llvm-project/llvm/lib/Target/ARM/ARMJITInfo.cpp

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//===-- ARMJITInfo.cpp - Implement the JIT interfaces for the ARM target --===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements the JIT interfaces for the ARM target.
//
//===----------------------------------------------------------------------===//
#define DEBUG_TYPE "jit"
#include "ARMJITInfo.h"
#include "ARMConstantPoolValue.h"
#include "ARMRelocations.h"
#include "ARMSubtarget.h"
#include "llvm/Function.h"
#include "llvm/CodeGen/MachineCodeEmitter.h"
#include "llvm/Config/alloca.h"
#include "llvm/Support/Streams.h"
#include "llvm/System/Memory.h"
#include <cstdlib>
using namespace llvm;
void ARMJITInfo::replaceMachineCodeForFunction(void *Old, void *New) {
abort();
}
/// JITCompilerFunction - This contains the address of the JIT function used to
/// compile a function lazily.
static TargetJITInfo::JITCompilerFn JITCompilerFunction;
// Get the ASMPREFIX for the current host. This is often '_'.
#ifndef __USER_LABEL_PREFIX__
#define __USER_LABEL_PREFIX__
#endif
#define GETASMPREFIX2(X) #X
#define GETASMPREFIX(X) GETASMPREFIX2(X)
#define ASMPREFIX GETASMPREFIX(__USER_LABEL_PREFIX__)
// CompilationCallback stub - We can't use a C function with inline assembly in
// it, because we the prolog/epilog inserted by GCC won't work for us (we need
// to preserve more context and manipulate the stack directly). Instead,
// write our own wrapper, which does things our way, so we have complete
// control over register saving and restoring.
extern "C" {
#if defined(__arm__)
void ARMCompilationCallback(void);
asm(
".text\n"
".align 2\n"
".globl " ASMPREFIX "ARMCompilationCallback\n"
ASMPREFIX "ARMCompilationCallback:\n"
// Save caller saved registers since they may contain stuff
// for the real target function right now. We have to act as if this
// whole compilation callback doesn't exist as far as the caller is
// concerned, so we can't just preserve the callee saved regs.
"stmdb sp!, {r0, r1, r2, r3, lr}\n"
// The LR contains the address of the stub function on entry.
// pass it as the argument to the C part of the callback
"mov r0, lr\n"
"sub sp, sp, #4\n"
// Call the C portion of the callback
"bl " ASMPREFIX "ARMCompilationCallbackC\n"
"add sp, sp, #4\n"
// Restoring the LR to the return address of the function that invoked
// the stub and de-allocating the stack space for it requires us to
// swap the two saved LR values on the stack, as they're backwards
// for what we need since the pop instruction has a pre-determined
// order for the registers.
// +--------+
// 0 | LR | Original return address
// +--------+
// 1 | LR | Stub address (start of stub)
// 2-5 | R3..R0 | Saved registers (we need to preserve all regs)
// +--------+
//
// We need to exchange the values in slots 0 and 1 so we can
// return to the address in slot 1 with the address in slot 0
// restored to the LR.
"ldr r0, [sp,#20]\n"
"ldr r1, [sp,#16]\n"
"str r1, [sp,#20]\n"
"str r0, [sp,#16]\n"
// Return to the (newly modified) stub to invoke the real function.
// The above twiddling of the saved return addresses allows us to
// deallocate everything, including the LR the stub saved, all in one
// pop instruction.
"ldmia sp!, {r0, r1, r2, r3, lr, pc}\n"
);
#else // Not an ARM host
void ARMCompilationCallback() {
assert(0 && "Cannot call ARMCompilationCallback() on a non-ARM arch!\n");
abort();
}
#endif
}
/// ARMCompilationCallbackC - This is the target-specific function invoked
/// by the function stub when we did not know the real target of a call.
/// This function must locate the start of the stub or call site and pass
/// it into the JIT compiler function.
extern "C" void ARMCompilationCallbackC(intptr_t StubAddr) {
// Get the address of the compiled code for this function.
intptr_t NewVal = (intptr_t)JITCompilerFunction((void*)StubAddr);
// Rewrite the call target... so that we don't end up here every time we
// execute the call. We're replacing the first two instructions of the
// stub with:
// ldr pc, [pc,#-4]
// <addr>
if (!sys::Memory::setRangeWritable((void*)StubAddr, 8)) {
cerr << "ERROR: Unable to mark stub writable\n";
abort();
}
*(intptr_t *)StubAddr = 0xe51ff004; // ldr pc, [pc, #-4]
*(intptr_t *)(StubAddr+4) = NewVal;
if (!sys::Memory::setRangeExecutable((void*)StubAddr, 8)) {
cerr << "ERROR: Unable to mark stub executable\n";
abort();
}
}
TargetJITInfo::LazyResolverFn
ARMJITInfo::getLazyResolverFunction(JITCompilerFn F) {
JITCompilerFunction = F;
return ARMCompilationCallback;
}
void *ARMJITInfo::emitGlobalValueNonLazyPtr(const GlobalValue *GV, void *Ptr,
MachineCodeEmitter &MCE) {
MCE.startGVStub(GV, 4, 4);
MCE.emitWordLE((intptr_t)Ptr);
return MCE.finishGVStub(GV);
}
void *ARMJITInfo::emitFunctionStub(const Function* F, void *Fn,
MachineCodeEmitter &MCE) {
// If this is just a call to an external function, emit a branch instead of a
// call. The code is the same except for one bit of the last instruction.
if (Fn != (void*)(intptr_t)ARMCompilationCallback) {
// Branch to the corresponding function addr.
