src/assembler.cpp - SwiftShader - Git at Google

 //===- subzero/src/assembler.cpp - Assembler base class -------------------===//
 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.
 //
 // Modified by the Subzero authors.
 //
 //===----------------------------------------------------------------------===//
 //
 //                        The Subzero Code Generator
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file implements the Assembler class.
 //
 //===----------------------------------------------------------------------===//

 #include "assembler.h"
 #include "IceGlobalContext.h"
 #include "IceOperand.h"

 namespace Ice {

 static uintptr_t NewContents(Assembler &assembler, intptr_t capacity) {
   uintptr_t result = assembler.AllocateBytes(capacity);
   return result;
 }

 AssemblerFixup *AssemblerBuffer::createFixup(FixupKind Kind,
                                              const Constant *Value) {
   AssemblerFixup *F =
       new (assembler_.Allocate<AssemblerFixup>()) AssemblerFixup();
   F->set_position(0);
   F->set_kind(Kind);
   F->set_value(Value);
   fixups_.push_back(F);
   return F;
 }

 #ifndef NDEBUG
 AssemblerBuffer::EnsureCapacity::EnsureCapacity(AssemblerBuffer *buffer) {
   if (buffer->cursor() >= buffer->limit())
     buffer->ExtendCapacity();
   // In debug mode, we save the assembler buffer along with the gap
   // size before we start emitting to the buffer. This allows us to
   // check that any single generated instruction doesn't overflow the
   // limit implied by the minimum gap size.
   buffer_ = buffer;
   gap_ = ComputeGap();
   // Make sure that extending the capacity leaves a big enough gap
   // for any kind of instruction.
   assert(gap_ >= kMinimumGap);
   // Mark the buffer as having ensured the capacity.
   assert(!buffer->HasEnsuredCapacity()); // Cannot nest.
   buffer->has_ensured_capacity_ = true;
 }

 AssemblerBuffer::EnsureCapacity::~EnsureCapacity() {
   // Unmark the buffer, so we cannot emit after this.
   buffer_->has_ensured_capacity_ = false;
   // Make sure the generated instruction doesn't take up more
   // space than the minimum gap.
   intptr_t delta = gap_ - ComputeGap();
   assert(delta <= kMinimumGap);
 }
 #endif // !NDEBUG

 AssemblerBuffer::AssemblerBuffer(Assembler &assembler) : assembler_(assembler) {
   const intptr_t OneKB = 1024;
   static const intptr_t kInitialBufferCapacity = 4 * OneKB;
   contents_ = NewContents(assembler_, kInitialBufferCapacity);
   cursor_ = contents_;
   limit_ = ComputeLimit(contents_, kInitialBufferCapacity);
 #ifndef NDEBUG
   has_ensured_capacity_ = false;
 #endif // !NDEBUG

   // Verify internal state.
   assert(Capacity() == kInitialBufferCapacity);
   assert(Size() == 0);
 }

 AssemblerBuffer::~AssemblerBuffer() {}

 void AssemblerBuffer::ExtendCapacity() {
   intptr_t old_size = Size();
   intptr_t old_capacity = Capacity();
   const intptr_t OneMB = 1 << 20;
   intptr_t new_capacity = std::min(old_capacity * 2, old_capacity + OneMB);
   if (new_capacity < old_capacity) {
     llvm::report_fatal_error(
         "Unexpected overflow in AssemblerBuffer::ExtendCapacity");
   }

   // Allocate the new data area and copy contents of the old one to it.
   uintptr_t new_contents = NewContents(assembler_, new_capacity);
   memmove(reinterpret_cast<void *>(new_contents),
           reinterpret_cast<void *>(contents_), old_size);

   // Compute the relocation delta and switch to the new contents area.
   intptr_t delta = new_contents - contents_;
   contents_ = new_contents;

   // Update the cursor and recompute the limit.
   cursor_ += delta;
   limit_ = ComputeLimit(new_contents, new_capacity);

   // Verify internal state.
   assert(Capacity() == new_capacity);
   assert(Size() == old_size);
 }

 llvm::StringRef Assembler::getBufferView() const {
   return llvm::StringRef(reinterpret_cast<const char *>(buffer_.contents()),
                          buffer_.Size());
 }

 void Assembler::emitIASBytes(GlobalContext *Ctx) const {
   Ostream &Str = Ctx->getStrEmit();
   intptr_t EndPosition = buffer_.Size();
   intptr_t CurPosition = 0;
   const intptr_t FixupSize = 4;
   for (const AssemblerFixup *NextFixup : fixups()) {
     intptr_t NextFixupLoc = NextFixup->position();
     for (intptr_t i = CurPosition; i < NextFixupLoc; ++i) {
       Str << "\t.byte 0x";
       Str.write_hex(buffer_.Load<uint8_t>(i));
       Str << "\n";
     }
     Str << "\t.long ";
     NextFixup->emit(Ctx);
     if (fixupIsPCRel(NextFixup->kind()))
       Str << " - (. + " << FixupSize << ")";
     Str << "\n";
     CurPosition = NextFixupLoc + FixupSize;
     assert(CurPosition <= EndPosition);
   }
   // Handle any bytes that are not prefixed by a fixup.
   for (intptr_t i = CurPosition; i < EndPosition; ++i) {
     Str << "\t.byte 0x";
     Str.write_hex(buffer_.Load<uint8_t>(i));
     Str << "\n";
   }
 }

