llvm-6502/lib/ExecutionEngine/JIT/JITMemoryManager.cpp
Torok Edwin 7d696d8040 Convert more assert(0)+abort() -> LLVM_UNREACHABLE,
and abort()/exit() -> llvm_report_error().


git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@75363 91177308-0d34-0410-b5e6-96231b3b80d8
2009-07-11 13:10:19 +00:00

580 lines
21 KiB
C++

//===-- JITMemoryManager.cpp - Memory Allocator for JIT'd code ------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file defines the DefaultJITMemoryManager class.
//
//===----------------------------------------------------------------------===//
#include "llvm/GlobalValue.h"
#include "llvm/ExecutionEngine/JITMemoryManager.h"
#include "llvm/Support/Compiler.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/System/Memory.h"
#include <map>
#include <vector>
#include <cassert>
#include <climits>
#include <cstdio>
#include <cstdlib>
#include <cstring>
using namespace llvm;
JITMemoryManager::~JITMemoryManager() {}
//===----------------------------------------------------------------------===//
// Memory Block Implementation.
//===----------------------------------------------------------------------===//
namespace {
/// MemoryRangeHeader - For a range of memory, this is the header that we put
/// on the block of memory. It is carefully crafted to be one word of memory.
/// Allocated blocks have just this header, free'd blocks have FreeRangeHeader
/// which starts with this.
struct FreeRangeHeader;
struct MemoryRangeHeader {
/// ThisAllocated - This is true if this block is currently allocated. If
/// not, this can be converted to a FreeRangeHeader.
unsigned ThisAllocated : 1;
/// PrevAllocated - Keep track of whether the block immediately before us is
/// allocated. If not, the word immediately before this header is the size
/// of the previous block.
unsigned PrevAllocated : 1;
/// BlockSize - This is the size in bytes of this memory block,
/// including this header.
uintptr_t BlockSize : (sizeof(intptr_t)*CHAR_BIT - 2);
/// getBlockAfter - Return the memory block immediately after this one.
///
MemoryRangeHeader &getBlockAfter() const {
return *(MemoryRangeHeader*)((char*)this+BlockSize);
}
/// getFreeBlockBefore - If the block before this one is free, return it,
/// otherwise return null.
FreeRangeHeader *getFreeBlockBefore() const {
if (PrevAllocated) return 0;
intptr_t PrevSize = ((intptr_t *)this)[-1];
return (FreeRangeHeader*)((char*)this-PrevSize);
}
/// FreeBlock - Turn an allocated block into a free block, adjusting
/// bits in the object headers, and adding an end of region memory block.
FreeRangeHeader *FreeBlock(FreeRangeHeader *FreeList);
/// TrimAllocationToSize - If this allocated block is significantly larger
/// than NewSize, split it into two pieces (where the former is NewSize
/// bytes, including the header), and add the new block to the free list.
FreeRangeHeader *TrimAllocationToSize(FreeRangeHeader *FreeList,
uint64_t NewSize);
};
/// FreeRangeHeader - For a memory block that isn't already allocated, this
/// keeps track of the current block and has a pointer to the next free block.
/// Free blocks are kept on a circularly linked list.
struct FreeRangeHeader : public MemoryRangeHeader {
FreeRangeHeader *Prev;
FreeRangeHeader *Next;
/// getMinBlockSize - Get the minimum size for a memory block. Blocks
/// smaller than this size cannot be created.
static unsigned getMinBlockSize() {
return sizeof(FreeRangeHeader)+sizeof(intptr_t);
}
/// SetEndOfBlockSizeMarker - The word at the end of every free block is
/// known to be the size of the free block. Set it for this block.
void SetEndOfBlockSizeMarker() {
void *EndOfBlock = (char*)this + BlockSize;
((intptr_t *)EndOfBlock)[-1] = BlockSize;
}
FreeRangeHeader *RemoveFromFreeList() {
assert(Next->Prev == this && Prev->Next == this && "Freelist broken!");
Next->Prev = Prev;
return Prev->Next = Next;
}
void AddToFreeList(FreeRangeHeader *FreeList) {
Next = FreeList;
Prev = FreeList->Prev;
Prev->Next = this;
Next->Prev = this;
}
/// GrowBlock - The block after this block just got deallocated. Merge it
/// into the current block.
void GrowBlock(uintptr_t NewSize);
/// AllocateBlock - Mark this entire block allocated, updating freelists
/// etc. This returns a pointer to the circular free-list.