// The stub is 8-byte size and 4-aligned.
MCE.startGVStub(F, 8, 4);
intptr_t Addr = (intptr_t)MCE.getCurrentPCValue();
MCE.emitWordLE(0xe51ff004); // ldr pc, [pc, #-4]
MCE.emitWordLE((intptr_t)Fn); // addr of function
sys::Memory::InvalidateInstructionCache((void*)Addr, 8);
} else {
// The compilation callback will overwrite the first two words of this
// stub with indirect branch instructions targeting the compiled code.
// This stub sets the return address to restart the stub, so that
// the new branch will be invoked when we come back.
//
// Branch and link to the compilation callback.
// The stub is 16-byte size and 4-byte aligned.
MCE.startGVStub(F, 16, 4);
intptr_t Addr = (intptr_t)MCE.getCurrentPCValue();
// Save LR so the callback can determine which stub called it.
// The compilation callback is responsible for popping this prior
// to returning.
MCE.emitWordLE(0xe92d4000); // push {lr}
// Set the return address to go back to the start of this stub.
MCE.emitWordLE(0xe24fe00c); // sub lr, pc, #12
// Invoke the compilation callback.
MCE.emitWordLE(0xe51ff004); // ldr pc, [pc, #-4]
// The address of the compilation callback.
MCE.emitWordLE((intptr_t)ARMCompilationCallback);
sys::Memory::InvalidateInstructionCache((void*)Addr, 16);
}
return MCE.finishGVStub(F);
}
intptr_t ARMJITInfo::resolveRelocDestAddr(MachineRelocation *MR) const {
ARM::RelocationType RT = (ARM::RelocationType)MR->getRelocationType();
if (RT == ARM::reloc_arm_pic_jt)
// Destination address - jump table base.
return (intptr_t)(MR->getResultPointer()) - MR->getConstantVal();
else if (RT == ARM::reloc_arm_jt_base)
// Jump table base address.
return getJumpTableBaseAddr(MR->getJumpTableIndex());
else if (RT == ARM::reloc_arm_cp_entry)
// Constant pool entry address.
return getConstantPoolEntryAddr(MR->getConstantPoolIndex());
else if (RT == ARM::reloc_arm_machine_cp_entry) {
2008-11-08 06:57:53 +08:00
ARMConstantPoolValue *ACPV = (ARMConstantPoolValue*)MR->getConstantVal();
assert((!ACPV->hasModifier() && !ACPV->mustAddCurrentAddress()) &&
"Can't handle this machine constant pool entry yet!");
intptr_t Addr = (intptr_t)(MR->getResultPointer());
Addr -= getPCLabelAddr(ACPV->getLabelId()) + ACPV->getPCAdjustment();
return Addr;
}
return (intptr_t)(MR->getResultPointer());
}
/// relocate - Before the JIT can run a block of code that has been emitted,
/// it must rewrite the code to contain the actual addresses of any
/// referenced global symbols.
void ARMJITInfo::relocate(void *Function, MachineRelocation *MR,
unsigned NumRelocs, unsigned char* GOTBase) {
for (unsigned i = 0; i != NumRelocs; ++i, ++MR) {
void *RelocPos = (char*)Function + MR->getMachineCodeOffset();
intptr_t ResultPtr = resolveRelocDestAddr(MR);
switch ((ARM::RelocationType)MR->getRelocationType()) {
case ARM::reloc_arm_cp_entry:
case ARM::reloc_arm_relative: {
// It is necessary to calculate the correct PC relative value. We
// subtract the base addr from the target addr to form a byte offset.
ResultPtr = ResultPtr-(intptr_t)RelocPos-8;
// If the result is positive, set bit U(23) to 1.
if (ResultPtr >= 0)
*((unsigned*)RelocPos) |= 1 << 23;
else {
// Otherwise, obtain the absolute value and set
// bit U(23) to 0.
ResultPtr *= -1;
*((unsigned*)RelocPos) &= 0xFF7FFFFF;
}
// Set the immed value calculated.
*((unsigned*)RelocPos) |= (unsigned)ResultPtr;
// Set register Rn to PC.
*((unsigned*)RelocPos) |= 0xF << 16;
break;
}
case ARM::reloc_arm_pic_jt:
case ARM::reloc_arm_machine_cp_entry:
case ARM::reloc_arm_absolute: {
// These addresses have already been resolved.
*((unsigned*)RelocPos) |= (unsigned)ResultPtr;
break;
}
case ARM::reloc_arm_branch: {
// It is necessary to calculate the correct value of signed_immed_24
// field. We subtract the base addr from the target addr to form a
// byte offset, which must be inside the range -33554432 and +33554428.
// Then, we set the signed_immed_24 field of the instruction to bits
// [25:2] of the byte offset. More details ARM-ARM p. A4-11.
ResultPtr = ResultPtr - (intptr_t)RelocPos - 8;
ResultPtr = (ResultPtr & 0x03FFFFFC) >> 2;
assert(ResultPtr >= -33554432 && ResultPtr <= 33554428);
*((unsigned*)RelocPos) |= ResultPtr;
break;
}
case ARM::reloc_arm_jt_base: {
// JT base - (instruction addr + 8)
ResultPtr = ResultPtr - (intptr_t)RelocPos - 8;
*((unsigned*)RelocPos) |= ResultPtr;
break;
}
}
}
}