llvm-for-llvmta/lib/ExecutionEngine/Orc/OrcABISupport.cpp

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2022-04-25 10:02:23 +02:00
//===------------- OrcABISupport.cpp - ABI specific support code ----------===//
//
// 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
//
//===----------------------------------------------------------------------===//
#include "llvm/ExecutionEngine/Orc/OrcABISupport.h"
#include "llvm/Support/FormatVariadic.h"
#include "llvm/Support/Process.h"
#include "llvm/Support/raw_ostream.h"
#define DEBUG_TYPE "orc"
using namespace llvm;
template <typename ORCABI>
bool stubAndPointerRangesOk(JITTargetAddress StubBlockAddr,
JITTargetAddress PointerBlockAddr,
unsigned NumStubs) {
constexpr unsigned MaxDisp = ORCABI::StubToPointerMaxDisplacement;
JITTargetAddress FirstStub = StubBlockAddr;
JITTargetAddress LastStub = FirstStub + ((NumStubs - 1) * ORCABI::StubSize);
JITTargetAddress FirstPointer = PointerBlockAddr;
JITTargetAddress LastPointer =
FirstPointer + ((NumStubs - 1) * ORCABI::StubSize);
if (FirstStub < FirstPointer) {
if (LastStub >= FirstPointer)
return false; // Ranges overlap.
return (FirstPointer - FirstStub <= MaxDisp) &&
(LastPointer - LastStub <= MaxDisp); // out-of-range.
}
if (LastPointer >= FirstStub)
return false; // Ranges overlap.
return (FirstStub - FirstPointer <= MaxDisp) &&
(LastStub - LastPointer <= MaxDisp);
}
namespace llvm {
namespace orc {
void OrcAArch64::writeResolverCode(char *ResolverWorkingMem,
JITTargetAddress ResolverTargetAddress,
JITTargetAddress ReentryFnAddr,
JITTargetAddress ReentryCtxAddr) {
const uint32_t ResolverCode[] = {
// resolver_entry:
0xa9bf47fd, // 0x000: stp x29, x17, [sp, #-16]!
0x910003fd, // 0x004: mov x29, sp
0xa9bf73fb, // 0x008: stp x27, x28, [sp, #-16]!
0xa9bf6bf9, // 0x00c: stp x25, x26, [sp, #-16]!
0xa9bf63f7, // 0x010: stp x23, x24, [sp, #-16]!
0xa9bf5bf5, // 0x014: stp x21, x22, [sp, #-16]!
0xa9bf53f3, // 0x018: stp x19, x20, [sp, #-16]!
0xa9bf3fee, // 0x01c: stp x14, x15, [sp, #-16]!
0xa9bf37ec, // 0x020: stp x12, x13, [sp, #-16]!
0xa9bf2fea, // 0x024: stp x10, x11, [sp, #-16]!
0xa9bf27e8, // 0x028: stp x8, x9, [sp, #-16]!
0xa9bf1fe6, // 0x02c: stp x6, x7, [sp, #-16]!
0xa9bf17e4, // 0x030: stp x4, x5, [sp, #-16]!
0xa9bf0fe2, // 0x034: stp x2, x3, [sp, #-16]!
0xa9bf07e0, // 0x038: stp x0, x1, [sp, #-16]!
0xadbf7ffe, // 0x03c: stp q30, q31, [sp, #-32]!
0xadbf77fc, // 0x040: stp q28, q29, [sp, #-32]!
0xadbf6ffa, // 0x044: stp q26, q27, [sp, #-32]!
0xadbf67f8, // 0x048: stp q24, q25, [sp, #-32]!
0xadbf5ff6, // 0x04c: stp q22, q23, [sp, #-32]!
0xadbf57f4, // 0x050: stp q20, q21, [sp, #-32]!
0xadbf4ff2, // 0x054: stp q18, q19, [sp, #-32]!
0xadbf47f0, // 0x058: stp q16, q17, [sp, #-32]!
0xadbf3fee, // 0x05c: stp q14, q15, [sp, #-32]!
0xadbf37ec, // 0x060: stp q12, q13, [sp, #-32]!
0xadbf2fea, // 0x064: stp q10, q11, [sp, #-32]!
0xadbf27e8, // 0x068: stp q8, q9, [sp, #-32]!
0xadbf1fe6, // 0x06c: stp q6, q7, [sp, #-32]!
0xadbf17e4, // 0x070: stp q4, q5, [sp, #-32]!
0xadbf0fe2, // 0x074: stp q2, q3, [sp, #-32]!
0xadbf07e0, // 0x078: stp q0, q1, [sp, #-32]!