FreeRangeHeader *AllocateBlock();
};
}
/// AllocateBlock - Mark this entire block allocated, updating freelists
/// etc. This returns a pointer to the circular free-list.
FreeRangeHeader *FreeRangeHeader::AllocateBlock() {
assert(!ThisAllocated && !getBlockAfter().PrevAllocated &&
"Cannot allocate an allocated block!");
// Mark this block allocated.
ThisAllocated = 1;
getBlockAfter().PrevAllocated = 1;
// Remove it from the free list.
return RemoveFromFreeList();
}
/// FreeBlock - Turn an allocated block into a free block, adjusting
/// bits in the object headers, and adding an end of region memory block.
/// If possible, coalesce this block with neighboring blocks. Return the
/// FreeRangeHeader to allocate from.
FreeRangeHeader *MemoryRangeHeader::FreeBlock(FreeRangeHeader *FreeList) {
MemoryRangeHeader *FollowingBlock = &getBlockAfter();
assert(ThisAllocated && "This block is already allocated!");
assert(FollowingBlock->PrevAllocated && "Flags out of sync!");
FreeRangeHeader *FreeListToReturn = FreeList;
// If the block after this one is free, merge it into this block.
if (!FollowingBlock->ThisAllocated) {
FreeRangeHeader &FollowingFreeBlock = *(FreeRangeHeader *)FollowingBlock;
// "FreeList" always needs to be a valid free block. If we're about to
// coalesce with it, update our notion of what the free list is.
if (&FollowingFreeBlock == FreeList) {
FreeList = FollowingFreeBlock.Next;
FreeListToReturn = 0;
assert(&FollowingFreeBlock != FreeList && "No tombstone block?");
}
FollowingFreeBlock.RemoveFromFreeList();
// Include the following block into this one.
BlockSize += FollowingFreeBlock.BlockSize;
FollowingBlock = &FollowingFreeBlock.getBlockAfter();
// Tell the block after the block we are coalescing that this block is
// allocated.
FollowingBlock->PrevAllocated = 1;
}
assert(FollowingBlock->ThisAllocated && "Missed coalescing?");
if (FreeRangeHeader *PrevFreeBlock = getFreeBlockBefore()) {
PrevFreeBlock->GrowBlock(PrevFreeBlock->BlockSize + BlockSize);
return FreeListToReturn ? FreeListToReturn : PrevFreeBlock;
}
// Otherwise, mark this block free.
FreeRangeHeader &FreeBlock = *(FreeRangeHeader*)this;
FollowingBlock->PrevAllocated = 0;
FreeBlock.ThisAllocated = 0;
// Link this into the linked list of free blocks.
FreeBlock.AddToFreeList(FreeList);
// Add a marker at the end of the block, indicating the size of this free
// block.
FreeBlock.SetEndOfBlockSizeMarker();
return FreeListToReturn ? FreeListToReturn : &FreeBlock;
}
/// GrowBlock - The block after this block just got deallocated. Merge it
/// into the current block.
void FreeRangeHeader::GrowBlock(uintptr_t NewSize) {
assert(NewSize > BlockSize && "Not growing block?");
BlockSize = NewSize;
SetEndOfBlockSizeMarker();
getBlockAfter().PrevAllocated = 0;
}
/// TrimAllocationToSize - If this allocated block is significantly larger
/// than NewSize, split it into two pieces (where the former is NewSize
/// bytes, including the header), and add the new block to the free list.
FreeRangeHeader *MemoryRangeHeader::
TrimAllocationToSize(FreeRangeHeader *FreeList, uint64_t NewSize) {
assert(ThisAllocated && getBlockAfter().PrevAllocated &&
"Cannot deallocate part of an allocated block!");
// Don't allow blocks to be trimmed below minimum required size
NewSize = std::max<uint64_t>(FreeRangeHeader::getMinBlockSize(), NewSize);
// Round up size for alignment of header.
unsigned HeaderAlign = __alignof(FreeRangeHeader);
NewSize = (NewSize+ (HeaderAlign-1)) & ~(HeaderAlign-1);
// Size is now the size of the block we will remove from the start of the
// current block.
assert(NewSize <= BlockSize &&
"Allocating more space from this block than exists!");
// If splitting this block will cause the remainder to be too small, do not
// split the block.
if (BlockSize <= NewSize+FreeRangeHeader::getMinBlockSize())
return FreeList;
// Otherwise, we splice the required number of bytes out of this block, form
// a new block immediately after it, then mark this block allocated.
