.
//
// Example:
//
// absl::int128 big = absl::MakeInt128(1, 0);
// absl::int128 big_n = absl::MakeInt128(-1, 0);
friend constexpr int128 MakeInt128(int64_t high, uint64_t low);
// Int128Max()
//
// Returns the maximum value for a 128-bit signed integer.
friend constexpr int128 Int128Max();
// Int128Min()
//
// Returns the minimum value for a 128-bit signed integer.
friend constexpr int128 Int128Min();
// Support for absl::Hash.
template <typename H>
friend H AbslHashValue(H h, int128 v) {
return H::combine(std::move(h), Int128High64(v), Int128Low64(v));
}
private:
constexpr int128(int64_t high, uint64_t low);
#if defined(ABSL_HAVE_INTRINSIC_INT128)
__int128 v_;
#else // ABSL_HAVE_INTRINSIC_INT128
#if defined(ABSL_IS_LITTLE_ENDIAN)
uint64_t lo_;
int64_t hi_;
#elif defined(ABSL_IS_BIG_ENDIAN)
int64_t hi_;
uint64_t lo_;
#else // byte order
#error "Unsupported byte order: must be little-endian or big-endian."
#endif // byte order
#endif // ABSL_HAVE_INTRINSIC_INT128
};
std::ostream& operator<<(std::ostream& os, int128 v);
// TODO(absl-team) add operator>>(std::istream&, int128)
constexpr int128 Int128Max() {
return int128((std::numeric_limits<int64_t>::max)(),
(std::numeric_limits<uint64_t>::max)());
}
constexpr int128 Int128Min() {
return int128((std::numeric_limits<int64_t>::min)(), 0);
}
} // namespace absl
// Specialized numeric_limits for int128.
namespace std {
template <>
class numeric_limits<absl::int128> {
public:
static constexpr bool is_specialized = true;
static constexpr bool is_signed = true;
static constexpr bool is_integer = true;
static constexpr bool is_exact = true;
static constexpr bool has_infinity = false;
static constexpr bool has_quiet_NaN = false;
static constexpr bool has_signaling_NaN = false;
static constexpr float_denorm_style has_denorm = denorm_absent;
static constexpr bool has_denorm_loss = false;
static constexpr float_round_style round_style = round_toward_zero;
static constexpr bool is_iec559 = false;
static constexpr bool is_bounded = true;
static constexpr bool is_modulo = false;
static constexpr int digits = 127;
static constexpr int digits10 = 38;
static constexpr int max_digits10 = 0;
static constexpr int radix = 2;
static constexpr int min_exponent = 0;
static constexpr int min_exponent10 = 0;
static constexpr int max_exponent = 0;
static constexpr int max_exponent10 = 0;
#ifdef ABSL_HAVE_INTRINSIC_INT128
static constexpr bool traps = numeric_limits<__int128>::traps;
#else // ABSL_HAVE_INTRINSIC_INT128
static constexpr bool traps = numeric_limits<uint64_t>::traps;
#endif // ABSL_HAVE_INTRINSIC_INT128
static constexpr bool tinyness_before = false;
static constexpr absl::int128 (min)() { return absl::Int128Min(); }
static constexpr absl::int128 lowest() { return absl::Int128Min(); }
static constexpr absl::int128 (max)() { return absl::Int128Max(); }
static constexpr absl::int128 epsilon() { return 0; }
static constexpr absl::int128 round_error() { return 0; }
static constexpr absl::int128 infinity() { return 0; }
static constexpr absl::int128 quiet_NaN() { return 0; }
static constexpr absl::int128 signaling_NaN() { return 0; }
static constexpr absl::int128 denorm_min() { return 0; }
};
} // namespace std
// --------------------------------------------------------------------------
// Implementation details follow
@ -339,6 +571,10 @@ inline uint128& uint128::operator=(unsigned __int128 v) {
}
#endif // ABSL_HAVE_INTRINSIC_INT128
inline uint128& uint128::operator=(int128 v) {
return *this = uint128(v);
}
// Arithmetic operators.
uint128 operator<<(uint128 lhs, int amount);
@ -420,6 +656,9 @@ constexpr uint128::uint128(unsigned __int128 v)
hi_{static_cast<uint64_t>(v >> 64)} {}
#endif // ABSL_HAVE_INTRINSIC_INT128
constexpr uint128::uint128(int128 v)
: lo_{Int128Low64(v)}, hi_{static_cast<uint64_t>(Int128High64(v))} {}
#elif defined(ABSL_IS_BIG_ENDIAN)
constexpr uint128::uint128(uint64_t high, uint64_t low)
@ -450,6 +689,9 @@ constexpr uint128::uint128(unsigned __int128 v)
lo_{static_cast<uint64_t>(v & ~uint64_t{0})} {}
#endif // ABSL_HAVE_INTRINSIC_INT128
constexpr uint128::uint128(int128 v)
: hi_{static_cast<uint64_t>(Int128High64(v))}, lo_{Int128Low64(v)} {}
#else // byte order
#error "Unsupported byte order: must be little-endian or big-endian."
#endif // byte order
@ -719,6 +961,117 @@ inline uint128& uint128::operator--() {
return *this;
}
constexpr int128 MakeInt128(int64_t high, uint64_t low) {
return int128(high, low);
}
// Assignment from integer types.
inline int128& int128::operator=(int v) {
return *this = int128(v);
}
inline int128& int128::operator=(unsigned int v) {
return *this = int128(v);
}
inline int128& int128::operator=(long v) { // NOLINT(runtime/int)
return *this = int128(v);
}
// NOLINTNEXTLINE(runtime/int)
inline int128& int128::operator=(unsigned long v) {
return *this = int128(v);
}
// NOLINTNEXTLINE(runtime/int)
inline int128& int128::operator=(long long v) {
return *this = int128(v);
}
// NOLINTNEXTLINE(runtime/int)
inline int128& int128::operator=(unsigned long long v) {
return *this = int128(v);
}
// Arithmetic operators.
int128 operator+(int128 lhs, int128 rhs);
int128 operator-(int128 lhs, int128 rhs);
int128 operator*(int128 lhs, int128 rhs);
int128 operator/(int128 lhs, int128 rhs);
int128 operator%(int128 lhs, int128 rhs);
int128 operator|(int128 lhs, int128 rhs);
int128 operator&(int128 lhs, int128 rhs);
int128 operator^(int128 lhs, int128 rhs);
int128 operator<<(int128 lhs, int amount);
int128 operator>>(int128 lhs, int amount);
inline int128& int128::operator+=(int128 other) {
*this = *this + other;
return *this;
}
inline int128& int128::operator-=(int128 other) {
*this = *this - other;
return *this;
}
inline int128& int128::operator*=(int128 other) {
*this = *this * other;
return *this;
}
inline int128& int128::operator/=(int128 other) {
*this = *this / other;
return *this;
}
inline int128& int128::operator%=(int128 other) {
*this = *this % other;
return *this;
}
inline int128& int128::operator|=(int128 other) {
*this = *this | other;
return *this;
}
inline int128& int128::operator&=(int128 other) {
*this = *this & other;
return *this;
}
inline int128& int128::operator^=(int128 other) {
*this = *this ^ other;
return *this;
}
inline int128& int128::operator<<=(int amount) {
*this = *this << amount;
return *this;
}
inline int128& int128::operator>>=(int amount) {
*this = *this >> amount;
return *this;
}
namespace int128_internal {
// Casts from unsigned to signed while preserving the underlying binary
// representation.
constexpr int64_t BitCastToSigned(uint64_t v) {
// Casting an unsigned integer to a signed integer of the same
// width is implementation defined behavior if the source value would not fit
// in the destination type. We step around it with a roundtrip bitwise not
// operation to make sure this function remains constexpr. Clang, GCC, and
// MSVC optimize this to a no-op on x86-64.
return v & (uint64_t{1} << 63) ? ~static_cast<int64_t>(~v)
: static_cast<int64_t>(v);
}
} // namespace int128_internal
#if defined(ABSL_HAVE_INTRINSIC_INT128)
#include "absl/numeric/int128_have_intrinsic.inc" // IWYU pragma: export
#else // ABSL_HAVE_INTRINSIC_INT128

284
absl/numeric/int128_have_intrinsic.inc
View file

@ -16,3 +16,287 @@
// This file contains :int128 implementation details that depend on internal
// representation when ABSL_HAVE_INTRINSIC_INT128 is defined. This file is
// included by int128.h and relies on ABSL_INTERNAL_WCHAR_T being defined.
namespace int128_internal {
// Casts from unsigned to signed while preserving the underlying binary
// representation.
constexpr __int128 BitCastToSigned(unsigned __int128 v) {
// Casting an unsigned integer to a signed integer of the same
// width is implementation defined behavior if the source value would not fit
// in the destination type. We step around it with a roundtrip bitwise not
// operation to make sure this function remains constexpr. Clang and GCC
// optimize this to a no-op on x86-64.
return v & (static_cast<unsigned __int128>(1) << 127)
? ~static_cast<__int128>(~v)
: static_cast<__int128>(v);
}
} // namespace int128_internal
inline int128& int128::operator=(__int128 v) {
v_ = v;
return *this;
}
constexpr uint64_t Int128Low64(int128 v) {
return static_cast<uint64_t>(v.v_ & ~uint64_t{0});
}
constexpr int64_t Int128High64(int128 v) {
// Initially cast to unsigned to prevent a right shift on a negative value.
return int128_internal::BitCastToSigned(
static_cast<uint64_t>(static_cast<unsigned __int128>(v.v_) >> 64));
}
constexpr int128::int128(int64_t high, uint64_t low)
// Initially cast to unsigned to prevent a left shift that overflows.
: v_(int128_internal::BitCastToSigned(static_cast<unsigned __int128>(high)
<< 64) |
low) {}
constexpr int128::int128(int v) : v_{v} {}
constexpr int128::int128(long v) : v_{v} {} // NOLINT(runtime/int)
constexpr int128::int128(long long v) : v_{v} {} // NOLINT(runtime/int)
constexpr int128::int128(__int128 v) : v_{v} {}
constexpr int128::int128(unsigned int v) : v_{v} {}
constexpr int128::int128(unsigned long v) : v_{v} {} // NOLINT(runtime/int)
// NOLINTNEXTLINE(runtime/int)
constexpr int128::int128(unsigned long long v) : v_{v} {}
constexpr int128::int128(unsigned __int128 v) : v_{static_cast<__int128>(v)} {}
inline int128::int128(float v) {
v_ = static_cast<__int128>(v);
}
inline int128::int128(double v) {
v_ = static_cast<__int128>(v);
}
inline int128::int128(long double v) {
v_ = static_cast<__int128>(v);
}
constexpr int128::int128(uint128 v) : v_{static_cast<__int128>(v)} {}
constexpr int128::operator bool() const { return static_cast<bool>(v_); }
constexpr int128::operator char() const { return static_cast<char>(v_); }
constexpr int128::operator signed char() const {
return static_cast<signed char>(v_);
}
constexpr int128::operator unsigned char() const {
return static_cast<unsigned char>(v_);
}
constexpr int128::operator char16_t() const {
return static_cast<char16_t>(v_);
}
constexpr int128::operator char32_t() const {
return static_cast<char32_t>(v_);
}
constexpr int128::operator ABSL_INTERNAL_WCHAR_T() const {
return static_cast<ABSL_INTERNAL_WCHAR_T>(v_);
}
constexpr int128::operator short() const { // NOLINT(runtime/int)
return static_cast<short>(v_); // NOLINT(runtime/int)
}
constexpr int128::operator unsigned short() const { // NOLINT(runtime/int)
return static_cast<unsigned short>(v_); // NOLINT(runtime/int)
}
constexpr int128::operator int() const {
return static_cast<int>(v_);
}
constexpr int128::operator unsigned int() const {
return static_cast<unsigned int>(v_);
}
constexpr int128::operator long() const { // NOLINT(runtime/int)
return static_cast<long>(v_); // NOLINT(runtime/int)
}
constexpr int128::operator unsigned long() const { // NOLINT(runtime/int)
return static_cast<unsigned long>(v_); // NOLINT(runtime/int)
}
constexpr int128::operator long long() const { // NOLINT(runtime/int)
return static_cast<long long>(v_); // NOLINT(runtime/int)
}
constexpr int128::operator unsigned long long() const { // NOLINT(runtime/int)
return static_cast<unsigned long long>(v_); // NOLINT(runtime/int)
}
constexpr int128::operator __int128() const { return v_; }
constexpr int128::operator unsigned __int128() const {
return static_cast<unsigned __int128>(v_);
}
// Clang on PowerPC sometimes produces incorrect __int128 to floating point
// conversions. In that case, we do the conversion with a similar implementation
// to the conversion operators in int128_no_intrinsic.inc.
#if defined(__clang__) && !defined(__ppc64__)
inline int128::operator float() const { return static_cast<float>(v_); }
inline int128::operator double () const { return static_cast<double>(v_); }
inline int128::operator long double() const {
return static_cast<long double>(v_);
}
#else // Clang on PowerPC
// Forward declaration for conversion operators to floating point types.
int128 operator-(int128 v);
bool operator!=(int128 lhs, int128 rhs);
inline int128::operator float() const {
// We must convert the absolute value and then negate as needed, because
// floating point types are typically sign-magnitude. Otherwise, the
// difference between the high and low 64 bits when interpreted as two's
// complement overwhelms the precision of the mantissa.
//
// Also check to make sure we don't negate Int128Min()
return v_ < 0 && *this != Int128Min()
? -static_cast<float>(-*this)
: static_cast<float>(Int128Low64(*this)) +
std::ldexp(static_cast<float>(Int128High64(*this)), 64);
}
inline int128::operator double() const {
// See comment in int128::operator float() above.
return v_ < 0 && *this != Int128Min()
? -static_cast<double>(-*this)
: static_cast<double>(Int128Low64(*this)) +
std::ldexp(static_cast<double>(Int128High64(*this)), 64);
}
inline int128::operator long double() const {
// See comment in int128::operator float() above.
return v_ < 0 && *this != Int128Min()
? -static_cast<long double>(-*this)
: static_cast<long double>(Int128Low64(*this)) +
std::ldexp(static_cast<long double>(Int128High64(*this)),
64);
}
#endif // Clang on PowerPC
// Comparison operators.
inline bool operator==(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) == static_cast<__int128>(rhs);
}
inline bool operator!=(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) != static_cast<__int128>(rhs);
}
inline bool operator<(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) < static_cast<__int128>(rhs);
}
inline bool operator>(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) > static_cast<__int128>(rhs);
}
inline bool operator<=(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) <= static_cast<__int128>(rhs);
}
inline bool operator>=(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) >= static_cast<__int128>(rhs);
}
// Unary operators.
inline int128 operator-(int128 v) {
return -static_cast<__int128>(v);
}
inline bool operator!(int128 v) {
return !static_cast<__int128>(v);
}
inline int128 operator~(int128 val) {
return ~static_cast<__int128>(val);
}
// Arithmetic operators.
inline int128 operator+(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) + static_cast<__int128>(rhs);
}
inline int128 operator-(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) - static_cast<__int128>(rhs);
}
inline int128 operator*(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) * static_cast<__int128>(rhs);
}
inline int128 operator/(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) / static_cast<__int128>(rhs);
}
inline int128 operator%(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) % static_cast<__int128>(rhs);
}
inline int128 int128::operator++(int) {
int128 tmp(*this);
++v_;
return tmp;
}
inline int128 int128::operator--(int) {
int128 tmp(*this);
--v_;
return tmp;
}
inline int128& int128::operator++() {
++v_;
return *this;
}
inline int128& int128::operator--() {
--v_;
return *this;
}
inline int128 operator|(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) | static_cast<__int128>(rhs);
}
inline int128 operator&(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) & static_cast<__int128>(rhs);
}
inline int128 operator^(int128 lhs, int128 rhs) {
return static_cast<__int128>(lhs) ^ static_cast<__int128>(rhs);
}
inline int128 operator<<(int128 lhs, int amount) {
return static_cast<__int128>(lhs) << amount;
}
inline int128 operator>>(int128 lhs, int amount) {
return static_cast<__int128>(lhs) >> amount;
}

