c10/util/SmallVector.cpp - platform/external/pytorch - Git at Google

 //===- llvm/ADT/SmallVector.cpp - 'Normally small' vectors ----------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // This file implements the SmallVector class.
 //
 //===----------------------------------------------------------------------===//

 // ATen: modified from llvm::SmallVector.
 // replaced llvm::safe_malloc with std::bad_alloc
 // deleted LLVM_ENABLE_EXCEPTIONS

 #include <c10/util/SmallVector.h>
 #include <cstdint>
 #include <stdexcept>
 #include <string>
 using namespace c10;

 // Check that no bytes are wasted and everything is well-aligned.
 namespace {
 // These structures may cause binary compat warnings on AIX. Suppress the
 // warning since we are only using these types for the static assertions below.
 #if defined(_AIX)
 #pragma GCC diagnostic push
 #pragma GCC diagnostic ignored "-Waix-compat"
 #endif
 struct Struct16B {
   alignas(16) void* X;
 };
 struct Struct32B {
   alignas(32) void* X;
 };
 #if defined(_AIX)
 #pragma GCC diagnostic pop
 #endif
 } // namespace
 static_assert(
     sizeof(SmallVector<void*, 0>) == sizeof(unsigned) * 2 + sizeof(void*),
     "wasted space in SmallVector size 0");
 static_assert(
     alignof(SmallVector<Struct16B, 0>) >= alignof(Struct16B),
     "wrong alignment for 16-byte aligned T");
 static_assert(
     alignof(SmallVector<Struct32B, 0>) >= alignof(Struct32B),
     "wrong alignment for 32-byte aligned T");
 static_assert(
     sizeof(SmallVector<Struct16B, 0>) >= alignof(Struct16B),
     "missing padding for 16-byte aligned T");
 static_assert(
     sizeof(SmallVector<Struct32B, 0>) >= alignof(Struct32B),
     "missing padding for 32-byte aligned T");
 static_assert(
     sizeof(SmallVector<void*, 1>) == sizeof(unsigned) * 2 + sizeof(void*) * 2,
     "wasted space in SmallVector size 1");

 static_assert(
     sizeof(SmallVector<char, 0>) == sizeof(void*) * 2 + sizeof(void*),
     "1 byte elements have word-sized type for size and capacity");

 /// Report that MinSize doesn't fit into this vector's size type. Throws
 /// std::length_error or calls report_fatal_error.
 [[noreturn]] static void report_size_overflow(size_t MinSize, size_t MaxSize);
 static void report_size_overflow(size_t MinSize, size_t MaxSize) {
   std::string Reason = "SmallVector unable to grow. Requested capacity (" +
       std::to_string(MinSize) +
       ") is larger than maximum value for size type (" +
       std::to_string(MaxSize) + ")";
   throw std::length_error(Reason);
 }

 /// Report that this vector is already at maximum capacity. Throws
 /// std::length_error or calls report_fatal_error.
 [[noreturn]] static void report_at_maximum_capacity(size_t MaxSize);
 static void report_at_maximum_capacity(size_t MaxSize) {
   std::string Reason =
       "SmallVector capacity unable to grow. Already at maximum size " +
       std::to_string(MaxSize);
   throw std::length_error(Reason);
 }

 // Note: Moving this function into the header may cause performance regression.
 template <class Size_T>
 static size_t getNewCapacity(size_t MinSize, size_t TSize, size_t OldCapacity) {
   constexpr size_t MaxSize = std::numeric_limits<Size_T>::max();

   // Ensure we can fit the new capacity.
   // This is only going to be applicable when the capacity is 32 bit.
   if (MinSize > MaxSize)
     report_size_overflow(MinSize, MaxSize);

   // Ensure we can meet the guarantee of space for at least one more element.
   // The above check alone will not catch the case where grow is called with a
   // default MinSize of 0, but the current capacity cannot be increased.
   // This is only going to be applicable when the capacity is 32 bit.
   if (OldCapacity == MaxSize)
     report_at_maximum_capacity(MaxSize);

   // In theory 2*capacity can overflow if the capacity is 64 bit, but the
   // original capacity would never be large enough for this to be a problem.
   size_t NewCapacity = 2 * OldCapacity + 1; // Always grow.
   return std::min(std::max(NewCapacity, MinSize), MaxSize);
 }

