runtime/temporary-stack.cpp - llvm-project/flang - Git at Google

 //===-- runtime/temporary-stack.cpp ---------------------------------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 // Implements std::vector like storage for a dynamically resizable number of
 // temporaries. For use in HLFIR lowering.

 #include "flang/Runtime/temporary-stack.h"
 #include "terminator.h"
 #include "flang/ISO_Fortran_binding_wrapper.h"
 #include "flang/Runtime/assign.h"
 #include "flang/Runtime/descriptor.h"
 #include "flang/Runtime/memory.h"

 namespace {

 using namespace Fortran::runtime;

 // the number of elements to allocate when first creating the vector
 constexpr size_t INITIAL_ALLOC = 8;

 /// To store C style data. Does not run constructors/destructors.
 /// Not using std::vector to avoid linking the runtime library to stdc++
 template <bool COPY_VALUES> class DescriptorStorage final {
   using size_type = uint64_t; // see checkedMultiply()

   size_type capacity_{0};
   size_type size_{0};
   Descriptor **data_{nullptr};
   Terminator terminator_;

   // return true on overflow
   static bool checkedMultiply(size_type x, size_type y, size_type &res);

   void resize(size_type newCapacity);

   Descriptor *cloneDescriptor(const Descriptor &source);

 public:
   DescriptorStorage(const char *sourceFile, int line);
   ~DescriptorStorage();

   // `new` but using the runtime allocation API
   static inline DescriptorStorage *allocate(const char *sourceFile, int line) {
     Terminator term{sourceFile, line};
     void *ptr = AllocateMemoryOrCrash(term, sizeof(DescriptorStorage));
     return new (ptr) DescriptorStorage{sourceFile, line};
   }

   // `delete` but using the runtime allocation API
   static inline void destroy(DescriptorStorage *instance) {
     instance->~DescriptorStorage();
     FreeMemory(instance);
   }

   // clones a descriptor into this storage
   void push(const Descriptor &source);

   // out must be big enough to hold a descriptor of the right rank and addendum
   void pop(Descriptor &out);

   // out must be big enough to hold a descriptor of the right rank and addendum
   void at(size_type i, Descriptor &out);
 };

 using ValueStack = DescriptorStorage</*COPY_VALUES=*/true>;
 using DescriptorStack = DescriptorStorage</*COPY_VALUES=*/false>;
 } // namespace

 template <bool COPY_VALUES>
 bool DescriptorStorage<COPY_VALUES>::checkedMultiply(
     size_type x, size_type y, size_type &res) {
   // TODO: c++20 [[unlikely]]
   if (x > UINT64_MAX / y) {
     return true;
   }
   res = x * y;
   return false;
 }

 template <bool COPY_VALUES>
 void DescriptorStorage<COPY_VALUES>::resize(size_type newCapacity) {
   if (newCapacity <= capacity_) {
     return;
   }
   size_type bytes;
   if (checkedMultiply(newCapacity, sizeof(Descriptor *), bytes)) {
     terminator_.Crash("temporary-stack: out of memory");
   }
   Descriptor **newData =
       static_cast<Descriptor **>(AllocateMemoryOrCrash(terminator_, bytes));
   // "memcpy" in glibc has a "nonnull" attribute on the source pointer.
   // Avoid passing a null pointer, since it would result in an undefined
   // behavior.
   if (data_ != nullptr) {
     memcpy(newData, data_, capacity_ * sizeof(Descriptor *));
     FreeMemory(data_);
   }
   data_ = newData;
   capacity_ = newCapacity;
 }

 template <bool COPY_VALUES>
 Descriptor *DescriptorStorage<COPY_VALUES>::cloneDescriptor(
     const Descriptor &source) {
   const std::size_t bytes = source.SizeInBytes();
   void *memory = AllocateMemoryOrCrash(terminator_, bytes);
   Descriptor *desc = new (memory) Descriptor{source};
   return desc;
 }