 } // end of namespace Ice
	//===- subzero/src/assembler.cpp - Assembler base class -------------------===//
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.
	//
	// Modified by the Subzero authors.
	//
	//===----------------------------------------------------------------------===//
	//
	// The Subzero Code Generator
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file implements the Assembler class.
	//
	//===----------------------------------------------------------------------===//

	#include "assembler.h"
	#include "IceGlobalContext.h"
	#include "IceOperand.h"

	namespace Ice {

	static uintptr_t NewContents(Assembler &assembler, intptr_t capacity) {
	uintptr_t result = assembler.AllocateBytes(capacity);
	return result;
	}

	AssemblerFixup *AssemblerBuffer::createFixup(FixupKind Kind,
	const Constant *Value) {
	AssemblerFixup *F =
	new (assembler_.Allocate<AssemblerFixup>()) AssemblerFixup();
	F->set_position(0);
	F->set_kind(Kind);
	F->set_value(Value);
	fixups_.push_back(F);
	return F;
	}

	#ifndef NDEBUG
	AssemblerBuffer::EnsureCapacity::EnsureCapacity(AssemblerBuffer *buffer) {
	if (buffer->cursor() >= buffer->limit())
	buffer->ExtendCapacity();
	// In debug mode, we save the assembler buffer along with the gap
	// size before we start emitting to the buffer. This allows us to
	// check that any single generated instruction doesn't overflow the
	// limit implied by the minimum gap size.
	buffer_ = buffer;
	gap_ = ComputeGap();
	// Make sure that extending the capacity leaves a big enough gap
	// for any kind of instruction.
	assert(gap_ >= kMinimumGap);
	// Mark the buffer as having ensured the capacity.
	assert(!buffer->HasEnsuredCapacity()); // Cannot nest.
	buffer->has_ensured_capacity_ = true;
	}

	AssemblerBuffer::EnsureCapacity::~EnsureCapacity() {
	// Unmark the buffer, so we cannot emit after this.
	buffer_->has_ensured_capacity_ = false;
	// Make sure the generated instruction doesn't take up more
	// space than the minimum gap.
	intptr_t delta = gap_ - ComputeGap();
	assert(delta <= kMinimumGap);
	}
	#endif // !NDEBUG

	AssemblerBuffer::AssemblerBuffer(Assembler &assembler) : assembler_(assembler) {
	const intptr_t OneKB = 1024;
	static const intptr_t kInitialBufferCapacity = 4 * OneKB;
	contents_ = NewContents(assembler_, kInitialBufferCapacity);
	cursor_ = contents_;
	limit_ = ComputeLimit(contents_, kInitialBufferCapacity);
	#ifndef NDEBUG
	has_ensured_capacity_ = false;
	#endif // !NDEBUG

	// Verify internal state.
	assert(Capacity() == kInitialBufferCapacity);
	assert(Size() == 0);
	}

	AssemblerBuffer::~AssemblerBuffer() {}

	void AssemblerBuffer::ExtendCapacity() {
	intptr_t old_size = Size();
	intptr_t old_capacity = Capacity();
	const intptr_t OneMB = 1 << 20;
	intptr_t new_capacity = std::min(old_capacity * 2, old_capacity + OneMB);
	if (new_capacity < old_capacity) {
	llvm::report_fatal_error(
	"Unexpected overflow in AssemblerBuffer::ExtendCapacity");
	}

	// Allocate the new data area and copy contents of the old one to it.
	uintptr_t new_contents = NewContents(assembler_, new_capacity);
	memmove(reinterpret_cast<void *>(new_contents),
	reinterpret_cast<void *>(contents_), old_size);

	// Compute the relocation delta and switch to the new contents area.
	intptr_t delta = new_contents - contents_;
	contents_ = new_contents;

	// Update the cursor and recompute the limit.
	cursor_ += delta;
	limit_ = ComputeLimit(new_contents, new_capacity);

	// Verify internal state.
	assert(Capacity() == new_capacity);
	assert(Size() == old_size);
	}

	llvm::StringRef Assembler::getBufferView() const {
	return llvm::StringRef(reinterpret_cast<const char *>(buffer_.contents()),
	buffer_.Size());
	}

	void Assembler::emitIASBytes(GlobalContext *Ctx) const {
	Ostream &Str = Ctx->getStrEmit();
	intptr_t EndPosition = buffer_.Size();
	intptr_t CurPosition = 0;
	const intptr_t FixupSize = 4;
	for (const AssemblerFixup *NextFixup : fixups()) {
	intptr_t NextFixupLoc = NextFixup->position();
	for (intptr_t i = CurPosition; i < NextFixupLoc; ++i) {
	Str << "\t.byte 0x";
	Str.write_hex(buffer_.Load<uint8_t>(i));
	Str << "\n";
	}
	Str << "\t.long ";
	NextFixup->emit(Ctx);
	if (fixupIsPCRel(NextFixup->kind()))
	Str << " - (. + " << FixupSize << ")";
	Str << "\n";
	CurPosition = NextFixupLoc + FixupSize;
	assert(CurPosition <= EndPosition);
	}
	// Handle any bytes that are not prefixed by a fixup.
	for (intptr_t i = CurPosition; i < EndPosition; ++i) {
	Str << "\t.byte 0x";
	Str.write_hex(buffer_.Load<uint8_t>(i));
	Str << "\n";
	}
	}

	} // end of namespace Ice