0x580004e0, // 0x07c: ldr x0, Lreentry_ctx_ptr
0xaa1e03e1, // 0x080: mov x1, x30
0xd1003021, // 0x084: sub x1, x1, #12
0x58000442, // 0x088: ldr x2, Lreentry_fn_ptr
0xd63f0040, // 0x08c: blr x2
0xaa0003f1, // 0x090: mov x17, x0
0xacc107e0, // 0x094: ldp q0, q1, [sp], #32
0xacc10fe2, // 0x098: ldp q2, q3, [sp], #32
0xacc117e4, // 0x09c: ldp q4, q5, [sp], #32
0xacc11fe6, // 0x0a0: ldp q6, q7, [sp], #32
0xacc127e8, // 0x0a4: ldp q8, q9, [sp], #32
0xacc12fea, // 0x0a8: ldp q10, q11, [sp], #32
0xacc137ec, // 0x0ac: ldp q12, q13, [sp], #32
0xacc13fee, // 0x0b0: ldp q14, q15, [sp], #32
0xacc147f0, // 0x0b4: ldp q16, q17, [sp], #32
0xacc14ff2, // 0x0b8: ldp q18, q19, [sp], #32
0xacc157f4, // 0x0bc: ldp q20, q21, [sp], #32
0xacc15ff6, // 0x0c0: ldp q22, q23, [sp], #32
0xacc167f8, // 0x0c4: ldp q24, q25, [sp], #32
0xacc16ffa, // 0x0c8: ldp q26, q27, [sp], #32
0xacc177fc, // 0x0cc: ldp q28, q29, [sp], #32
0xacc17ffe, // 0x0d0: ldp q30, q31, [sp], #32
0xa8c107e0, // 0x0d4: ldp x0, x1, [sp], #16
0xa8c10fe2, // 0x0d8: ldp x2, x3, [sp], #16
0xa8c117e4, // 0x0dc: ldp x4, x5, [sp], #16
0xa8c11fe6, // 0x0e0: ldp x6, x7, [sp], #16
0xa8c127e8, // 0x0e4: ldp x8, x9, [sp], #16
0xa8c12fea, // 0x0e8: ldp x10, x11, [sp], #16
0xa8c137ec, // 0x0ec: ldp x12, x13, [sp], #16
0xa8c13fee, // 0x0f0: ldp x14, x15, [sp], #16
0xa8c153f3, // 0x0f4: ldp x19, x20, [sp], #16
0xa8c15bf5, // 0x0f8: ldp x21, x22, [sp], #16
0xa8c163f7, // 0x0fc: ldp x23, x24, [sp], #16
0xa8c16bf9, // 0x100: ldp x25, x26, [sp], #16
0xa8c173fb, // 0x104: ldp x27, x28, [sp], #16
0xa8c17bfd, // 0x108: ldp x29, x30, [sp], #16
0xd65f0220, // 0x10c: ret x17
0x01234567, // 0x110: Lreentry_fn_ptr:
0xdeadbeef, // 0x114: .quad 0
0x98765432, // 0x118: Lreentry_ctx_ptr:
0xcafef00d // 0x11c: .quad 0
};
const unsigned ReentryFnAddrOffset = 0x110;
const unsigned ReentryCtxAddrOffset = 0x118;
memcpy(ResolverWorkingMem, ResolverCode, sizeof(ResolverCode));
memcpy(ResolverWorkingMem + ReentryFnAddrOffset, &ReentryFnAddr,
sizeof(uint64_t));
memcpy(ResolverWorkingMem + ReentryCtxAddrOffset, &ReentryCtxAddr,
sizeof(uint64_t));
}
void OrcAArch64::writeTrampolines(char *TrampolineBlockWorkingMem,
JITTargetAddress TrampolineBlockTargetAddress,
JITTargetAddress ResolverAddr,
unsigned NumTrampolines) {
unsigned OffsetToPtr = alignTo(NumTrampolines * TrampolineSize, 8);
memcpy(TrampolineBlockWorkingMem + OffsetToPtr, &ResolverAddr,
sizeof(uint64_t));
// OffsetToPtr is actually the offset from the PC for the 2nd instruction, so
// subtract 32-bits.
OffsetToPtr -= 4;
uint32_t *Trampolines =
reinterpret_cast<uint32_t *>(TrampolineBlockWorkingMem);
for (unsigned I = 0; I < NumTrampolines; ++I, OffsetToPtr -= TrampolineSize) {
Trampolines[3 * I + 0] = 0xaa1e03f1; // mov x17, x30
Trampolines[3 * I + 1] = 0x58000010 | (OffsetToPtr << 3); // adr x16, Lptr
Trampolines[3 * I + 2] = 0xd63f0200; // blr x16
}
}
void OrcAArch64::writeIndirectStubsBlock(
char *StubsBlockWorkingMem, JITTargetAddress StubsBlockTargetAddress,
JITTargetAddress PointersBlockTargetAddress, unsigned NumStubs) {
// Stub format is:
//
// .section __orc_stubs
// stub1:
// ldr x0, ptr1 ; PC-rel load of ptr1
// br x0 ; Jump to resolver
// stub2:
// ldr x0, ptr2 ; PC-rel load of ptr2
// br x0 ; Jump to resolver
//
// ...