290
absl/numeric/int128_no_intrinsic.inc
View file

@ -16,3 +16,293 @@
// This file contains :int128 implementation details that depend on internal
// representation when ABSL_HAVE_INTRINSIC_INT128 is *not* defined. This file
// is included by int128.h and relies on ABSL_INTERNAL_WCHAR_T being defined.
constexpr uint64_t Int128Low64(int128 v) { return v.lo_; }
constexpr int64_t Int128High64(int128 v) { return v.hi_; }
#if defined(ABSL_IS_LITTLE_ENDIAN)
constexpr int128::int128(int64_t high, uint64_t low) :
lo_(low), hi_(high) {}
constexpr int128::int128(int v)
: lo_{static_cast<uint64_t>(v)}, hi_{v < 0 ? ~int64_t{0} : 0} {}
constexpr int128::int128(long v) // NOLINT(runtime/int)
: lo_{static_cast<uint64_t>(v)}, hi_{v < 0 ? ~int64_t{0} : 0} {}
constexpr int128::int128(long long v) // NOLINT(runtime/int)
: lo_{static_cast<uint64_t>(v)}, hi_{v < 0 ? ~int64_t{0} : 0} {}
constexpr int128::int128(unsigned int v) : lo_{v}, hi_{0} {}
// NOLINTNEXTLINE(runtime/int)
constexpr int128::int128(unsigned long v) : lo_{v}, hi_{0} {}
// NOLINTNEXTLINE(runtime/int)
constexpr int128::int128(unsigned long long v) : lo_{v}, hi_{0} {}
constexpr int128::int128(uint128 v)
: lo_{Uint128Low64(v)}, hi_{static_cast<int64_t>(Uint128High64(v))} {}
#elif defined(ABSL_IS_BIG_ENDIAN)
constexpr int128::int128(int64_t high, uint64_t low) :
hi_{high}, lo_{low} {}
constexpr int128::int128(int v)
: hi_{v < 0 ? ~int64_t{0} : 0}, lo_{static_cast<uint64_t>(v)} {}
constexpr int128::int128(long v) // NOLINT(runtime/int)
: hi_{v < 0 ? ~int64_t{0} : 0}, lo_{static_cast<uint64_t>(v)} {}
constexpr int128::int128(long long v) // NOLINT(runtime/int)
: hi_{v < 0 ? ~int64_t{0} : 0}, lo_{static_cast<uint64_t>(v)} {}
constexpr int128::int128(unsigned int v) : hi_{0}, lo_{v} {}
// NOLINTNEXTLINE(runtime/int)
constexpr int128::int128(unsigned long v) : hi_{0}, lo_{v} {}
// NOLINTNEXTLINE(runtime/int)
constexpr int128::int128(unsigned long long v) : hi_{0}, lo_{v} {}
constexpr int128::int128(uint128 v)
: hi_{static_cast<int64_t>(Uint128High64(v))}, lo_{Uint128Low64(v)} {}
#else // byte order
#error "Unsupported byte order: must be little-endian or big-endian."
#endif // byte order
constexpr int128::operator bool() const { return lo_ || hi_; }
constexpr int128::operator char() const {
// NOLINTNEXTLINE(runtime/int)
return static_cast<char>(static_cast<long long>(*this));
}
constexpr int128::operator signed char() const {
// NOLINTNEXTLINE(runtime/int)
return static_cast<signed char>(static_cast<long long>(*this));
}
constexpr int128::operator unsigned char() const {
return static_cast<unsigned char>(lo_);
}
constexpr int128::operator char16_t() const {
return static_cast<char16_t>(lo_);
}
constexpr int128::operator char32_t() const {
return static_cast<char32_t>(lo_);
}
constexpr int128::operator ABSL_INTERNAL_WCHAR_T() const {
// NOLINTNEXTLINE(runtime/int)
return static_cast<ABSL_INTERNAL_WCHAR_T>(static_cast<long long>(*this));
}
constexpr int128::operator short() const { // NOLINT(runtime/int)
// NOLINTNEXTLINE(runtime/int)
return static_cast<short>(static_cast<long long>(*this));
}
constexpr int128::operator unsigned short() const { // NOLINT(runtime/int)
return static_cast<unsigned short>(lo_); // NOLINT(runtime/int)
}
constexpr int128::operator int() const {
// NOLINTNEXTLINE(runtime/int)
return static_cast<int>(static_cast<long long>(*this));
}
constexpr int128::operator unsigned int() const {
return static_cast<unsigned int>(lo_);
}
constexpr int128::operator long() const { // NOLINT(runtime/int)
// NOLINTNEXTLINE(runtime/int)
return static_cast<long>(static_cast<long long>(*this));
}
constexpr int128::operator unsigned long() const { // NOLINT(runtime/int)
return static_cast<unsigned long>(lo_); // NOLINT(runtime/int)
}
constexpr int128::operator long long() const { // NOLINT(runtime/int)
// We don't bother checking the value of hi_. If *this < 0, lo_'s high bit
// must be set in order for the value to fit into a long long. Conversely, if
// lo_'s high bit is set, *this must be < 0 for the value to fit.
return int128_internal::BitCastToSigned(lo_);
}
constexpr int128::operator unsigned long long() const { // NOLINT(runtime/int)
return static_cast<unsigned long long>(lo_); // NOLINT(runtime/int)
}
// Forward declaration for conversion operators to floating point types.
int128 operator-(int128 v);
bool operator!=(int128 lhs, int128 rhs);
inline int128::operator float() const {
// We must convert the absolute value and then negate as needed, because
// floating point types are typically sign-magnitude. Otherwise, the
// difference between the high and low 64 bits when interpreted as two's
// complement overwhelms the precision of the mantissa.
//
// Also check to make sure we don't negate Int128Min()
return hi_ < 0 && *this != Int128Min()
? -static_cast<float>(-*this)
: static_cast<float>(lo_) +
std::ldexp(static_cast<float>(hi_), 64);
}
inline int128::operator double() const {
// See comment in int128::operator float() above.
return hi_ < 0 && *this != Int128Min()
? -static_cast<double>(-*this)
: static_cast<double>(lo_) +
std::ldexp(static_cast<double>(hi_), 64);
}
inline int128::operator long double() const {
// See comment in int128::operator float() above.
return hi_ < 0 && *this != Int128Min()
? -static_cast<long double>(-*this)
: static_cast<long double>(lo_) +
std::ldexp(static_cast<long double>(hi_), 64);
}
// Comparison operators.
inline bool operator==(int128 lhs, int128 rhs) {
return (Int128Low64(lhs) == Int128Low64(rhs) &&
Int128High64(lhs) == Int128High64(rhs));
}
inline bool operator!=(int128 lhs, int128 rhs) {
return !(lhs == rhs);
}
inline bool operator<(int128 lhs, int128 rhs) {
return (Int128High64(lhs) == Int128High64(rhs))
? (Int128Low64(lhs) < Int128Low64(rhs))
: (Int128High64(lhs) < Int128High64(rhs));
}
inline bool operator>(int128 lhs, int128 rhs) {
return (Int128High64(lhs) == Int128High64(rhs))
? (Int128Low64(lhs) > Int128Low64(rhs))
: (Int128High64(lhs) > Int128High64(rhs));
}
inline bool operator<=(int128 lhs, int128 rhs) {
return !(lhs > rhs);
}
inline bool operator>=(int128 lhs, int128 rhs) {
return !(lhs < rhs);
}
// Unary operators.
inline int128 operator-(int128 v) {
int64_t hi = ~Int128High64(v);
uint64_t lo = ~Int128Low64(v) + 1;
if (lo == 0) ++hi; // carry
return MakeInt128(hi, lo);
}
inline bool operator!(int128 v) {
return !Int128Low64(v) && !Int128High64(v);
}
inline int128 operator~(int128 val) {
return MakeInt128(~Int128High64(val), ~Int128Low64(val));
}
// Arithmetic operators.
inline int128 operator+(int128 lhs, int128 rhs) {
int128 result = MakeInt128(Int128High64(lhs) + Int128High64(rhs),
Int128Low64(lhs) + Int128Low64(rhs));
if (Int128Low64(result) < Int128Low64(lhs)) { // check for carry
return MakeInt128(Int128High64(result) + 1, Int128Low64(result));
}
return result;
}
inline int128 operator-(int128 lhs, int128 rhs) {
int128 result = MakeInt128(Int128High64(lhs) - Int128High64(rhs),
Int128Low64(lhs) - Int128Low64(rhs));
if (Int128Low64(lhs) < Int128Low64(rhs)) { // check for carry
return MakeInt128(Int128High64(result) - 1, Int128Low64(result));
}
return result;
}
inline int128 operator*(int128 lhs, int128 rhs) {
uint128 result = uint128(lhs) * rhs;
return MakeInt128(int128_internal::BitCastToSigned(Uint128High64(result)),
Uint128Low64(result));
}
inline int128 int128::operator++(int) {
int128 tmp(*this);
*this += 1;
return tmp;
}
inline int128 int128::operator--(int) {
int128 tmp(*this);
*this -= 1;
return tmp;
}
inline int128& int128::operator++() {
*this += 1;
return *this;
}
inline int128& int128::operator--() {
*this -= 1;
return *this;
}
inline int128 operator|(int128 lhs, int128 rhs) {
return MakeInt128(Int128High64(lhs) | Int128High64(rhs),
Int128Low64(lhs) | Int128Low64(rhs));
}
inline int128 operator&(int128 lhs, int128 rhs) {
return MakeInt128(Int128High64(lhs) & Int128High64(rhs),
Int128Low64(lhs) & Int128Low64(rhs));
}
inline int128 operator^(int128 lhs, int128 rhs) {
return MakeInt128(Int128High64(lhs) ^ Int128High64(rhs),
Int128Low64(lhs) ^ Int128Low64(rhs));
}
inline int128 operator<<(int128 lhs, int amount) {
// uint64_t shifts of >= 64 are undefined, so we need some special-casing.
if (amount < 64) {
if (amount != 0) {
return MakeInt128(
(Int128High64(lhs) << amount) |
static_cast<int64_t>(Int128Low64(lhs) >> (64 - amount)),
Int128Low64(lhs) << amount);
}
return lhs;
}
return MakeInt128(static_cast<int64_t>(Int128Low64(lhs) << (amount - 64)), 0);
}
inline int128 operator>>(int128 lhs, int amount) {
// uint64_t shifts of >= 64 are undefined, so we need some special-casing.
if (amount < 64) {
if (amount != 0) {
return MakeInt128(
Int128High64(lhs) >> amount,
(Int128Low64(lhs) >> amount) |
(static_cast<uint64_t>(Int128High64(lhs)) << (64 - amount)));
}
return lhs;
}
return MakeInt128(0,
static_cast<uint64_t>(Int128High64(lhs) >> (amount - 64)));
}