 // Note: Moving this function into the header may cause performance regression.
 template <class Size_T>
 void* SmallVectorBase<Size_T>::mallocForGrow(
     size_t MinSize,
     size_t TSize,
     size_t& NewCapacity) {
   NewCapacity = getNewCapacity<Size_T>(MinSize, TSize, this->capacity());
   // NOLINTNEXTLINE(cppcoreguidelines-no-malloc)
   auto Result = std::malloc(NewCapacity * TSize);
   if (Result == nullptr) {
     throw std::bad_alloc();
   }
   return Result;
 }

 // Note: Moving this function into the header may cause performance regression.
 template <class Size_T>
 void SmallVectorBase<Size_T>::grow_pod(
     void* FirstEl,
     size_t MinSize,
     size_t TSize) {
   size_t NewCapacity = getNewCapacity<Size_T>(MinSize, TSize, this->capacity());
   void* NewElts = nullptr;
   if (BeginX == FirstEl) {
     // NOLINTNEXTLINE(cppcoreguidelines-no-malloc)
     NewElts = std::malloc(NewCapacity * TSize);
     if (NewElts == nullptr) {
       throw std::bad_alloc();
     }

     // Copy the elements over.  No need to run dtors on PODs.
     memcpy(NewElts, this->BeginX, size() * TSize);
   } else {
     // If this wasn't grown from the inline copy, grow the allocated space.
     // NOLINTNEXTLINE(cppcoreguidelines-no-malloc)
     NewElts = std::realloc(this->BeginX, NewCapacity * TSize);
     if (NewElts == nullptr) {
       throw std::bad_alloc();
     }
   }

   this->BeginX = NewElts;
   this->Capacity = NewCapacity;
 }

 template class c10::SmallVectorBase<uint32_t>;

 // Disable the uint64_t instantiation for 32-bit builds.
 // Both uint32_t and uint64_t instantiations are needed for 64-bit builds.
 // This instantiation will never be used in 32-bit builds, and will cause
 // warnings when sizeof(Size_T) > sizeof(size_t).
 #if SIZE_MAX > UINT32_MAX
 template class c10::SmallVectorBase<uint64_t>;

 // Assertions to ensure this #if stays in sync with SmallVectorSizeType.
 static_assert(
     sizeof(SmallVectorSizeType<char>) == sizeof(uint64_t),
     "Expected SmallVectorBase<uint64_t> variant to be in use.");
 #else
 static_assert(
     sizeof(SmallVectorSizeType<char>) == sizeof(uint32_t),
     "Expected SmallVectorBase<uint32_t> variant to be in use.");
 #endif
	//===- llvm/ADT/SmallVector.cpp - 'Normally small' vectors ----------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements the SmallVector class.
	//
	//===----------------------------------------------------------------------===//

	// ATen: modified from llvm::SmallVector.
	// replaced llvm::safe_malloc with std::bad_alloc
	// deleted LLVM_ENABLE_EXCEPTIONS

	#include <c10/util/SmallVector.h>
	#include <cstdint>
	#include <stdexcept>
	#include <string>
	using namespace c10;

	// Check that no bytes are wasted and everything is well-aligned.
	namespace {
	// These structures may cause binary compat warnings on AIX. Suppress the
	// warning since we are only using these types for the static assertions below.
	#if defined(_AIX)
	#pragma GCC diagnostic push
	#pragma GCC diagnostic ignored "-Waix-compat"
	#endif
	struct Struct16B {
	alignas(16) void* X;
	};
	struct Struct32B {
	alignas(32) void* X;
	};
	#if defined(_AIX)
	#pragma GCC diagnostic pop
	#endif
	} // namespace
	static_assert(
	sizeof(SmallVector<void, 0>) == sizeof(unsigned) 2 + sizeof(void*),
	"wasted space in SmallVector size 0");
	static_assert(
	alignof(SmallVector<Struct16B, 0>) >= alignof(Struct16B),
	"wrong alignment for 16-byte aligned T");
	static_assert(
	alignof(SmallVector<Struct32B, 0>) >= alignof(Struct32B),
	"wrong alignment for 32-byte aligned T");
	static_assert(
	sizeof(SmallVector<Struct16B, 0>) >= alignof(Struct16B),
	"missing padding for 16-byte aligned T");
	static_assert(
	sizeof(SmallVector<Struct32B, 0>) >= alignof(Struct32B),
	"missing padding for 32-byte aligned T");
	static_assert(
	sizeof(SmallVector<void, 1>) == sizeof(unsigned) 2 + sizeof(void) 2,
	"wasted space in SmallVector size 1");

	static_assert(
	sizeof(SmallVector<char, 0>) == sizeof(void) 2 + sizeof(void*),
	"1 byte elements have word-sized type for size and capacity");