//
// .section __orc_ptrs
// ptr1:
// .quad 0x0
// ptr2:
// .quad 0x0
//
// ...
static_assert(StubSize == PointerSize,
"Pointer and stub size must match for algorithm below");
assert(stubAndPointerRangesOk<OrcAArch64>(
StubsBlockTargetAddress, PointersBlockTargetAddress, NumStubs) &&
"PointersBlock is out of range");
uint64_t PtrDisplacement =
PointersBlockTargetAddress - StubsBlockTargetAddress;
uint64_t *Stub = reinterpret_cast<uint64_t *>(StubsBlockWorkingMem);
uint64_t PtrOffsetField = PtrDisplacement << 3;
for (unsigned I = 0; I < NumStubs; ++I)
Stub[I] = 0xd61f020058000010 | PtrOffsetField;
}
void OrcX86_64_Base::writeTrampolines(
char *TrampolineBlockWorkingMem,
JITTargetAddress TrampolineBlockTargetAddress,
JITTargetAddress ResolverAddr, unsigned NumTrampolines) {
unsigned OffsetToPtr = NumTrampolines * TrampolineSize;
memcpy(TrampolineBlockWorkingMem + OffsetToPtr, &ResolverAddr,
sizeof(uint64_t));
uint64_t *Trampolines =
reinterpret_cast<uint64_t *>(TrampolineBlockWorkingMem);
uint64_t CallIndirPCRel = 0xf1c40000000015ff;
for (unsigned I = 0; I < NumTrampolines; ++I, OffsetToPtr -= TrampolineSize)
Trampolines[I] = CallIndirPCRel | ((OffsetToPtr - 6) << 16);
}
void OrcX86_64_Base::writeIndirectStubsBlock(
char *StubsBlockWorkingMem, JITTargetAddress StubsBlockTargetAddress,
JITTargetAddress PointersBlockTargetAddress, unsigned NumStubs) {
// Stub format is:
//
// .section __orc_stubs
// stub1:
// jmpq *ptr1(%rip)
// .byte 0xC4 ; <- Invalid opcode padding.
// .byte 0xF1
// stub2:
// jmpq *ptr2(%rip)
//
// ...
//
// .section __orc_ptrs
// ptr1:
// .quad 0x0
// ptr2:
// .quad 0x0
//
// ...
// Populate the stubs page stubs and mark it executable.
static_assert(StubSize == PointerSize,
"Pointer and stub size must match for algorithm below");
assert(stubAndPointerRangesOk<OrcX86_64_Base>(
StubsBlockTargetAddress, PointersBlockTargetAddress, NumStubs) &&
"PointersBlock is out of range");
uint64_t *Stub = reinterpret_cast<uint64_t *>(StubsBlockWorkingMem);
uint64_t PtrOffsetField =
(PointersBlockTargetAddress - StubsBlockTargetAddress - 6) << 16;
for (unsigned I = 0; I < NumStubs; ++I)
Stub[I] = 0xF1C40000000025ff | PtrOffsetField;
}
void OrcX86_64_SysV::writeResolverCode(char *ResolverWorkingMem,
JITTargetAddress ResolverTargetAddress,
JITTargetAddress ReentryFnAddr,
JITTargetAddress ReentryCtxAddr) {
LLVM_DEBUG({
dbgs() << "Writing resolver code to "
<< formatv("{0:x16}", ResolverTargetAddress) << "\n";
});
const uint8_t ResolverCode[] = {
// resolver_entry:
0x55, // 0x00: pushq %rbp
0x48, 0x89, 0xe5, // 0x01: movq %rsp, %rbp
0x50, // 0x04: pushq %rax
0x53, // 0x05: pushq %rbx
0x51, // 0x06: pushq %rcx
0x52, // 0x07: pushq %rdx
0x56, // 0x08: pushq %rsi
0x57, // 0x09: pushq %rdi
0x41, 0x50, // 0x0a: pushq %r8
0x41, 0x51, // 0x0c: pushq %r9
0x41, 0x52, // 0x0e: pushq %r10
0x41, 0x53, // 0x10: pushq %r11
0x41, 0x54, // 0x12: pushq %r12
0x41, 0x55, // 0x14: pushq %r13
0x41, 0x56, // 0x16: pushq %r14
0x41, 0x57, // 0x18: pushq %r15
0x48, 0x81, 0xec, 0x08, 0x02, 0x00, 0x00, // 0x1a: subq 0x208, %rsp
0x48, 0x0f, 0xae, 0x04, 0x24, // 0x21: fxsave64 (%rsp)
0x48, 0xbf, // 0x26: movabsq <CBMgr>, %rdi
// 0x28: JIT re-entry ctx addr.