 template <bool COPY_VALUES>
 DescriptorStorage<COPY_VALUES>::DescriptorStorage(
     const char *sourceFile, int line)
     : terminator_{sourceFile, line} {
   resize(INITIAL_ALLOC);
 }

 template <bool COPY_VALUES>
 DescriptorStorage<COPY_VALUES>::~DescriptorStorage() {
   for (size_type i = 0; i < size_; ++i) {
     Descriptor *element = data_[i];
     if constexpr (COPY_VALUES) {
       element->Destroy(false, true);
     }
     FreeMemory(element);
   }
   FreeMemory(data_);
 }

 template <bool COPY_VALUES>
 void DescriptorStorage<COPY_VALUES>::push(const Descriptor &source) {
   if (size_ == capacity_) {
     size_type newSize;
     if (checkedMultiply(capacity_, 2, newSize)) {
       terminator_.Crash("temporary-stack: out of address space");
     }
     resize(newSize);
   }
   data_[size_] = cloneDescriptor(source);
   Descriptor &box = *data_[size_];
   size_ += 1;

   if constexpr (COPY_VALUES) {
     // copy the data pointed to by the box
     box.set_base_addr(nullptr);
     box.Allocate();
     RTNAME(AssignTemporary)
     (box, source, terminator_.sourceFileName(), terminator_.sourceLine());
   }
 }

 template <bool COPY_VALUES>
 void DescriptorStorage<COPY_VALUES>::pop(Descriptor &out) {
   if (size_ == 0) {
     terminator_.Crash("temporary-stack: pop empty storage");
   }
   size_ -= 1;
   Descriptor *ptr = data_[size_];
   out = *ptr; // Descriptor::operator= handles the different sizes
   FreeMemory(ptr);
 }

 template <bool COPY_VALUES>
 void DescriptorStorage<COPY_VALUES>::at(size_type i, Descriptor &out) {
   if (i >= size_) {
     terminator_.Crash("temporary-stack: out of bounds access");
   }
   Descriptor *ptr = data_[i];
   out = *ptr; // Descriptor::operator= handles the different sizes
 }

 inline static ValueStack *getValueStorage(void *opaquePtr) {
   return static_cast<ValueStack *>(opaquePtr);
 }
 inline static DescriptorStack *getDescriptorStorage(void *opaquePtr) {
   return static_cast<DescriptorStack *>(opaquePtr);
 }

 namespace Fortran::runtime {
 extern "C" {
 void *RTNAME(CreateValueStack)(const char *sourceFile, int line) {
   return ValueStack::allocate(sourceFile, line);
 }

 void RTNAME(PushValue)(void *opaquePtr, const Descriptor &value) {
   getValueStorage(opaquePtr)->push(value);
 }

 void RTNAME(PopValue)(void *opaquePtr, Descriptor &value) {
   getValueStorage(opaquePtr)->pop(value);
 }

 void RTNAME(ValueAt)(void *opaquePtr, uint64_t i, Descriptor &value) {
   getValueStorage(opaquePtr)->at(i, value);
 }

 void RTNAME(DestroyValueStack)(void *opaquePtr) {
   ValueStack::destroy(getValueStorage(opaquePtr));
 }

 void *RTNAME(CreateDescriptorStack)(const char *sourceFile, int line) {
   return DescriptorStack::allocate(sourceFile, line);
 }

 void RTNAME(PushDescriptor)(void *opaquePtr, const Descriptor &value) {
   getDescriptorStorage(opaquePtr)->push(value);
 }

 void RTNAME(PopDescriptor)(void *opaquePtr, Descriptor &value) {
   getDescriptorStorage(opaquePtr)->pop(value);
 }

 void RTNAME(DescriptorAt)(void *opaquePtr, uint64_t i, Descriptor &value) {
   getValueStorage(opaquePtr)->at(i, value);
 }

 void RTNAME(DestroyDescriptorStack)(void *opaquePtr) {
   DescriptorStack::destroy(getDescriptorStorage(opaquePtr));
 }

 } // extern "C"
 } // namespace Fortran::runtime
	//===-- runtime/temporary-stack.cpp ---------------------------------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	// Implements std::vector like storage for a dynamically resizable number of
	// temporaries. For use in HLFIR lowering.