729
absl/numeric/int128_stream_test.cc
View file

@ -147,6 +147,735 @@ TEST(Uint128, OStreamFormatTest) {
}
}
struct Int128TestCase {
absl::int128 value;
std::ios_base::fmtflags flags;
std::streamsize width;
const char* expected;
};
void CheckInt128Case(const Int128TestCase& test_case) {
std::ostringstream os;
os.flags(test_case.flags);
os.width(test_case.width);
os.fill(kFill);
os << test_case.value;
SCOPED_TRACE(StreamFormatToString(test_case.flags, test_case.width));
EXPECT_EQ(test_case.expected, os.str());
}
TEST(Int128, OStreamValueTest) {
CheckInt128Case({1, kDec, /*width = */ 0, "1"});
CheckInt128Case({1, kOct, /*width = */ 0, "1"});
CheckInt128Case({1, kHex, /*width = */ 0, "1"});
CheckInt128Case({9, kDec, /*width = */ 0, "9"});
CheckInt128Case({9, kOct, /*width = */ 0, "11"});
CheckInt128Case({9, kHex, /*width = */ 0, "9"});
CheckInt128Case({12345, kDec, /*width = */ 0, "12345"});
CheckInt128Case({12345, kOct, /*width = */ 0, "30071"});
CheckInt128Case({12345, kHex, /*width = */ 0, "3039"});
CheckInt128Case(
{0x8000000000000000, kDec, /*width = */ 0, "9223372036854775808"});
CheckInt128Case(
{0x8000000000000000, kOct, /*width = */ 0, "1000000000000000000000"});
CheckInt128Case(
{0x8000000000000000, kHex, /*width = */ 0, "8000000000000000"});
CheckInt128Case({std::numeric_limits<uint64_t>::max(), kDec,
/*width = */ 0, "18446744073709551615"});
CheckInt128Case({std::numeric_limits<uint64_t>::max(), kOct,
/*width = */ 0, "1777777777777777777777"});
CheckInt128Case({std::numeric_limits<uint64_t>::max(), kHex,
/*width = */ 0, "ffffffffffffffff"});
CheckInt128Case(
{absl::MakeInt128(1, 0), kDec, /*width = */ 0, "18446744073709551616"});
CheckInt128Case(
{absl::MakeInt128(1, 0), kOct, /*width = */ 0, "2000000000000000000000"});
CheckInt128Case(
{absl::MakeInt128(1, 0), kHex, /*width = */ 0, "10000000000000000"});
CheckInt128Case({absl::MakeInt128(std::numeric_limits<int64_t>::max(),
std::numeric_limits<uint64_t>::max()),
std::ios::dec, /*width = */ 0,
"170141183460469231731687303715884105727"});
CheckInt128Case({absl::MakeInt128(std::numeric_limits<int64_t>::max(),
std::numeric_limits<uint64_t>::max()),
std::ios::oct, /*width = */ 0,
"1777777777777777777777777777777777777777777"});
CheckInt128Case({absl::MakeInt128(std::numeric_limits<int64_t>::max(),
std::numeric_limits<uint64_t>::max()),
std::ios::hex, /*width = */ 0,
"7fffffffffffffffffffffffffffffff"});
CheckInt128Case({absl::MakeInt128(std::numeric_limits<int64_t>::min(), 0),
std::ios::dec, /*width = */ 0,
"-170141183460469231731687303715884105728"});
CheckInt128Case({absl::MakeInt128(std::numeric_limits<int64_t>::min(), 0),
std::ios::oct, /*width = */ 0,
"2000000000000000000000000000000000000000000"});
CheckInt128Case({absl::MakeInt128(std::numeric_limits<int64_t>::min(), 0),
std::ios::hex, /*width = */ 0,
"80000000000000000000000000000000"});
CheckInt128Case({-1, std::ios::dec, /*width = */ 0, "-1"});
CheckInt128Case({-1, std::ios::oct, /*width = */ 0,
"3777777777777777777777777777777777777777777"});
CheckInt128Case(
{-1, std::ios::hex, /*width = */ 0, "ffffffffffffffffffffffffffffffff"});
CheckInt128Case({-12345, std::ios::dec, /*width = */ 0, "-12345"});
CheckInt128Case({-12345, std::ios::oct, /*width = */ 0,
"3777777777777777777777777777777777777747707"});
CheckInt128Case({-12345, std::ios::hex, /*width = */ 0,
"ffffffffffffffffffffffffffffcfc7"});
}
std::vector<Int128TestCase> GetInt128FormatCases();
TEST(Int128, OStreamFormatTest) {
for (const Int128TestCase& test_case : GetInt128FormatCases()) {
CheckInt128Case(test_case);
}
}
std::vector<Int128TestCase> GetInt128FormatCases() {
return {
{0, std::ios_base::fmtflags(), /*width = */ 0, "0"},
{0, std::ios_base::fmtflags(), /*width = */ 6, "_____0"},
{0, kPos, /*width = */ 0, "+0"},
{0, kPos, /*width = */ 6, "____+0"},
{0, kBase, /*width = */ 0, "0"},
{0, kBase, /*width = */ 6, "_____0"},
{0, kBase | kPos, /*width = */ 0, "+0"},
{0, kBase | kPos, /*width = */ 6, "____+0"},
{0, kUpper, /*width = */ 0, "0"},
{0, kUpper, /*width = */ 6, "_____0"},
{0, kUpper | kPos, /*width = */ 0, "+0"},
{0, kUpper | kPos, /*width = */ 6, "____+0"},
{0, kUpper | kBase, /*width = */ 0, "0"},
{0, kUpper | kBase, /*width = */ 6, "_____0"},
{0, kUpper | kBase | kPos, /*width = */ 0, "+0"},
{0, kUpper | kBase | kPos, /*width = */ 6, "____+0"},
{0, kLeft, /*width = */ 0, "0"},
{0, kLeft, /*width = */ 6, "0_____"},
{0, kLeft | kPos, /*width = */ 0, "+0"},
{0, kLeft | kPos, /*width = */ 6, "+0____"},
{0, kLeft | kBase, /*width = */ 0, "0"},
{0, kLeft | kBase, /*width = */ 6, "0_____"},
{0, kLeft | kBase | kPos, /*width = */ 0, "+0"},
{0, kLeft | kBase | kPos, /*width = */ 6, "+0____"},
{0, kLeft | kUpper, /*width = */ 0, "0"},
{0, kLeft | kUpper, /*width = */ 6, "0_____"},
{0, kLeft | kUpper | kPos, /*width = */ 0, "+0"},
{0, kLeft | kUpper | kPos, /*width = */ 6, "+0____"},
{0, kLeft | kUpper | kBase, /*width = */ 0, "0"},
{0, kLeft | kUpper | kBase, /*width = */ 6, "0_____"},
{0, kLeft | kUpper | kBase | kPos, /*width = */ 0, "+0"},
{0, kLeft | kUpper | kBase | kPos, /*width = */ 6, "+0____"},
{0, kInt, /*width = */ 0, "0"},
{0, kInt, /*width = */ 6, "_____0"},
{0, kInt | kPos, /*width = */ 0, "+0"},
{0, kInt | kPos, /*width = */ 6, "+____0"},
{0, kInt | kBase, /*width = */ 0, "0"},
{0, kInt | kBase, /*width = */ 6, "_____0"},
{0, kInt | kBase | kPos, /*width = */ 0, "+0"},
{0, kInt | kBase | kPos, /*width = */ 6, "+____0"},
{0, kInt | kUpper, /*width = */ 0, "0"},
{0, kInt | kUpper, /*width = */ 6, "_____0"},
{0, kInt | kUpper | kPos, /*width = */ 0, "+0"},
{0, kInt | kUpper | kPos, /*width = */ 6, "+____0"},
{0, kInt | kUpper | kBase, /*width = */ 0, "0"},
{0, kInt | kUpper | kBase, /*width = */ 6, "_____0"},
{0, kInt | kUpper | kBase | kPos, /*width = */ 0, "+0"},
{0, kInt | kUpper | kBase | kPos, /*width = */ 6, "+____0"},
{0, kRight, /*width = */ 0, "0"},
{0, kRight, /*width = */ 6, "_____0"},
{0, kRight | kPos, /*width = */ 0, "+0"},
{0, kRight | kPos, /*width = */ 6, "____+0"},
{0, kRight | kBase, /*width = */ 0, "0"},
{0, kRight | kBase, /*width = */ 6, "_____0"},
{0, kRight | kBase | kPos, /*width = */ 0, "+0"},
{0, kRight | kBase | kPos, /*width = */ 6, "____+0"},
{0, kRight | kUpper, /*width = */ 0, "0"},
{0, kRight | kUpper, /*width = */ 6, "_____0"},
{0, kRight | kUpper | kPos, /*width = */ 0, "+0"},
{0, kRight | kUpper | kPos, /*width = */ 6, "____+0"},
{0, kRight | kUpper | kBase, /*width = */ 0, "0"},
{0, kRight | kUpper | kBase, /*width = */ 6, "_____0"},
{0, kRight | kUpper | kBase | kPos, /*width = */ 0, "+0"},
{0, kRight | kUpper | kBase | kPos, /*width = */ 6, "____+0"},
{0, kDec, /*width = */ 0, "0"},
{0, kDec, /*width = */ 6, "_____0"},
{0, kDec | kPos, /*width = */ 0, "+0"},
{0, kDec | kPos, /*width = */ 6, "____+0"},
{0, kDec | kBase, /*width = */ 0, "0"},
{0, kDec | kBase, /*width = */ 6, "_____0"},
{0, kDec | kBase | kPos, /*width = */ 0, "+0"},
{0, kDec | kBase | kPos, /*width = */ 6, "____+0"},
{0, kDec | kUpper, /*width = */ 0, "0"},
{0, kDec | kUpper, /*width = */ 6, "_____0"},
{0, kDec | kUpper | kPos, /*width = */ 0, "+0"},
{0, kDec | kUpper | kPos, /*width = */ 6, "____+0"},
{0, kDec | kUpper | kBase, /*width = */ 0, "0"},
{0, kDec | kUpper | kBase, /*width = */ 6, "_____0"},
{0, kDec | kUpper | kBase | kPos, /*width = */ 0, "+0"},
{0, kDec | kUpper | kBase | kPos, /*width = */ 6, "____+0"},
{0, kDec | kLeft, /*width = */ 0, "0"},
{0, kDec | kLeft, /*width = */ 6, "0_____"},
{0, kDec | kLeft | kPos, /*width = */ 0, "+0"},
{0, kDec | kLeft | kPos, /*width = */ 6, "+0____"},
{0, kDec | kLeft | kBase, /*width = */ 0, "0"},
{0, kDec | kLeft | kBase, /*width = */ 6, "0_____"},
{0, kDec | kLeft | kBase | kPos, /*width = */ 0, "+0"},
{0, kDec | kLeft | kBase | kPos, /*width = */ 6, "+0____"},
{0, kDec | kLeft | kUpper, /*width = */ 0, "0"},
{0, kDec | kLeft | kUpper, /*width = */ 6, "0_____"},
{0, kDec | kLeft | kUpper | kPos, /*width = */ 0, "+0"},
{0, kDec | kLeft | kUpper | kPos, /*width = */ 6, "+0____"},
{0, kDec | kLeft | kUpper | kBase, /*width = */ 0, "0"},
{0, kDec | kLeft | kUpper | kBase, /*width = */ 6, "0_____"},
{0, kDec | kLeft | kUpper | kBase | kPos, /*width = */ 0, "+0"},
{0, kDec | kLeft | kUpper | kBase | kPos, /*width = */ 6, "+0____"},
{0, kDec | kInt, /*width = */ 0, "0"},
{0, kDec | kInt, /*width = */ 6, "_____0"},
{0, kDec | kInt | kPos, /*width = */ 0, "+0"},
{0, kDec | kInt | kPos, /*width = */ 6, "+____0"},
{0, kDec | kInt | kBase, /*width = */ 0, "0"},
{0, kDec | kInt | kBase, /*width = */ 6, "_____0"},
{0, kDec | kInt | kBase | kPos, /*width = */ 0, "+0"},
{0, kDec | kInt | kBase | kPos, /*width = */ 6, "+____0"},
{0, kDec | kInt | kUpper, /*width = */ 0, "0"},
{0, kDec | kInt | kUpper, /*width = */ 6, "_____0"},
{0, kDec | kInt | kUpper | kPos, /*width = */ 0, "+0"},
{0, kDec | kInt | kUpper | kPos, /*width = */ 6, "+____0"},
{0, kDec | kInt | kUpper | kBase, /*width = */ 0, "0"},
{0, kDec | kInt | kUpper | kBase, /*width = */ 6, "_____0"},
{0, kDec | kInt | kUpper | kBase | kPos, /*width = */ 0, "+0"},
{0, kDec | kInt | kUpper | kBase | kPos, /*width = */ 6, "+____0"},
{0, kDec | kRight, /*width = */ 0, "0"},
{0, kDec | kRight, /*width = */ 6, "_____0"},
{0, kDec | kRight | kPos, /*width = */ 0, "+0"},
{0, kDec | kRight | kPos, /*width = */ 6, "____+0"},
{0, kDec | kRight | kBase, /*width = */ 0, "0"},
{0, kDec | kRight | kBase, /*width = */ 6, "_____0"},
{0, kDec | kRight | kBase | kPos, /*width = */ 0, "+0"},
{0, kDec | kRight | kBase | kPos, /*width = */ 6, "____+0"},
{0, kDec | kRight | kUpper, /*width = */ 0, "0"},
{0, kDec | kRight | kUpper, /*width = */ 6, "_____0"},
{0, kDec | kRight | kUpper | kPos, /*width = */ 0, "+0"},
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{42, kHex | kUpper | kBase, /*width = */ 0, "0X2A"},
{42, kHex | kUpper | kBase, /*width = */ 6, "__0X2A"},