MemoryRangeHeader &FormerNextBlock = getBlockAfter();
// Change the size of this block.
BlockSize = NewSize;
// Get the new block we just sliced out and turn it into a free block.
FreeRangeHeader &NewNextBlock = (FreeRangeHeader &)getBlockAfter();
NewNextBlock.BlockSize = (char*)&FormerNextBlock - (char*)&NewNextBlock;
NewNextBlock.ThisAllocated = 0;
NewNextBlock.PrevAllocated = 1;
NewNextBlock.SetEndOfBlockSizeMarker();
FormerNextBlock.PrevAllocated = 0;
NewNextBlock.AddToFreeList(FreeList);
return &NewNextBlock;
}
//===----------------------------------------------------------------------===//
// Memory Block Implementation.
//===----------------------------------------------------------------------===//
namespace {
/// DefaultJITMemoryManager - Manage memory for the JIT code generation.
/// This splits a large block of MAP_NORESERVE'd memory into two
/// sections, one for function stubs, one for the functions themselves. We
/// have to do this because we may need to emit a function stub while in the
/// middle of emitting a function, and we don't know how large the function we
/// are emitting is.
class VISIBILITY_HIDDEN DefaultJITMemoryManager : public JITMemoryManager {
bool PoisonMemory; // Whether to poison freed memory.
std::vector<sys::MemoryBlock> Blocks; // Memory blocks allocated by the JIT
FreeRangeHeader *FreeMemoryList; // Circular list of free blocks.
// When emitting code into a memory block, this is the block.
MemoryRangeHeader *CurBlock;
uint8_t *CurStubPtr, *StubBase;
uint8_t *CurGlobalPtr, *GlobalEnd;
uint8_t *GOTBase; // Target Specific reserved memory
void *DlsymTable; // Stub external symbol information
// Centralize memory block allocation.
sys::MemoryBlock getNewMemoryBlock(unsigned size);
std::map<const Function*, MemoryRangeHeader*> FunctionBlocks;
std::map<const Function*, MemoryRangeHeader*> TableBlocks;
public:
DefaultJITMemoryManager();
~DefaultJITMemoryManager();
void AllocateGOT();
void SetDlsymTable(void *);
uint8_t *allocateStub(const GlobalValue* F, unsigned StubSize,
unsigned Alignment);
/// startFunctionBody - When a function starts, allocate a block of free
/// executable memory, returning a pointer to it and its actual size.
uint8_t *startFunctionBody(const Function *F, uintptr_t &ActualSize) {
FreeRangeHeader* candidateBlock = FreeMemoryList;
FreeRangeHeader* head = FreeMemoryList;
FreeRangeHeader* iter = head->Next;
uintptr_t largest = candidateBlock->BlockSize;
// Search for the largest free block
while (iter != head) {
if (iter->BlockSize > largest) {
largest = iter->BlockSize;
candidateBlock = iter;
}
iter = iter->Next;
}
// Select this candidate block for allocation
CurBlock = candidateBlock;
// Allocate the entire memory block.
FreeMemoryList = candidateBlock->AllocateBlock();
ActualSize = CurBlock->BlockSize-sizeof(MemoryRangeHeader);
return (uint8_t *)(CurBlock+1);
}
/// endFunctionBody - The function F is now allocated, and takes the memory
/// in the range [FunctionStart,FunctionEnd).
void endFunctionBody(const Function *F, uint8_t *FunctionStart,
uint8_t *FunctionEnd) {
assert(FunctionEnd > FunctionStart);
assert(FunctionStart == (uint8_t *)(CurBlock+1) &&
"Mismatched function start/end!");
uintptr_t BlockSize = FunctionEnd - (uint8_t *)CurBlock;
FunctionBlocks[F] = CurBlock;
// Release the memory at the end of this block that isn't needed.
FreeMemoryList =CurBlock->TrimAllocationToSize(FreeMemoryList, BlockSize);
}
/// allocateSpace - Allocate a memory block of the given size.
uint8_t *allocateSpace(intptr_t Size, unsigned Alignment) {
CurBlock = FreeMemoryList;
FreeMemoryList = FreeMemoryList->AllocateBlock();
uint8_t *result = (uint8_t *)(CurBlock + 1);
if (Alignment == 0) Alignment = 1;
result = (uint8_t*)(((intptr_t)result+Alignment-1) &
~(intptr_t)(Alignment-1));
uintptr_t BlockSize = result + Size - (uint8_t *)CurBlock;
FreeMemoryList =CurBlock->TrimAllocationToSize(FreeMemoryList, BlockSize);
return result;
}
/// allocateGlobal - Allocate memory for a global. Unlike allocateSpace,
/// this method does not touch the current block and can be called at any
/// time.
uint8_t *allocateGlobal(uintptr_t Size, unsigned Alignment) {
uint8_t *Result = CurGlobalPtr;
// Align the pointer.
if (Alignment == 0) Alignment = 1;
Result = (uint8_t*)(((uintptr_t)Result + Alignment-1) &
~(uintptr_t)(Alignment-1));
// Move the current global pointer forward.