	#include "flang/Runtime/temporary-stack.h"
	#include "terminator.h"
	#include "flang/ISO_Fortran_binding_wrapper.h"
	#include "flang/Runtime/assign.h"
	#include "flang/Runtime/descriptor.h"
	#include "flang/Runtime/memory.h"

	namespace {

	using namespace Fortran::runtime;

	// the number of elements to allocate when first creating the vector
	constexpr size_t INITIAL_ALLOC = 8;

	/// To store C style data. Does not run constructors/destructors.
	/// Not using std::vector to avoid linking the runtime library to stdc++
	template <bool COPY_VALUES> class DescriptorStorage final {
	using size_type = uint64_t; // see checkedMultiply()

	size_type capacity_{0};
	size_type size_{0};
	Descriptor **data_{nullptr};
	Terminator terminator_;

	// return true on overflow
	static bool checkedMultiply(size_type x, size_type y, size_type &res);

	void resize(size_type newCapacity);

	Descriptor *cloneDescriptor(const Descriptor &source);

	public:
	DescriptorStorage(const char *sourceFile, int line);
	~DescriptorStorage();

	// `new` but using the runtime allocation API
	static inline DescriptorStorage allocate(const char sourceFile, int line) {
	Terminator term{sourceFile, line};
	void *ptr = AllocateMemoryOrCrash(term, sizeof(DescriptorStorage));
	return new (ptr) DescriptorStorage{sourceFile, line};
	}

	// `delete` but using the runtime allocation API
	static inline void destroy(DescriptorStorage *instance) {
	instance->~DescriptorStorage();
	FreeMemory(instance);
	}

	// clones a descriptor into this storage
	void push(const Descriptor &source);

	// out must be big enough to hold a descriptor of the right rank and addendum
	void pop(Descriptor &out);

	// out must be big enough to hold a descriptor of the right rank and addendum
	void at(size_type i, Descriptor &out);
	};

	using ValueStack = DescriptorStorage</COPY_VALUES=/true>;
	using DescriptorStack = DescriptorStorage</COPY_VALUES=/false>;
	} // namespace

	template <bool COPY_VALUES>
	bool DescriptorStorage<COPY_VALUES>::checkedMultiply(
	size_type x, size_type y, size_type &res) {
	// TODO: c++20 [[unlikely]]
	if (x > UINT64_MAX / y) {
	return true;
	}
	res = x * y;
	return false;
	}

	template <bool COPY_VALUES>
	void DescriptorStorage<COPY_VALUES>::resize(size_type newCapacity) {
	if (newCapacity <= capacity_) {
	return;
	}
	size_type bytes;
	if (checkedMultiply(newCapacity, sizeof(Descriptor *), bytes)) {
	terminator_.Crash("temporary-stack: out of memory");
	}
	Descriptor **newData =
	static_cast<Descriptor **>(AllocateMemoryOrCrash(terminator_, bytes));
	// "memcpy" in glibc has a "nonnull" attribute on the source pointer.
	// Avoid passing a null pointer, since it would result in an undefined
	// behavior.
	if (data_ != nullptr) {
	memcpy(newData, data_, capacity_ * sizeof(Descriptor *));
	FreeMemory(data_);
	}
	data_ = newData;
	capacity_ = newCapacity;
	}

	template <bool COPY_VALUES>
	Descriptor *DescriptorStorage<COPY_VALUES>::cloneDescriptor(
	const Descriptor &source) {
	const std::size_t bytes = source.SizeInBytes();
	void *memory = AllocateMemoryOrCrash(terminator_, bytes);
	Descriptor *desc = new (memory) Descriptor{source};
	return desc;
	}