{42, kHex | kUpper | kBase | kPos, /*width = */ 0, "0X2A"},
{42, kHex | kUpper | kBase | kPos, /*width = */ 6, "__0X2A"},
{42, kHex | kLeft, /*width = */ 0, "2a"},
{42, kHex | kLeft, /*width = */ 6, "2a____"},
{42, kHex | kLeft | kPos, /*width = */ 0, "2a"},
{42, kHex | kLeft | kPos, /*width = */ 6, "2a____"},
{42, kHex | kLeft | kBase, /*width = */ 0, "0x2a"},
{42, kHex | kLeft | kBase, /*width = */ 6, "0x2a__"},
{42, kHex | kLeft | kBase | kPos, /*width = */ 0, "0x2a"},
{42, kHex | kLeft | kBase | kPos, /*width = */ 6, "0x2a__"},
{42, kHex | kLeft | kUpper, /*width = */ 0, "2A"},
{42, kHex | kLeft | kUpper, /*width = */ 6, "2A____"},
{42, kHex | kLeft | kUpper | kPos, /*width = */ 0, "2A"},
{42, kHex | kLeft | kUpper | kPos, /*width = */ 6, "2A____"},
{42, kHex | kLeft | kUpper | kBase, /*width = */ 0, "0X2A"},
{42, kHex | kLeft | kUpper | kBase, /*width = */ 6, "0X2A__"},
{42, kHex | kLeft | kUpper | kBase | kPos, /*width = */ 0, "0X2A"},
{42, kHex | kLeft | kUpper | kBase | kPos, /*width = */ 6, "0X2A__"},
{42, kHex | kInt, /*width = */ 0, "2a"},
{42, kHex | kInt, /*width = */ 6, "____2a"},
{42, kHex | kInt | kPos, /*width = */ 0, "2a"},
{42, kHex | kInt | kPos, /*width = */ 6, "____2a"},
{42, kHex | kInt | kBase, /*width = */ 0, "0x2a"},
{42, kHex | kInt | kBase, /*width = */ 6, "0x__2a"},
{42, kHex | kInt | kBase | kPos, /*width = */ 0, "0x2a"},
{42, kHex | kInt | kBase | kPos, /*width = */ 6, "0x__2a"},
{42, kHex | kInt | kUpper, /*width = */ 0, "2A"},
{42, kHex | kInt | kUpper, /*width = */ 6, "____2A"},
{42, kHex | kInt | kUpper | kPos, /*width = */ 0, "2A"},
{42, kHex | kInt | kUpper | kPos, /*width = */ 6, "____2A"},
{42, kHex | kInt | kUpper | kBase, /*width = */ 0, "0X2A"},
{42, kHex | kInt | kUpper | kBase, /*width = */ 6, "0X__2A"},
{42, kHex | kInt | kUpper | kBase | kPos, /*width = */ 0, "0X2A"},
{42, kHex | kInt | kUpper | kBase | kPos, /*width = */ 6, "0X__2A"},
{42, kHex | kRight, /*width = */ 0, "2a"},
{42, kHex | kRight, /*width = */ 6, "____2a"},
{42, kHex | kRight | kPos, /*width = */ 0, "2a"},
{42, kHex | kRight | kPos, /*width = */ 6, "____2a"},
{42, kHex | kRight | kBase, /*width = */ 0, "0x2a"},
{42, kHex | kRight | kBase, /*width = */ 6, "__0x2a"},
{42, kHex | kRight | kBase | kPos, /*width = */ 0, "0x2a"},
{42, kHex | kRight | kBase | kPos, /*width = */ 6, "__0x2a"},
{42, kHex | kRight | kUpper, /*width = */ 0, "2A"},
{42, kHex | kRight | kUpper, /*width = */ 6, "____2A"},
{42, kHex | kRight | kUpper | kPos, /*width = */ 0, "2A"},
{42, kHex | kRight | kUpper | kPos, /*width = */ 6, "____2A"},
{42, kHex | kRight | kUpper | kBase, /*width = */ 0, "0X2A"},
{42, kHex | kRight | kUpper | kBase, /*width = */ 6, "__0X2A"},
{42, kHex | kRight | kUpper | kBase | kPos, /*width = */ 0, "0X2A"},
{42, kHex | kRight | kUpper | kBase | kPos, /*width = */ 6, "__0X2A"},
{-321, std::ios_base::fmtflags(), /*width = */ 0, "-321"},
{-321, std::ios_base::fmtflags(), /*width = */ 6, "__-321"},
{-321, kPos, /*width = */ 0, "-321"},
{-321, kPos, /*width = */ 6, "__-321"},
{-321, kBase, /*width = */ 0, "-321"},
{-321, kBase, /*width = */ 6, "__-321"},
{-321, kBase | kPos, /*width = */ 0, "-321"},
{-321, kBase | kPos, /*width = */ 6, "__-321"},
{-321, kUpper, /*width = */ 0, "-321"},
{-321, kUpper, /*width = */ 6, "__-321"},
{-321, kUpper | kPos, /*width = */ 0, "-321"},
{-321, kUpper | kPos, /*width = */ 6, "__-321"},
{-321, kUpper | kBase, /*width = */ 0, "-321"},
{-321, kUpper | kBase, /*width = */ 6, "__-321"},
{-321, kUpper | kBase | kPos, /*width = */ 0, "-321"},
{-321, kUpper | kBase | kPos, /*width = */ 6, "__-321"},
{-321, kLeft, /*width = */ 0, "-321"},
{-321, kLeft, /*width = */ 6, "-321__"},
{-321, kLeft | kPos, /*width = */ 0, "-321"},
{-321, kLeft | kPos, /*width = */ 6, "-321__"},
{-321, kLeft | kBase, /*width = */ 0, "-321"},
{-321, kLeft | kBase, /*width = */ 6, "-321__"},
{-321, kLeft | kBase | kPos, /*width = */ 0, "-321"},
{-321, kLeft | kBase | kPos, /*width = */ 6, "-321__"},
{-321, kLeft | kUpper, /*width = */ 0, "-321"},
{-321, kLeft | kUpper, /*width = */ 6, "-321__"},
{-321, kLeft | kUpper | kPos, /*width = */ 0, "-321"},
{-321, kLeft | kUpper | kPos, /*width = */ 6, "-321__"},
{-321, kLeft | kUpper | kBase, /*width = */ 0, "-321"},
{-321, kLeft | kUpper | kBase, /*width = */ 6, "-321__"},
{-321, kLeft | kUpper | kBase | kPos, /*width = */ 0, "-321"},
{-321, kLeft | kUpper | kBase | kPos, /*width = */ 6, "-321__"},
{-321, kInt, /*width = */ 0, "-321"},
{-321, kInt, /*width = */ 6, "-__321"},
{-321, kInt | kPos, /*width = */ 0, "-321"},
{-321, kInt | kPos, /*width = */ 6, "-__321"},
{-321, kInt | kBase, /*width = */ 0, "-321"},
{-321, kInt | kBase, /*width = */ 6, "-__321"},
{-321, kInt | kBase | kPos, /*width = */ 0, "-321"},
{-321, kInt | kBase | kPos, /*width = */ 6, "-__321"},
{-321, kInt | kUpper, /*width = */ 0, "-321"},
{-321, kInt | kUpper, /*width = */ 6, "-__321"},
{-321, kInt | kUpper | kPos, /*width = */ 0, "-321"},
{-321, kInt | kUpper | kPos, /*width = */ 6, "-__321"},
{-321, kInt | kUpper | kBase, /*width = */ 0, "-321"},
{-321, kInt | kUpper | kBase, /*width = */ 6, "-__321"},
{-321, kInt | kUpper | kBase | kPos, /*width = */ 0, "-321"},
{-321, kInt | kUpper | kBase | kPos, /*width = */ 6, "-__321"},
{-321, kRight, /*width = */ 0, "-321"},
{-321, kRight, /*width = */ 6, "__-321"},
{-321, kRight | kPos, /*width = */ 0, "-321"},
{-321, kRight | kPos, /*width = */ 6, "__-321"},
{-321, kRight | kBase, /*width = */ 0, "-321"},
{-321, kRight | kBase, /*width = */ 6, "__-321"},
{-321, kRight | kBase | kPos, /*width = */ 0, "-321"},
{-321, kRight | kBase | kPos, /*width = */ 6, "__-321"},
{-321, kRight | kUpper, /*width = */ 0, "-321"},
{-321, kRight | kUpper, /*width = */ 6, "__-321"},
{-321, kRight | kUpper | kPos, /*width = */ 0, "-321"},
{-321, kRight | kUpper | kPos, /*width = */ 6, "__-321"},
{-321, kRight | kUpper | kBase, /*width = */ 0, "-321"},
{-321, kRight | kUpper | kBase, /*width = */ 6, "__-321"},
{-321, kRight | kUpper | kBase | kPos, /*width = */ 0, "-321"},
{-321, kRight | kUpper | kBase | kPos, /*width = */ 6, "__-321"},
{-321, kDec, /*width = */ 0, "-321"},
{-321, kDec, /*width = */ 6, "__-321"},
{-321, kDec | kPos, /*width = */ 0, "-321"},
{-321, kDec | kPos, /*width = */ 6, "__-321"},
{-321, kDec | kBase, /*width = */ 0, "-321"},
{-321, kDec | kBase, /*width = */ 6, "__-321"},
{-321, kDec | kBase | kPos, /*width = */ 0, "-321"},
{-321, kDec | kBase | kPos, /*width = */ 6, "__-321"},
{-321, kDec | kUpper, /*width = */ 0, "-321"},
{-321, kDec | kUpper, /*width = */ 6, "__-321"},
{-321, kDec | kUpper | kPos, /*width = */ 0, "-321"},
{-321, kDec | kUpper | kPos, /*width = */ 6, "__-321"},
{-321, kDec | kUpper | kBase, /*width = */ 0, "-321"},
{-321, kDec | kUpper | kBase, /*width = */ 6, "__-321"},
{-321, kDec | kUpper | kBase | kPos, /*width = */ 0, "-321"},
{-321, kDec | kUpper | kBase | kPos, /*width = */ 6, "__-321"},
{-321, kDec | kLeft, /*width = */ 0, "-321"},
{-321, kDec | kLeft, /*width = */ 6, "-321__"},
{-321, kDec | kLeft | kPos, /*width = */ 0, "-321"},
{-321, kDec | kLeft | kPos, /*width = */ 6, "-321__"},
{-321, kDec | kLeft | kBase, /*width = */ 0, "-321"},
{-321, kDec | kLeft | kBase, /*width = */ 6, "-321__"},
{-321, kDec | kLeft | kBase | kPos, /*width = */ 0, "-321"},
{-321, kDec | kLeft | kBase | kPos, /*width = */ 6, "-321__"},
{-321, kDec | kLeft | kUpper, /*width = */ 0, "-321"},
{-321, kDec | kLeft | kUpper, /*width = */ 6, "-321__"},
{-321, kDec | kLeft | kUpper | kPos, /*width = */ 0, "-321"},
{-321, kDec | kLeft | kUpper | kPos, /*width = */ 6, "-321__"},
{-321, kDec | kLeft | kUpper | kBase, /*width = */ 0, "-321"},
{-321, kDec | kLeft | kUpper | kBase, /*width = */ 6, "-321__"},
{-321, kDec | kLeft | kUpper | kBase | kPos, /*width = */ 0, "-321"},
{-321, kDec | kLeft | kUpper | kBase | kPos, /*width = */ 6, "-321__"},
{-321, kDec | kInt, /*width = */ 0, "-321"},
{-321, kDec | kInt, /*width = */ 6, "-__321"},
{-321, kDec | kInt | kPos, /*width = */ 0, "-321"},
{-321, kDec | kInt | kPos, /*width = */ 6, "-__321"},
{-321, kDec | kInt | kBase, /*width = */ 0, "-321"},
{-321, kDec | kInt | kBase, /*width = */ 6, "-__321"},
{-321, kDec | kInt | kBase | kPos, /*width = */ 0, "-321"},
{-321, kDec | kInt | kBase | kPos, /*width = */ 6, "-__321"},
{-321, kDec | kInt | kUpper, /*width = */ 0, "-321"},
{-321, kDec | kInt | kUpper, /*width = */ 6, "-__321"},
{-321, kDec | kInt | kUpper | kPos, /*width = */ 0, "-321"},
{-321, kDec | kInt | kUpper | kPos, /*width = */ 6, "-__321"},
{-321, kDec | kInt | kUpper | kBase, /*width = */ 0, "-321"},
{-321, kDec | kInt | kUpper | kBase, /*width = */ 6, "-__321"},
{-321, kDec | kInt | kUpper | kBase | kPos, /*width = */ 0, "-321"},
{-321, kDec | kInt | kUpper | kBase | kPos, /*width = */ 6, "-__321"},
{-321, kDec | kRight, /*width = */ 0, "-321"},
{-321, kDec | kRight, /*width = */ 6, "__-321"},
{-321, kDec | kRight | kPos, /*width = */ 0, "-321"},
{-321, kDec | kRight | kPos, /*width = */ 6, "__-321"},
{-321, kDec | kRight | kBase, /*width = */ 0, "-321"},
{-321, kDec | kRight | kBase, /*width = */ 6, "__-321"},
{-321, kDec | kRight | kBase | kPos, /*width = */ 0, "-321"},
{-321, kDec | kRight | kBase | kPos, /*width = */ 6, "__-321"},
{-321, kDec | kRight | kUpper, /*width = */ 0, "-321"},
{-321, kDec | kRight | kUpper, /*width = */ 6, "__-321"},
{-321, kDec | kRight | kUpper | kPos, /*width = */ 0, "-321"},
{-321, kDec | kRight | kUpper | kPos, /*width = */ 6, "__-321"},
{-321, kDec | kRight | kUpper | kBase, /*width = */ 0, "-321"},
{-321, kDec | kRight | kUpper | kBase, /*width = */ 6, "__-321"},
{-321, kDec | kRight | kUpper | kBase | kPos, /*width = */ 0, "-321"},
{-321, kDec | kRight | kUpper | kBase | kPos, /*width = */ 6, "__-321"}};
}
std::vector<Uint128TestCase> GetUint128FormatCases() {
return {
{0, std::ios_base::fmtflags(), /*width = */ 0, "0"},