CurGlobalPtr += Result - CurGlobalPtr + Size;
// Check for overflow.
if (CurGlobalPtr > GlobalEnd) {
// FIXME: Allocate more memory.
llvm_report_error("JIT ran out of memory for globals!");
}
return Result;
}
/// startExceptionTable - Use startFunctionBody to allocate memory for the
/// function's exception table.
uint8_t* startExceptionTable(const Function* F, uintptr_t &ActualSize) {
return startFunctionBody(F, ActualSize);
}
/// endExceptionTable - The exception table of F is now allocated,
/// and takes the memory in the range [TableStart,TableEnd).
void endExceptionTable(const Function *F, uint8_t *TableStart,
uint8_t *TableEnd, uint8_t* FrameRegister) {
assert(TableEnd > TableStart);
assert(TableStart == (uint8_t *)(CurBlock+1) &&
"Mismatched table start/end!");
uintptr_t BlockSize = TableEnd - (uint8_t *)CurBlock;
TableBlocks[F] = CurBlock;
// Release the memory at the end of this block that isn't needed.
FreeMemoryList =CurBlock->TrimAllocationToSize(FreeMemoryList, BlockSize);
}
uint8_t *getGOTBase() const {
return GOTBase;
}
void *getDlsymTable() const {
return DlsymTable;
}
/// deallocateMemForFunction - Deallocate all memory for the specified
/// function body.
void deallocateMemForFunction(const Function *F) {
std::map<const Function*, MemoryRangeHeader*>::iterator
I = FunctionBlocks.find(F);
if (I == FunctionBlocks.end()) return;
// Find the block that is allocated for this function.
MemoryRangeHeader *MemRange = I->second;
assert(MemRange->ThisAllocated && "Block isn't allocated!");
// Fill the buffer with garbage!
if (PoisonMemory) {
memset(MemRange+1, 0xCD, MemRange->BlockSize-sizeof(*MemRange));
}
// Free the memory.
FreeMemoryList = MemRange->FreeBlock(FreeMemoryList);
// Finally, remove this entry from FunctionBlocks.
FunctionBlocks.erase(I);
I = TableBlocks.find(F);
if (I == TableBlocks.end()) return;
// Find the block that is allocated for this function.
MemRange = I->second;
assert(MemRange->ThisAllocated && "Block isn't allocated!");
// Fill the buffer with garbage!
if (PoisonMemory) {
memset(MemRange+1, 0xCD, MemRange->BlockSize-sizeof(*MemRange));
}
// Free the memory.
FreeMemoryList = MemRange->FreeBlock(FreeMemoryList);
// Finally, remove this entry from TableBlocks.
TableBlocks.erase(I);
}
/// setMemoryWritable - When code generation is in progress,
/// the code pages may need permissions changed.
void setMemoryWritable(void)
{
for (unsigned i = 0, e = Blocks.size(); i != e; ++i)
sys::Memory::setWritable(Blocks[i]);
}
/// setMemoryExecutable - When code generation is done and we're ready to
/// start execution, the code pages may need permissions changed.
void setMemoryExecutable(void)
{
for (unsigned i = 0, e = Blocks.size(); i != e; ++i)
sys::Memory::setExecutable(Blocks[i]);
}
/// setPoisonMemory - Controls whether we write garbage over freed memory.
///
void setPoisonMemory(bool poison) {
PoisonMemory = poison;
}
};
}
DefaultJITMemoryManager::DefaultJITMemoryManager() {
#ifdef NDEBUG
PoisonMemory = true;
#else
PoisonMemory = false;
#endif
// Allocate a 16M block of memory for functions.
#if defined(__APPLE__) && defined(__arm__)
sys::MemoryBlock MemBlock = getNewMemoryBlock(4 << 20);
#else
sys::MemoryBlock MemBlock = getNewMemoryBlock(16 << 20);
#endif
uint8_t *MemBase = static_cast<uint8_t*>(MemBlock.base());
// Allocate stubs backwards to the base, globals forward from the stubs, and
// functions forward after globals.