	/// Report that MinSize doesn't fit into this vector's size type. Throws
	/// std::length_error or calls report_fatal_error.
	[[noreturn]] static void report_size_overflow(size_t MinSize, size_t MaxSize);
	static void report_size_overflow(size_t MinSize, size_t MaxSize) {
	std::string Reason = "SmallVector unable to grow. Requested capacity (" +
	std::to_string(MinSize) +
	") is larger than maximum value for size type (" +
	std::to_string(MaxSize) + ")";
	throw std::length_error(Reason);
	}

	/// Report that this vector is already at maximum capacity. Throws
	/// std::length_error or calls report_fatal_error.
	[[noreturn]] static void report_at_maximum_capacity(size_t MaxSize);
	static void report_at_maximum_capacity(size_t MaxSize) {
	std::string Reason =
	"SmallVector capacity unable to grow. Already at maximum size " +
	std::to_string(MaxSize);
	throw std::length_error(Reason);
	}

	// Note: Moving this function into the header may cause performance regression.
	template <class Size_T>
	static size_t getNewCapacity(size_t MinSize, size_t TSize, size_t OldCapacity) {
	constexpr size_t MaxSize = std::numeric_limits<Size_T>::max();

	// Ensure we can fit the new capacity.
	// This is only going to be applicable when the capacity is 32 bit.
	if (MinSize > MaxSize)
	report_size_overflow(MinSize, MaxSize);

	// Ensure we can meet the guarantee of space for at least one more element.
	// The above check alone will not catch the case where grow is called with a
	// default MinSize of 0, but the current capacity cannot be increased.
	// This is only going to be applicable when the capacity is 32 bit.
	if (OldCapacity == MaxSize)
	report_at_maximum_capacity(MaxSize);

	// In theory 2*capacity can overflow if the capacity is 64 bit, but the
	// original capacity would never be large enough for this to be a problem.
	size_t NewCapacity = 2 * OldCapacity + 1; // Always grow.
	return std::min(std::max(NewCapacity, MinSize), MaxSize);
	}

	// Note: Moving this function into the header may cause performance regression.
	template <class Size_T>
	void* SmallVectorBase<Size_T>::mallocForGrow(
	size_t MinSize,
	size_t TSize,
	size_t& NewCapacity) {
	NewCapacity = getNewCapacity<Size_T>(MinSize, TSize, this->capacity());
	// NOLINTNEXTLINE(cppcoreguidelines-no-malloc)
	auto Result = std::malloc(NewCapacity * TSize);
	if (Result == nullptr) {
	throw std::bad_alloc();
	}
	return Result;
	}

	// Note: Moving this function into the header may cause performance regression.
	template <class Size_T>
	void SmallVectorBase<Size_T>::grow_pod(
	void* FirstEl,
	size_t MinSize,
	size_t TSize) {
	size_t NewCapacity = getNewCapacity<Size_T>(MinSize, TSize, this->capacity());
	void* NewElts = nullptr;
	if (BeginX == FirstEl) {
	// NOLINTNEXTLINE(cppcoreguidelines-no-malloc)
	NewElts = std::malloc(NewCapacity * TSize);
	if (NewElts == nullptr) {
	throw std::bad_alloc();
	}

	// Copy the elements over. No need to run dtors on PODs.
	memcpy(NewElts, this->BeginX, size() * TSize);
	} else {
	// If this wasn't grown from the inline copy, grow the allocated space.
	// NOLINTNEXTLINE(cppcoreguidelines-no-malloc)
	NewElts = std::realloc(this->BeginX, NewCapacity * TSize);
	if (NewElts == nullptr) {
	throw std::bad_alloc();
	}
	}

	this->BeginX = NewElts;
	this->Capacity = NewCapacity;
	}

	template class c10::SmallVectorBase<uint32_t>;

	// Disable the uint64_t instantiation for 32-bit builds.
	// Both uint32_t and uint64_t instantiations are needed for 64-bit builds.
	// This instantiation will never be used in 32-bit builds, and will cause
	// warnings when sizeof(Size_T) > sizeof(size_t).
	#if SIZE_MAX > UINT32_MAX
	template class c10::SmallVectorBase<uint64_t>;

	// Assertions to ensure this #if stays in sync with SmallVectorSizeType.
	static_assert(
	sizeof(SmallVectorSizeType<char>) == sizeof(uint64_t),
	"Expected SmallVectorBase<uint64_t> variant to be in use.");
	#else
	static_assert(
	sizeof(SmallVectorSizeType<char>) == sizeof(uint32_t),
	"Expected SmallVectorBase<uint32_t> variant to be in use.");
	#endif