743
absl/numeric/int128_test.cc
View file

@ -479,4 +479,747 @@ TEST(Uint128, Hash) {
}));
}
TEST(Int128Uint128, ConversionTest) {
absl::int128 nonnegative_signed_values[] = {
0,
1,
0xffeeddccbbaa9988,
absl::MakeInt128(0x7766554433221100, 0),
absl::MakeInt128(0x1234567890abcdef, 0xfedcba0987654321),
absl::Int128Max()};
for (absl::int128 value : nonnegative_signed_values) {
EXPECT_EQ(value, absl::int128(absl::uint128(value)));
absl::uint128 assigned_value;
assigned_value = value;
EXPECT_EQ(value, absl::int128(assigned_value));
}
absl::int128 negative_values[] = {
-1, -0x1234567890abcdef,
absl::MakeInt128(-0x5544332211ffeedd, 0),
-absl::MakeInt128(0x76543210fedcba98, 0xabcdef0123456789)};
for (absl::int128 value : negative_values) {
EXPECT_EQ(absl::uint128(-value), -absl::uint128(value));
absl::uint128 assigned_value;
assigned_value = value;
EXPECT_EQ(absl::uint128(-value), -assigned_value);
}
}
template <typename T>
class Int128IntegerTraitsTest : public ::testing::Test {};
TYPED_TEST_SUITE(Int128IntegerTraitsTest, IntegerTypes);
TYPED_TEST(Int128IntegerTraitsTest, ConstructAssignTest) {
static_assert(std::is_constructible<absl::int128, TypeParam>::value,
"absl::int128 must be constructible from TypeParam");
static_assert(std::is_assignable<absl::int128&, TypeParam>::value,
"absl::int128 must be assignable from TypeParam");
static_assert(!std::is_assignable<TypeParam&, absl::int128>::value,
"TypeParam must not be assignable from absl::int128");
}
template <typename T>
class Int128FloatTraitsTest : public ::testing::Test {};
TYPED_TEST_SUITE(Int128FloatTraitsTest, FloatingPointTypes);
TYPED_TEST(Int128FloatTraitsTest, ConstructAssignTest) {
static_assert(std::is_constructible<absl::int128, TypeParam>::value,
"absl::int128 must be constructible from TypeParam");
static_assert(!std::is_assignable<absl::int128&, TypeParam>::value,
"absl::int128 must not be assignable from TypeParam");
static_assert(!std::is_assignable<TypeParam&, absl::int128>::value,
"TypeParam must not be assignable from absl::int128");
}
#ifdef ABSL_HAVE_INTRINSIC_INT128
// These type traits done separately as TYPED_TEST requires typeinfo, and not
// all platforms have this for __int128 even though they define the type.
TEST(Int128, IntrinsicTypeTraitsTest) {
static_assert(std::is_constructible<absl::int128, __int128>::value,
"absl::int128 must be constructible from __int128");
static_assert(std::is_assignable<absl::int128&, __int128>::value,
"absl::int128 must be assignable from __int128");
static_assert(!std::is_assignable<__int128&, absl::int128>::value,
"__int128 must not be assignable from absl::int128");
static_assert(std::is_constructible<absl::int128, unsigned __int128>::value,
"absl::int128 must be constructible from unsigned __int128");
static_assert(!std::is_assignable<absl::int128&, unsigned __int128>::value,
"absl::int128 must be assignable from unsigned __int128");
static_assert(!std::is_assignable<unsigned __int128&, absl::int128>::value,
"unsigned __int128 must not be assignable from absl::int128");
}
#endif // ABSL_HAVE_INTRINSIC_INT128
TEST(Int128, TrivialTraitsTest) {
static_assert(absl::is_trivially_default_constructible<absl::int128>::value,
"");
static_assert(absl::is_trivially_copy_constructible<absl::int128>::value, "");
static_assert(absl::is_trivially_copy_assignable<absl::int128>::value, "");
static_assert(std::is_trivially_destructible<absl::int128>::value, "");
}
TEST(Int128, BoolConversionTest) {
EXPECT_FALSE(absl::int128(0));
for (int i = 0; i < 64; ++i) {
EXPECT_TRUE(absl::MakeInt128(0, uint64_t{1} << i));
}
for (int i = 0; i < 63; ++i) {
EXPECT_TRUE(absl::MakeInt128(int64_t{1} << i, 0));
}
EXPECT_TRUE(absl::Int128Min());
EXPECT_EQ(absl::int128(1), absl::int128(true));
EXPECT_EQ(absl::int128(0), absl::int128(false));
}
template <typename T>
class Int128IntegerConversionTest : public ::testing::Test {};
TYPED_TEST_SUITE(Int128IntegerConversionTest, IntegerTypes);
TYPED_TEST(Int128IntegerConversionTest, RoundTripTest) {
EXPECT_EQ(TypeParam{0}, static_cast<TypeParam>(absl::int128(0)));
EXPECT_EQ(std::numeric_limits<TypeParam>::min(),
static_cast<TypeParam>(
absl::int128(std::numeric_limits<TypeParam>::min())));
EXPECT_EQ(std::numeric_limits<TypeParam>::max(),
static_cast<TypeParam>(
absl::int128(std::numeric_limits<TypeParam>::max())));
}
template <typename T>
class Int128FloatConversionTest : public ::testing::Test {};
TYPED_TEST_SUITE(Int128FloatConversionTest, FloatingPointTypes);
TYPED_TEST(Int128FloatConversionTest, ConstructAndCastTest) {
// Conversions where the floating point values should be exactly the same.
// 0x9f5b is a randomly chosen small value.
for (int i = 0; i < 110; ++i) { // 110 = 126 - #bits in 0x9f5b
SCOPED_TRACE(::testing::Message() << "i = " << i);
TypeParam float_value = std::ldexp(static_cast<TypeParam>(0x9f5b), i);
absl::int128 int_value = absl::int128(0x9f5b) << i;
EXPECT_EQ(float_value, static_cast<TypeParam>(int_value));
EXPECT_EQ(-float_value, static_cast<TypeParam>(-int_value));
EXPECT_EQ(int_value, absl::int128(float_value));
EXPECT_EQ(-int_value, absl::int128(-float_value));
}
// Round trip conversions with a small sample of randomly generated uint64_t
// values (less than int64_t max so that value * 2^64 fits into int128).
uint64_t values[] = {0x6d4492c24fb86199, 0x26ead65e4cb359b5,
0x2c43407433ba3fd1, 0x3b574ec668df6b55,
0x1c750e55a29f4f0f};
for (uint64_t value : values) {
for (int i = 0; i <= 64; ++i) {
SCOPED_TRACE(::testing::Message()
<< "value = " << value << "; i = " << i);
TypeParam fvalue = std::ldexp(static_cast<TypeParam>(value), i);
EXPECT_DOUBLE_EQ(fvalue, static_cast<TypeParam>(absl::int128(fvalue)));
EXPECT_DOUBLE_EQ(-fvalue, static_cast<TypeParam>(-absl::int128(fvalue)));
EXPECT_DOUBLE_EQ(-fvalue, static_cast<TypeParam>(absl::int128(-fvalue)));
EXPECT_DOUBLE_EQ(fvalue, static_cast<TypeParam>(-absl::int128(-fvalue)));
}
}
// Round trip conversions with a small sample of random large positive values.
absl::int128 large_values[] = {
absl::MakeInt128(0x5b0640d96c7b3d9f, 0xb7a7189e51d18622),
absl::MakeInt128(0x34bed042c6f65270, 0x73b236570669a089),
absl::MakeInt128(0x43deba9e6da12724, 0xf7f0f83da686797d),
absl::MakeInt128(0x71e8d383be4e5589, 0x75c3f96fb00752b6)};
for (absl::int128 value : large_values) {
// Make value have as many significant bits as can be represented by
// the mantissa, also making sure the highest and lowest bit in the range
// are set.
value >>= (127 - std::numeric_limits<TypeParam>::digits);
value |= absl::int128(1) << (std::numeric_limits<TypeParam>::digits - 1);
value |= 1;
for (int i = 0; i < 127 - std::numeric_limits<TypeParam>::digits; ++i) {
absl::int128 int_value = value << i;
EXPECT_EQ(int_value,
static_cast<absl::int128>(static_cast<TypeParam>(int_value)));
EXPECT_EQ(-int_value,
static_cast<absl::int128>(static_cast<TypeParam>(-int_value)));
}
}
// Small sample of checks that rounding is toward zero
EXPECT_EQ(0, absl::int128(TypeParam(0.1)));
EXPECT_EQ(17, absl::int128(TypeParam(17.8)));
EXPECT_EQ(0, absl::int128(TypeParam(-0.8)));
EXPECT_EQ(-53, absl::int128(TypeParam(-53.1)));
EXPECT_EQ(0, absl::int128(TypeParam(0.5)));
EXPECT_EQ(0, absl::int128(TypeParam(-0.5)));
TypeParam just_lt_one = std::nexttoward(TypeParam(1), TypeParam(0));
EXPECT_EQ(0, absl::int128(just_lt_one));
TypeParam just_gt_minus_one = std::nexttoward(TypeParam(-1), TypeParam(0));
EXPECT_EQ(0, absl::int128(just_gt_minus_one));
// Check limits
EXPECT_DOUBLE_EQ(std::ldexp(static_cast<TypeParam>(1), 127),
static_cast<TypeParam>(absl::Int128Max()));
EXPECT_DOUBLE_EQ(-std::ldexp(static_cast<TypeParam>(1), 127),
static_cast<TypeParam>(absl::Int128Min()));
}
TEST(Int128, FactoryTest) {
EXPECT_EQ(absl::int128(-1), absl::MakeInt128(-1, -1));
EXPECT_EQ(absl::int128(-31), absl::MakeInt128(-1, -31));
EXPECT_EQ(absl::int128(std::numeric_limits<int64_t>::min()),
absl::MakeInt128(-1, std::numeric_limits<int64_t>::min()));
EXPECT_EQ(absl::int128(0), absl::MakeInt128(0, 0));
EXPECT_EQ(absl::int128(1), absl::MakeInt128(0, 1));
EXPECT_EQ(absl::int128(std::numeric_limits<int64_t>::max()),
absl::MakeInt128(0, std::numeric_limits<int64_t>::max()));
}
TEST(Int128, HighLowTest) {
struct HighLowPair {
int64_t high;
uint64_t low;
};
HighLowPair values[]{{0, 0}, {0, 1}, {1, 0}, {123, 456}, {-654, 321}};
for (const HighLowPair& pair : values) {
absl::int128 value = absl::MakeInt128(pair.high, pair.low);
EXPECT_EQ(pair.low, absl::Int128Low64(value));
EXPECT_EQ(pair.high, absl::Int128High64(value));
}
}
TEST(Int128, LimitsTest) {
EXPECT_EQ(absl::MakeInt128(0x7fffffffffffffff, 0xffffffffffffffff),
absl::Int128Max());
EXPECT_EQ(absl::Int128Max(), ~absl::Int128Min());
}
#if defined(ABSL_HAVE_INTRINSIC_INT128)
TEST(Int128, IntrinsicConversionTest) {
__int128 intrinsic =
(static_cast<__int128>(0x3a5b76c209de76f6) << 64) + 0x1f25e1d63a2b46c5;
absl::int128 custom =
absl::MakeInt128(0x3a5b76c209de76f6, 0x1f25e1d63a2b46c5);
EXPECT_EQ(custom, absl::int128(intrinsic));
EXPECT_EQ(intrinsic, static_cast<__int128>(custom));
}
#endif // ABSL_HAVE_INTRINSIC_INT128
TEST(Int128, ConstexprTest) {
constexpr absl::int128 zero = absl::int128();
constexpr absl::int128 one = 1;
constexpr absl::int128 minus_two = -2;
constexpr absl::int128 min = absl::Int128Min();