	template <bool COPY_VALUES>
	DescriptorStorage<COPY_VALUES>::DescriptorStorage(
	const char *sourceFile, int line)
	: terminator_{sourceFile, line} {
	resize(INITIAL_ALLOC);
	}

	template <bool COPY_VALUES>
	DescriptorStorage<COPY_VALUES>::~DescriptorStorage() {
	for (size_type i = 0; i < size_; ++i) {
	Descriptor *element = data_[i];
	if constexpr (COPY_VALUES) {
	element->Destroy(false, true);
	}
	FreeMemory(element);
	}
	FreeMemory(data_);
	}

	template <bool COPY_VALUES>
	void DescriptorStorage<COPY_VALUES>::push(const Descriptor &source) {
	if (size_ == capacity_) {
	size_type newSize;
	if (checkedMultiply(capacity_, 2, newSize)) {
	terminator_.Crash("temporary-stack: out of address space");
	}
	resize(newSize);
	}
	data_[size_] = cloneDescriptor(source);
	Descriptor &box = *data_[size_];
	size_ += 1;

	if constexpr (COPY_VALUES) {
	// copy the data pointed to by the box
	box.set_base_addr(nullptr);
	box.Allocate();
	RTNAME(AssignTemporary)
	(box, source, terminator_.sourceFileName(), terminator_.sourceLine());
	}
	}

	template <bool COPY_VALUES>
	void DescriptorStorage<COPY_VALUES>::pop(Descriptor &out) {
	if (size_ == 0) {
	terminator_.Crash("temporary-stack: pop empty storage");
	}
	size_ -= 1;
	Descriptor *ptr = data_[size_];
	out = *ptr; // Descriptor::operator= handles the different sizes
	FreeMemory(ptr);
	}

	template <bool COPY_VALUES>
	void DescriptorStorage<COPY_VALUES>::at(size_type i, Descriptor &out) {
	if (i >= size_) {
	terminator_.Crash("temporary-stack: out of bounds access");
	}
	Descriptor *ptr = data_[i];
	out = *ptr; // Descriptor::operator= handles the different sizes
	}

	inline static ValueStack getValueStorage(void opaquePtr) {
	return static_cast<ValueStack *>(opaquePtr);
	}
	inline static DescriptorStack getDescriptorStorage(void opaquePtr) {
	return static_cast<DescriptorStack *>(opaquePtr);
	}

	namespace Fortran::runtime {
	extern "C" {
	void RTNAME(CreateValueStack)(const char sourceFile, int line) {
	return ValueStack::allocate(sourceFile, line);
	}

	void RTNAME(PushValue)(void *opaquePtr, const Descriptor &value) {
	getValueStorage(opaquePtr)->push(value);
	}

	void RTNAME(PopValue)(void *opaquePtr, Descriptor &value) {
	getValueStorage(opaquePtr)->pop(value);
	}

	void RTNAME(ValueAt)(void *opaquePtr, uint64_t i, Descriptor &value) {
	getValueStorage(opaquePtr)->at(i, value);
	}

	void RTNAME(DestroyValueStack)(void *opaquePtr) {
	ValueStack::destroy(getValueStorage(opaquePtr));
	}

	void RTNAME(CreateDescriptorStack)(const char sourceFile, int line) {
	return DescriptorStack::allocate(sourceFile, line);
	}

	void RTNAME(PushDescriptor)(void *opaquePtr, const Descriptor &value) {
	getDescriptorStorage(opaquePtr)->push(value);
	}

	void RTNAME(PopDescriptor)(void *opaquePtr, Descriptor &value) {
	getDescriptorStorage(opaquePtr)->pop(value);
	}

	void RTNAME(DescriptorAt)(void *opaquePtr, uint64_t i, Descriptor &value) {
	getValueStorage(opaquePtr)->at(i, value);
	}

	void RTNAME(DestroyDescriptorStack)(void *opaquePtr) {
	DescriptorStack::destroy(getDescriptorStorage(opaquePtr));
	}

	} // extern "C"
	} // namespace Fortran::runtime