StubBase = MemBase;
CurStubPtr = MemBase + 512*1024; // Use 512k for stubs, working backwards.
CurGlobalPtr = CurStubPtr; // Use 2M for globals, working forwards.
GlobalEnd = CurGlobalPtr + 2*1024*1024;
// We set up the memory chunk with 4 mem regions, like this:
// [ START
// [ Free #0 ] -> Large space to allocate functions from.
// [ Allocated #1 ] -> Tiny space to separate regions.
// [ Free #2 ] -> Tiny space so there is always at least 1 free block.
// [ Allocated #3 ] -> Tiny space to prevent looking past end of block.
// END ]
//
// The last three blocks are never deallocated or touched.
// Add MemoryRangeHeader to the end of the memory region, indicating that
// the space after the block of memory is allocated. This is block #3.
MemoryRangeHeader *Mem3 = (MemoryRangeHeader*)(MemBase+MemBlock.size())-1;
Mem3->ThisAllocated = 1;
Mem3->PrevAllocated = 0;
Mem3->BlockSize = 0;
/// Add a tiny free region so that the free list always has one entry.
FreeRangeHeader *Mem2 =
(FreeRangeHeader *)(((char*)Mem3)-FreeRangeHeader::getMinBlockSize());
Mem2->ThisAllocated = 0;
Mem2->PrevAllocated = 1;
Mem2->BlockSize = FreeRangeHeader::getMinBlockSize();
Mem2->SetEndOfBlockSizeMarker();
Mem2->Prev = Mem2; // Mem2 *is* the free list for now.
Mem2->Next = Mem2;
/// Add a tiny allocated region so that Mem2 is never coalesced away.
MemoryRangeHeader *Mem1 = (MemoryRangeHeader*)Mem2-1;
Mem1->ThisAllocated = 1;
Mem1->PrevAllocated = 0;
Mem1->BlockSize = (char*)Mem2 - (char*)Mem1;
// Add a FreeRangeHeader to the start of the function body region, indicating
// that the space is free. Mark the previous block allocated so we never look
// at it.
FreeRangeHeader *Mem0 = (FreeRangeHeader*)GlobalEnd;
Mem0->ThisAllocated = 0;
Mem0->PrevAllocated = 1;
Mem0->BlockSize = (char*)Mem1-(char*)Mem0;
Mem0->SetEndOfBlockSizeMarker();
Mem0->AddToFreeList(Mem2);
// Start out with the freelist pointing to Mem0.
FreeMemoryList = Mem0;
GOTBase = NULL;
DlsymTable = NULL;
}
void DefaultJITMemoryManager::AllocateGOT() {
assert(GOTBase == 0 && "Cannot allocate the got multiple times");
GOTBase = new uint8_t[sizeof(void*) * 8192];
HasGOT = true;
}
void DefaultJITMemoryManager::SetDlsymTable(void *ptr) {
DlsymTable = ptr;
}
DefaultJITMemoryManager::~DefaultJITMemoryManager() {
for (unsigned i = 0, e = Blocks.size(); i != e; ++i)
sys::Memory::ReleaseRWX(Blocks[i]);
delete[] GOTBase;
Blocks.clear();
}
uint8_t *DefaultJITMemoryManager::allocateStub(const GlobalValue* F,
unsigned StubSize,
unsigned Alignment) {
CurStubPtr -= StubSize;
CurStubPtr = (uint8_t*)(((intptr_t)CurStubPtr) &
~(intptr_t)(Alignment-1));
if (CurStubPtr < StubBase) {
// FIXME: allocate a new block
llvm_report_error("JIT ran out of memory for function stubs!");
}
return CurStubPtr;
}
sys::MemoryBlock DefaultJITMemoryManager::getNewMemoryBlock(unsigned size) {
// Allocate a new block close to the last one.
const sys::MemoryBlock *BOld = Blocks.empty() ? 0 : &Blocks.back();
std::string ErrMsg;
sys::MemoryBlock B = sys::Memory::AllocateRWX(size, BOld, &ErrMsg);
if (B.base() == 0) {
llvm_report_error("Allocation failed when allocating new memory in the"
" JIT\n" + ErrMsg);
}
Blocks.push_back(B);
return B;
}
JITMemoryManager *JITMemoryManager::CreateDefaultMemManager() {
return new DefaultJITMemoryManager();
}