constexpr absl::int128 max = absl::Int128Max();
EXPECT_EQ(zero, absl::int128(0));
EXPECT_EQ(one, absl::int128(1));
EXPECT_EQ(minus_two, absl::MakeInt128(-1, -2));
EXPECT_GT(max, one);
EXPECT_LT(min, minus_two);
}
TEST(Int128, ComparisonTest) {
struct TestCase {
absl::int128 smaller;
absl::int128 larger;
};
TestCase cases[] = {
{absl::int128(0), absl::int128(123)},
{absl::MakeInt128(-12, 34), absl::MakeInt128(12, 34)},
{absl::MakeInt128(1, 1000), absl::MakeInt128(1000, 1)},
{absl::MakeInt128(-1000, 1000), absl::MakeInt128(-1, 1)},
};
for (const TestCase& pair : cases) {
SCOPED_TRACE(::testing::Message() << "pair.smaller = " << pair.smaller
<< "; pair.larger = " << pair.larger);
EXPECT_TRUE(pair.smaller == pair.smaller); // NOLINT(readability/check)
EXPECT_TRUE(pair.larger == pair.larger); // NOLINT(readability/check)
EXPECT_FALSE(pair.smaller == pair.larger); // NOLINT(readability/check)
EXPECT_TRUE(pair.smaller != pair.larger); // NOLINT(readability/check)
EXPECT_FALSE(pair.smaller != pair.smaller); // NOLINT(readability/check)
EXPECT_FALSE(pair.larger != pair.larger); // NOLINT(readability/check)
EXPECT_TRUE(pair.smaller < pair.larger); // NOLINT(readability/check)
EXPECT_FALSE(pair.larger < pair.smaller); // NOLINT(readability/check)
EXPECT_TRUE(pair.larger > pair.smaller); // NOLINT(readability/check)
EXPECT_FALSE(pair.smaller > pair.larger); // NOLINT(readability/check)
EXPECT_TRUE(pair.smaller <= pair.larger); // NOLINT(readability/check)
EXPECT_FALSE(pair.larger <= pair.smaller); // NOLINT(readability/check)
EXPECT_TRUE(pair.smaller <= pair.smaller); // NOLINT(readability/check)
EXPECT_TRUE(pair.larger <= pair.larger); // NOLINT(readability/check)
EXPECT_TRUE(pair.larger >= pair.smaller); // NOLINT(readability/check)
EXPECT_FALSE(pair.smaller >= pair.larger); // NOLINT(readability/check)
EXPECT_TRUE(pair.smaller >= pair.smaller); // NOLINT(readability/check)
EXPECT_TRUE(pair.larger >= pair.larger); // NOLINT(readability/check)
}
}
TEST(Int128, UnaryNegationTest) {
int64_t values64[] = {0, 1, 12345, 0x4000000000000000,
std::numeric_limits<int64_t>::max()};
for (int64_t value : values64) {
SCOPED_TRACE(::testing::Message() << "value = " << value);
EXPECT_EQ(absl::int128(-value), -absl::int128(value));
EXPECT_EQ(absl::int128(value), -absl::int128(-value));
EXPECT_EQ(absl::MakeInt128(-value, 0), -absl::MakeInt128(value, 0));
EXPECT_EQ(absl::MakeInt128(value, 0), -absl::MakeInt128(-value, 0));
}
}
TEST(Int128, LogicalNotTest) {
EXPECT_TRUE(!absl::int128(0));
for (int i = 0; i < 64; ++i) {
EXPECT_FALSE(!absl::MakeInt128(0, uint64_t{1} << i));
}
for (int i = 0; i < 63; ++i) {
EXPECT_FALSE(!absl::MakeInt128(int64_t{1} << i, 0));
}
}
TEST(Int128, AdditionSubtractionTest) {
// 64 bit pairs that will not cause overflow / underflow. These test negative
// carry; positive carry must be checked separately.
std::pair<int64_t, int64_t> cases[]{
{0, 0}, // 0, 0
{0, 2945781290834}, // 0, +
{1908357619234, 0}, // +, 0
{0, -1204895918245}, // 0, -
{-2957928523560, 0}, // -, 0
{89023982312461, 98346012567134}, // +, +
{-63454234568239, -23456235230773}, // -, -
{98263457263502, -21428561935925}, // +, -
{-88235237438467, 15923659234573}, // -, +
};
for (const auto& pair : cases) {
SCOPED_TRACE(::testing::Message()
<< "pair = {" << pair.first << ", " << pair.second << '}');
EXPECT_EQ(absl::int128(pair.first + pair.second),
absl::int128(pair.first) + absl::int128(pair.second));
EXPECT_EQ(absl::int128(pair.second + pair.first),
absl::int128(pair.second) += absl::int128(pair.first));
EXPECT_EQ(absl::int128(pair.first - pair.second),
absl::int128(pair.first) - absl::int128(pair.second));
EXPECT_EQ(absl::int128(pair.second - pair.first),
absl::int128(pair.second) -= absl::int128(pair.first));
EXPECT_EQ(
absl::MakeInt128(pair.second + pair.first, 0),
absl::MakeInt128(pair.second, 0) + absl::MakeInt128(pair.first, 0));
EXPECT_EQ(
absl::MakeInt128(pair.first + pair.second, 0),
absl::MakeInt128(pair.first, 0) += absl::MakeInt128(pair.second, 0));
EXPECT_EQ(
absl::MakeInt128(pair.second - pair.first, 0),
absl::MakeInt128(pair.second, 0) - absl::MakeInt128(pair.first, 0));
EXPECT_EQ(
absl::MakeInt128(pair.first - pair.second, 0),
absl::MakeInt128(pair.first, 0) -= absl::MakeInt128(pair.second, 0));
}
// check positive carry
EXPECT_EQ(absl::MakeInt128(31, 0),
absl::MakeInt128(20, 1) +
absl::MakeInt128(10, std::numeric_limits<uint64_t>::max()));
}
TEST(Int128, IncrementDecrementTest) {
absl::int128 value = 0;
EXPECT_EQ(0, value++);
EXPECT_EQ(1, value);
EXPECT_EQ(1, value--);
EXPECT_EQ(0, value);
EXPECT_EQ(-1, --value);
EXPECT_EQ(-1, value);
EXPECT_EQ(0, ++value);
EXPECT_EQ(0, value);
}
TEST(Int128, MultiplicationTest) {
// 1 bit x 1 bit, and negative combinations
for (int i = 0; i < 64; ++i) {
for (int j = 0; j < 127 - i; ++j) {
SCOPED_TRACE(::testing::Message() << "i = " << i << "; j = " << j);
absl::int128 a = absl::int128(1) << i;
absl::int128 b = absl::int128(1) << j;
absl::int128 c = absl::int128(1) << (i + j);
EXPECT_EQ(c, a * b);
EXPECT_EQ(-c, -a * b);
EXPECT_EQ(-c, a * -b);
EXPECT_EQ(c, -a * -b);
EXPECT_EQ(c, absl::int128(a) *= b);
EXPECT_EQ(-c, absl::int128(-a) *= b);
EXPECT_EQ(-c, absl::int128(a) *= -b);
EXPECT_EQ(c, absl::int128(-a) *= -b);
}
}
// Pairs of random values that will not overflow signed 64-bit multiplication
std::pair<int64_t, int64_t> small_values[] = {
{0x5e61, 0xf29f79ca14b4}, // +, +
{0x3e033b, -0x612c0ee549}, // +, -
{-0x052ce7e8, 0x7c728f0f}, // -, +
{-0x3af7054626, -0xfb1e1d}, // -, -
};
for (const std::pair<int64_t, int64_t>& pair : small_values) {
SCOPED_TRACE(::testing::Message()
<< "pair = {" << pair.first << ", " << pair.second << '}');
EXPECT_EQ(absl::int128(pair.first * pair.second),
absl::int128(pair.first) * absl::int128(pair.second));
EXPECT_EQ(absl::int128(pair.first * pair.second),
absl::int128(pair.first) *= absl::int128(pair.second));
EXPECT_EQ(absl::MakeInt128(pair.first * pair.second, 0),
absl::MakeInt128(pair.first, 0) * absl::int128(pair.second));
EXPECT_EQ(absl::MakeInt128(pair.first * pair.second, 0),
absl::MakeInt128(pair.first, 0) *= absl::int128(pair.second));
}
// Pairs of positive random values that will not overflow 64-bit
// multiplication and can be left shifted by 32 without overflow
std::pair<int64_t, int64_t> small_values2[] = {
{0x1bb0a110, 0x31487671},
{0x4792784e, 0x28add7d7},
{0x7b66553a, 0x11dff8ef},
};
for (const std::pair<int64_t, int64_t>& pair : small_values2) {
SCOPED_TRACE(::testing::Message()
<< "pair = {" << pair.first << ", " << pair.second << '}');
absl::int128 a = absl::int128(pair.first << 32);
absl::int128 b = absl::int128(pair.second << 32);
absl::int128 c = absl::MakeInt128(pair.first * pair.second, 0);
EXPECT_EQ(c, a * b);
EXPECT_EQ(-c, -a * b);
EXPECT_EQ(-c, a * -b);
EXPECT_EQ(c, -a * -b);
EXPECT_EQ(c, absl::int128(a) *= b);
EXPECT_EQ(-c, absl::int128(-a) *= b);
EXPECT_EQ(-c, absl::int128(a) *= -b);
EXPECT_EQ(c, absl::int128(-a) *= -b);
}
// check 0, 1, and -1 behavior with large values
absl::int128 large_values[] = {
{absl::MakeInt128(0xd66f061af02d0408, 0x727d2846cb475b53)},
{absl::MakeInt128(0x27b8d5ed6104452d, 0x03f8a33b0ee1df4f)},
{-absl::MakeInt128(0x621b6626b9e8d042, 0x27311ac99df00938)},
{-absl::MakeInt128(0x34e0656f1e95fb60, 0x4281cfd731257a47)},
};
for (absl::int128 value : large_values) {
EXPECT_EQ(0, 0 * value);
EXPECT_EQ(0, value * 0);
EXPECT_EQ(0, absl::int128(0) *= value);
EXPECT_EQ(0, value *= 0);
EXPECT_EQ(value, 1 * value);
EXPECT_EQ(value, value * 1);
EXPECT_EQ(value, absl::int128(1) *= value);
EXPECT_EQ(value, value *= 1);
EXPECT_EQ(-value, -1 * value);
EXPECT_EQ(-value, value * -1);
EXPECT_EQ(-value, absl::int128(-1) *= value);
EXPECT_EQ(-value, value *= -1);
}
// Manually calculated random large value cases
EXPECT_EQ(absl::MakeInt128(0xcd0efd3442219bb, 0xde47c05bcd9df6e1),
absl::MakeInt128(0x7c6448, 0x3bc4285c47a9d253) * 0x1a6037537b);
EXPECT_EQ(-absl::MakeInt128(0x1f8f149850b1e5e6, 0x1e50d6b52d272c3e),
-absl::MakeInt128(0x23, 0x2e68a513ca1b8859) * 0xe5a434cd14866e);
EXPECT_EQ(-absl::MakeInt128(0x55cae732029d1fce, 0xca6474b6423263e4),
0xa9b98a8ddf66bc * -absl::MakeInt128(0x81, 0x672e58231e2469d7));
EXPECT_EQ(absl::MakeInt128(0x19c8b7620b507dc4, 0xfec042b71a5f29a4),
-0x3e39341147 * -absl::MakeInt128(0x6a14b2, 0x5ed34cca42327b3c));
EXPECT_EQ(absl::MakeInt128(0xcd0efd3442219bb, 0xde47c05bcd9df6e1),
absl::MakeInt128(0x7c6448, 0x3bc4285c47a9d253) *= 0x1a6037537b);
EXPECT_EQ(-absl::MakeInt128(0x1f8f149850b1e5e6, 0x1e50d6b52d272c3e),
-absl::MakeInt128(0x23, 0x2e68a513ca1b8859) *= 0xe5a434cd14866e);
EXPECT_EQ(-absl::MakeInt128(0x55cae732029d1fce, 0xca6474b6423263e4),
absl::int128(0xa9b98a8ddf66bc) *=
-absl::MakeInt128(0x81, 0x672e58231e2469d7));
EXPECT_EQ(absl::MakeInt128(0x19c8b7620b507dc4, 0xfec042b71a5f29a4),
absl::int128(-0x3e39341147) *=
-absl::MakeInt128(0x6a14b2, 0x5ed34cca42327b3c));
}
TEST(Int128, DivisionAndModuloTest) {
// Check against 64 bit division and modulo operators with a sample of
// randomly generated pairs.
std::pair<int64_t, int64_t> small_pairs[] = {
{0x15f2a64138, 0x67da05}, {0x5e56d194af43045f, 0xcf1543fb99},
{0x15e61ed052036a, -0xc8e6}, {0x88125a341e85, -0xd23fb77683},
{-0xc06e20, 0x5a}, {-0x4f100219aea3e85d, 0xdcc56cb4efe993},
{-0x168d629105, -0xa7}, {-0x7b44e92f03ab2375, -0x6516},
};
for (const std::pair<int64_t, int64_t>& pair : small_pairs) {
SCOPED_TRACE(::testing::Message()
<< "pair = {" << pair.first << ", " << pair.second << '}');
absl::int128 dividend = pair.first;
absl::int128 divisor = pair.second;
int64_t quotient = pair.first / pair.second;
int64_t remainder = pair.first % pair.second;
EXPECT_EQ(quotient, dividend / divisor);
EXPECT_EQ(quotient, absl::int128(dividend) /= divisor);
EXPECT_EQ(remainder, dividend % divisor);
EXPECT_EQ(remainder, absl::int128(dividend) %= divisor);
}
// Test behavior with 0, 1, and -1 with a sample of randomly generated large
// values.
absl::int128 values[] = {
absl::MakeInt128(0x63d26ee688a962b2, 0x9e1411abda5c1d70),
absl::MakeInt128(0x152f385159d6f986, 0xbf8d48ef63da395d),
-absl::MakeInt128(0x3098d7567030038c, 0x14e7a8a098dc2164),
-absl::MakeInt128(0x49a037aca35c809f, 0xa6a87525480ef330),
};
for (absl::int128 value : values) {
SCOPED_TRACE(::testing::Message() << "value = " << value);
EXPECT_EQ(0, 0 / value);
EXPECT_EQ(0, absl::int128(0) /= value);
EXPECT_EQ(0, 0 % value);
EXPECT_EQ(0, absl::int128(0) %= value);
EXPECT_EQ(value, value / 1);
EXPECT_EQ(value, absl::int128(value) /= 1);
EXPECT_EQ(0, value % 1);
EXPECT_EQ(0, absl::int128(value) %= 1);
EXPECT_EQ(-value, value / -1);
EXPECT_EQ(-value, absl::int128(value) /= -1);
EXPECT_EQ(0, value % -1);
EXPECT_EQ(0, absl::int128(value) %= -1);
}
// Min and max values
EXPECT_EQ(0, absl::Int128Max() / absl::Int128Min());
EXPECT_EQ(absl::Int128Max(), absl::Int128Max() % absl::Int128Min());
EXPECT_EQ(-1, absl::Int128Min() / absl::Int128Max());
EXPECT_EQ(-1, absl::Int128Min() % absl::Int128Max());
// Power of two division and modulo of random large dividends
absl::int128 positive_values[] = {
absl::MakeInt128(0x21e1a1cc69574620, 0xe7ac447fab2fc869),
absl::MakeInt128(0x32c2ff3ab89e66e8, 0x03379a613fd1ce74),
absl::MakeInt128(0x6f32ca786184dcaf, 0x046f9c9ecb3a9ce1),
absl::MakeInt128(0x1aeb469dd990e0ee, 0xda2740f243cd37eb),
};
for (absl::int128 value : positive_values) {
for (int i = 0; i < 127; ++i) {
SCOPED_TRACE(::testing::Message()
<< "value = " << value << "; i = " << i);
absl::int128 power_of_two = absl::int128(1) << i;
EXPECT_EQ(value >> i, value / power_of_two);
EXPECT_EQ(value >> i, absl::int128(value) /= power_of_two);
EXPECT_EQ(value & (power_of_two - 1), value % power_of_two);
EXPECT_EQ(value & (power_of_two - 1),
absl::int128(value) %= power_of_two);
}
}
// Manually calculated cases with random large dividends
struct DivisionModCase {
absl::int128 dividend;
absl::int128 divisor;
absl::int128 quotient;
absl::int128 remainder;
};
DivisionModCase manual_cases[] = {
{absl::MakeInt128(0x6ada48d489007966, 0x3c9c5c98150d5d69),
absl::MakeInt128(0x8bc308fb, 0x8cb9cc9a3b803344), 0xc3b87e08,
absl::MakeInt128(0x1b7db5e1, 0xd9eca34b7af04b49)},
{absl::MakeInt128(0xd6946511b5b, 0x4886c5c96546bf5f),
-absl::MakeInt128(0x263b, 0xfd516279efcfe2dc), -0x59cbabf0,
absl::MakeInt128(0x622, 0xf462909155651d1f)},
{-absl::MakeInt128(0x33db734f9e8d1399, 0x8447ac92482bca4d), 0x37495078240,
-absl::MakeInt128(0xf01f1, 0xbc0368bf9a77eae8), -0x21a508f404d},
{-absl::MakeInt128(0x13f837b409a07e7d, 0x7fc8e248a7d73560), -0x1b9f,
absl::MakeInt128(0xb9157556d724, 0xb14f635714d7563e), -0x1ade},
};
for (const DivisionModCase test_case : manual_cases) {
EXPECT_EQ(test_case.quotient, test_case.dividend / test_case.divisor);
EXPECT_EQ(test_case.quotient,
absl::int128(test_case.dividend) /= test_case.divisor);
EXPECT_EQ(test_case.remainder, test_case.dividend % test_case.divisor);
EXPECT_EQ(test_case.remainder,
absl::int128(test_case.dividend) %= test_case.divisor);
}
}
TEST(Int128, BitwiseLogicTest) {
EXPECT_EQ(absl::int128(-1), ~absl::int128(0));
absl::int128 values[]{
0, -1, 0xde400bee05c3ff6b, absl::MakeInt128(0x7f32178dd81d634a, 0),
absl::MakeInt128(0xaf539057055613a9, 0x7d104d7d946c2e4d)};
for (absl::int128 value : values) {
EXPECT_EQ(value, ~~value);
EXPECT_EQ(value, value | value);
EXPECT_EQ(value, value & value);
EXPECT_EQ(0, value ^ value);
EXPECT_EQ(value, absl::int128(value) |= value);
EXPECT_EQ(value, absl::int128(value) &= value);
EXPECT_EQ(0, absl::int128(value) ^= value);
EXPECT_EQ(value, value | 0);
EXPECT_EQ(0, value & 0);
EXPECT_EQ(value, value ^ 0);
EXPECT_EQ(absl::int128(-1), value | absl::int128(-1));
EXPECT_EQ(value, value & absl::int128(-1));
EXPECT_EQ(~value, value ^ absl::int128(-1));
}
// small sample of randomly generated int64_t's
std::pair<int64_t, int64_t> pairs64[]{
{0x7f86797f5e991af4, 0x1ee30494fb007c97},
{0x0b278282bacf01af, 0x58780e0a57a49e86},
{0x059f266ccb93a666, 0x3d5b731bae9286f5},
{0x63c0c4820f12108c, 0x58166713c12e1c3a},
{0x381488bb2ed2a66e, 0x2220a3eb76a3698c},
{0x2a0a0dfb81e06f21, 0x4b60585927f5523c},
{0x555b1c3a03698537, 0x25478cd19d8e53cb},
{0x4750f6f27d779225, 0x16397553c6ff05fc},
};
for (const std::pair<int64_t, int64_t>& pair : pairs64) {
SCOPED_TRACE(::testing::Message()
<< "pair = {" << pair.first << ", " << pair.second << '}');
EXPECT_EQ(absl::MakeInt128(~pair.first, ~pair.second),
~absl::MakeInt128(pair.first, pair.second));
EXPECT_EQ(absl::int128(pair.first & pair.second),
absl::int128(pair.first) & absl::int128(pair.second));
EXPECT_EQ(absl::int128(pair.first | pair.second),
absl::int128(pair.first) | absl::int128(pair.second));
EXPECT_EQ(absl::int128(pair.first ^ pair.second),
absl::int128(pair.first) ^ absl::int128(pair.second));
EXPECT_EQ(absl::int128(pair.first & pair.second),
absl::int128(pair.first) &= absl::int128(pair.second));
EXPECT_EQ(absl::int128(pair.first | pair.second),
absl::int128(pair.first) |= absl::int128(pair.second));
EXPECT_EQ(absl::int128(pair.first ^ pair.second),
absl::int128(pair.first) ^= absl::int128(pair.second));
EXPECT_EQ(
absl::MakeInt128(pair.first & pair.second, 0),
absl::MakeInt128(pair.first, 0) & absl::MakeInt128(pair.second, 0));
EXPECT_EQ(
absl::MakeInt128(pair.first | pair.second, 0),
absl::MakeInt128(pair.first, 0) | absl::MakeInt128(pair.second, 0));
EXPECT_EQ(
absl::MakeInt128(pair.first ^ pair.second, 0),
absl::MakeInt128(pair.first, 0) ^ absl::MakeInt128(pair.second, 0));
EXPECT_EQ(
absl::MakeInt128(pair.first & pair.second, 0),
absl::MakeInt128(pair.first, 0) &= absl::MakeInt128(pair.second, 0));
EXPECT_EQ(
absl::MakeInt128(pair.first | pair.second, 0),
absl::MakeInt128(pair.first, 0) |= absl::MakeInt128(pair.second, 0));
EXPECT_EQ(
absl::MakeInt128(pair.first ^ pair.second, 0),
absl::MakeInt128(pair.first, 0) ^= absl::MakeInt128(pair.second, 0));
}
}
TEST(Int128, BitwiseShiftTest) {
for (int i = 0; i < 64; ++i) {
for (int j = 0; j <= i; ++j) {
// Left shift from j-th bit to i-th bit.
SCOPED_TRACE(::testing::Message() << "i = " << i << "; j = " << j);
EXPECT_EQ(uint64_t{1} << i, absl::int128(uint64_t{1} << j) << (i - j));
EXPECT_EQ(uint64_t{1} << i, absl::int128(uint64_t{1} << j) <<= (i - j));
}
}
for (int i = 0; i < 63; ++i) {
for (int j = 0; j < 64; ++j) {
// Left shift from j-th bit to (i + 64)-th bit.
SCOPED_TRACE(::testing::Message() << "i = " << i << "; j = " << j);
EXPECT_EQ(absl::MakeInt128(uint64_t{1} << i, 0),
absl::int128(uint64_t{1} << j) << (i + 64 - j));
EXPECT_EQ(absl::MakeInt128(uint64_t{1} << i, 0),
absl::int128(uint64_t{1} << j) <<= (i + 64 - j));
}
for (int j = 0; j <= i; ++j) {
// Left shift from (j + 64)-th bit to (i + 64)-th bit.
SCOPED_TRACE(::testing::Message() << "i = " << i << "; j = " << j);
EXPECT_EQ(absl::MakeInt128(uint64_t{1} << i, 0),
absl::MakeInt128(uint64_t{1} << j, 0) << (i - j));
EXPECT_EQ(absl::MakeInt128(uint64_t{1} << i, 0),
absl::MakeInt128(uint64_t{1} << j, 0) <<= (i - j));
}
}
for (int i = 0; i < 64; ++i) {
for (int j = i; j < 64; ++j) {
// Right shift from j-th bit to i-th bit.
SCOPED_TRACE(::testing::Message() << "i = " << i << "; j = " << j);
EXPECT_EQ(uint64_t{1} << i, absl::int128(uint64_t{1} << j) >> (j - i));
EXPECT_EQ(uint64_t{1} << i, absl::int128(uint64_t{1} << j) >>= (j - i));
}
for (int j = 0; j < 63; ++j) {
// Right shift from (j + 64)-th bit to i-th bit.
SCOPED_TRACE(::testing::Message() << "i = " << i << "; j = " << j);
EXPECT_EQ(uint64_t{1} << i,
absl::MakeInt128(uint64_t{1} << j, 0) >> (j + 64 - i));
EXPECT_EQ(uint64_t{1} << i,
absl::MakeInt128(uint64_t{1} << j, 0) >>= (j + 64 - i));
}
}
for (int i = 0; i < 63; ++i) {
for (int j = i; j < 63; ++j) {
// Right shift from (j + 64)-th bit to (i + 64)-th bit.
SCOPED_TRACE(::testing::Message() << "i = " << i << "; j = " << j);
EXPECT_EQ(absl::MakeInt128(uint64_t{1} << i, 0),
absl::MakeInt128(uint64_t{1} << j, 0) >> (j - i));
EXPECT_EQ(absl::MakeInt128(uint64_t{1} << i, 0),
absl::MakeInt128(uint64_t{1} << j, 0) >>= (j - i));
}
}
}
TEST(Int128, NumericLimitsTest) {
static_assert(std::numeric_limits<absl::int128>::is_specialized, "");
static_assert(std::numeric_limits<absl::int128>::is_signed, "");
static_assert(std::numeric_limits<absl::int128>::is_integer, "");
EXPECT_EQ(static_cast<int>(127 * std::log10(2)),
std::numeric_limits<absl::int128>::digits10);
EXPECT_EQ(absl::Int128Min(), std::numeric_limits<absl::int128>::min());
EXPECT_EQ(absl::Int128Min(), std::numeric_limits<absl::int128>::lowest());
EXPECT_EQ(absl::Int128Max(), std::numeric_limits<absl::int128>::max());
}
} // namespace

3
absl/random/internal/platform.h
View file

@ -162,7 +162,8 @@
// iOS does not support dispatch, even on x86, since applications
// should be bundled as fat binaries, with a different build tailored for
// each specific supported platform/architecture.
#if defined(__APPLE__) && (TARGET_OS_IPHONE || TARGET_OS_IPHONE_SIMULATOR)
#if (defined(TARGET_OS_IPHONE) && TARGET_OS_IPHONE) || \
(defined(TARGET_OS_IPHONE_SIMULATOR) && TARGET_OS_IPHONE_SIMULATOR)
#undef ABSL_RANDOM_INTERNAL_AES_DISPATCH
#define ABSL_RANDOM_INTERNAL_AES_DISPATCH 0
#endif

12
absl/strings/internal/str_format/arg.cc
View file

@ -32,6 +32,10 @@ void ReducePadding(size_t n, size_t *capacity) {
template <typename T>
struct MakeUnsigned : std::make_unsigned<T> {};
template <>
struct MakeUnsigned<absl::int128> {
using type = absl::uint128;
};
template <>
struct MakeUnsigned<absl::uint128> {
using type = absl::uint128;
};
@ -39,6 +43,8 @@ struct MakeUnsigned<absl::uint128> {
template <typename T>
struct IsSigned : std::is_signed<T> {};
template <>
struct IsSigned<absl::int128> : std::true_type {};
template <>
struct IsSigned<absl::uint128> : std::false_type {};
class ConvertedIntInfo {
@ -363,6 +369,11 @@ IntegralConvertResult FormatConvertImpl(unsigned long long v, // NOLINT
FormatSinkImpl *sink) {
return {ConvertIntArg(v, conv, sink)};
}
IntegralConvertResult FormatConvertImpl(absl::int128 v,
const ConversionSpec conv,
FormatSinkImpl *sink) {
return {ConvertIntArg(v, conv, sink)};
}
IntegralConvertResult FormatConvertImpl(absl::uint128 v,
const ConversionSpec conv,
FormatSinkImpl *sink) {
@ -372,6 +383,7 @@ IntegralConvertResult FormatConvertImpl(absl::uint128 v,
ABSL_INTERNAL_FORMAT_DISPATCH_OVERLOADS_EXPAND_();
} // namespace str_format_internal
} // namespace absl

4
absl/strings/internal/str_format/arg.h
View file

@ -144,6 +144,8 @@ IntegralConvertResult FormatConvertImpl(long long v, // NOLINT
IntegralConvertResult FormatConvertImpl(unsigned long long v, // NOLINT
ConversionSpec conv,
FormatSinkImpl* sink);
IntegralConvertResult FormatConvertImpl(int128 v, ConversionSpec conv,
FormatSinkImpl* sink);
IntegralConvertResult FormatConvertImpl(uint128 v, ConversionSpec conv,
FormatSinkImpl* sink);
template <typename T, enable_if_t<std::is_same<T, bool>::value, int> = 0>
@ -408,6 +410,7 @@ class FormatArgImpl {
__VA_ARGS__); \
ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(unsigned long long, /* NOLINT */ \
__VA_ARGS__); \
ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(int128, __VA_ARGS__); \
ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(uint128, __VA_ARGS__); \
ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(float, __VA_ARGS__); \
ABSL_INTERNAL_FORMAT_DISPATCH_INSTANTIATE_(double, __VA_ARGS__); \
@ -418,6 +421,7 @@ class FormatArgImpl {
ABSL_INTERNAL_FORMAT_DISPATCH_OVERLOADS_EXPAND_(extern);
} // namespace str_format_internal
} // namespace absl

37
absl/strings/internal/str_format/convert_test.cc
View file

@ -390,7 +390,6 @@ typedef ::testing::Types<
AllIntTypes;
INSTANTIATE_TYPED_TEST_CASE_P(TypedFormatConvertTestWithAllIntTypes,
TypedFormatConvertTest, AllIntTypes);
TEST_F(FormatConvertTest, VectorBool) {
// Make sure vector<bool>'s values behave as bools.
std::vector<bool> v = {true, false};
@ -402,6 +401,42 @@ TEST_F(FormatConvertTest, VectorBool) {
FormatArgImpl(cv[0]), FormatArgImpl(cv[1])})));
}
TEST_F(FormatConvertTest, Int128) {
absl::int128 positive = static_cast<absl::int128>(0x1234567890abcdef) * 1979;
absl::int128 negative = -positive;
absl::int128 max = absl::Int128Max(), min = absl::Int128Min();
const FormatArgImpl args[] = {FormatArgImpl(positive),
FormatArgImpl(negative), FormatArgImpl(max),
FormatArgImpl(min)};
struct Case {
const char* format;
const char* expected;
} cases[] = {
{"%1$d", "2595989796776606496405"},
{"%1$30d", " 2595989796776606496405"},
{"%1$-30d", "2595989796776606496405 "},
{"%1$u", "2595989796776606496405"},
{"%1$x", "8cba9876066020f695"},
{"%2$d", "-2595989796776606496405"},
{"%2$30d", " -2595989796776606496405"},
{"%2$-30d", "-2595989796776606496405 "},
{"%2$u", "340282366920938460867384810655161715051"},
{"%2$x", "ffffffffffffff73456789f99fdf096b"},
{"%3$d", "170141183460469231731687303715884105727"},
{"%3$u", "170141183460469231731687303715884105727"},
{"%3$x", "7fffffffffffffffffffffffffffffff"},
{"%4$d", "-170141183460469231731687303715884105728"},
{"%4$x", "80000000000000000000000000000000"},
};
for (auto c : cases) {
UntypedFormatSpecImpl format(c.format);
EXPECT_EQ(c.expected, FormatPack(format, absl::MakeSpan(args)));
}
}
TEST_F(FormatConvertTest, Uint128) {
absl::uint128 v = static_cast<absl::uint128>(0x1234567890abcdef) * 1979;
absl::uint128 max = absl::Uint128Max();

5
absl/strings/string_view.h
View file

@ -290,7 +290,8 @@ class string_view {
constexpr const_reference at(size_type i) const {
return ABSL_PREDICT_TRUE(i < size())
? ptr_[i]
: (base_internal::ThrowStdOutOfRange("absl::string_view::at"),
: ((void)base_internal::ThrowStdOutOfRange(
"absl::string_view::at"),
ptr_[i]);
}
@ -511,7 +512,7 @@ class string_view {
(std::numeric_limits<difference_type>::max)();
static constexpr size_type CheckLengthInternal(size_type len) {
return ABSL_ASSERT(len <= kMaxSize), len;
return (void)ABSL_ASSERT(len <= kMaxSize), len;
}
static constexpr size_type StrlenInternal(const char* str) {

3
absl/time/internal/test_util.cc
View file

@ -116,7 +116,10 @@ std::unique_ptr<cctz::ZoneInfoSource> TestFactory(
} // namespace
#if !defined(__MINGW32__)
// MinGW does not support the weak symbol extension mechanism.
ZoneInfoSourceFactory zone_info_source_factory = TestFactory;
#endif
} // namespace cctz_extension
} // namespace time_internal

3
absl/time/time.h
View file

@ -1412,8 +1412,7 @@ constexpr Duration FromInt64(int64_t v, std::ratio<3600>) {
// IsValidRep64<T>(0) is true if the expression `int64_t{std::declval<T>()}` is
// valid. That is, if a T can be assigned to an int64_t without narrowing.
template <typename T>
constexpr auto IsValidRep64(int)
-> decltype(int64_t{std::declval<T>()}, bool()) {
constexpr auto IsValidRep64(int) -> decltype(int64_t{std::declval<T>()} == 0) {
return true;
}
template <typename T>