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x48, 0x8b, 0x75, 0x08, // 0x30: movq 8(%rbp), %rsi
0x48, 0x83, 0xee, 0x06, // 0x34: subq $6, %rsi
0x48, 0xb8, // 0x38: movabsq <REntry>, %rax
// 0x3a: JIT re-entry fn addr:
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0xff, 0xd0, // 0x42: callq *%rax
0x48, 0x89, 0x45, 0x08, // 0x44: movq %rax, 8(%rbp)
0x48, 0x0f, 0xae, 0x0c, 0x24, // 0x48: fxrstor64 (%rsp)
0x48, 0x81, 0xc4, 0x08, 0x02, 0x00, 0x00, // 0x4d: addq 0x208, %rsp
0x41, 0x5f, // 0x54: popq %r15
0x41, 0x5e, // 0x56: popq %r14
0x41, 0x5d, // 0x58: popq %r13
0x41, 0x5c, // 0x5a: popq %r12
0x41, 0x5b, // 0x5c: popq %r11
0x41, 0x5a, // 0x5e: popq %r10
0x41, 0x59, // 0x60: popq %r9
0x41, 0x58, // 0x62: popq %r8
0x5f, // 0x64: popq %rdi
0x5e, // 0x65: popq %rsi
0x5a, // 0x66: popq %rdx
0x59, // 0x67: popq %rcx
0x5b, // 0x68: popq %rbx
0x58, // 0x69: popq %rax
0x5d, // 0x6a: popq %rbp
0xc3, // 0x6b: retq
};
const unsigned ReentryFnAddrOffset = 0x3a;
const unsigned ReentryCtxAddrOffset = 0x28;
memcpy(ResolverWorkingMem, ResolverCode, sizeof(ResolverCode));
memcpy(ResolverWorkingMem + ReentryFnAddrOffset, &ReentryFnAddr,
sizeof(uint64_t));
memcpy(ResolverWorkingMem + ReentryCtxAddrOffset, &ReentryCtxAddr,
sizeof(uint64_t));
}
void OrcX86_64_Win32::writeResolverCode(char *ResolverWorkingMem,
JITTargetAddress ResolverTargetAddress,
JITTargetAddress ReentryFnAddr,
JITTargetAddress ReentryCtxAddr) {
// resolverCode is similar to OrcX86_64 with differences specific to windows
// x64 calling convention: arguments go into rcx, rdx and come in reverse
// order, shadow space allocation on stack
const uint8_t ResolverCode[] = {
// resolver_entry:
0x55, // 0x00: pushq %rbp
0x48, 0x89, 0xe5, // 0x01: movq %rsp, %rbp
0x50, // 0x04: pushq %rax
0x53, // 0x05: pushq %rbx
0x51, // 0x06: pushq %rcx
0x52, // 0x07: pushq %rdx
0x56, // 0x08: pushq %rsi
0x57, // 0x09: pushq %rdi
0x41, 0x50, // 0x0a: pushq %r8
0x41, 0x51, // 0x0c: pushq %r9
0x41, 0x52, // 0x0e: pushq %r10
0x41, 0x53, // 0x10: pushq %r11
0x41, 0x54, // 0x12: pushq %r12
0x41, 0x55, // 0x14: pushq %r13
0x41, 0x56, // 0x16: pushq %r14
0x41, 0x57, // 0x18: pushq %r15
0x48, 0x81, 0xec, 0x08, 0x02, 0x00, 0x00, // 0x1a: subq 0x208, %rsp
0x48, 0x0f, 0xae, 0x04, 0x24, // 0x21: fxsave64 (%rsp)
0x48, 0xb9, // 0x26: movabsq <CBMgr>, %rcx
// 0x28: JIT re-entry ctx addr.
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x48, 0x8B, 0x55, 0x08, // 0x30: mov rdx, [rbp+0x8]
0x48, 0x83, 0xea, 0x06, // 0x34: sub rdx, 0x6
0x48, 0xb8, // 0x38: movabsq <REntry>, %rax
// 0x3a: JIT re-entry fn addr:
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
// 0x42: sub rsp, 0x20 (Allocate shadow space)
0x48, 0x83, 0xEC, 0x20,
0xff, 0xd0, // 0x46: callq *%rax
// 0x48: add rsp, 0x20 (Free shadow space)
0x48, 0x83, 0xC4, 0x20,
0x48, 0x89, 0x45, 0x08, // 0x4C: movq %rax, 8(%rbp)
0x48, 0x0f, 0xae, 0x0c, 0x24, // 0x50: fxrstor64 (%rsp)
0x48, 0x81, 0xc4, 0x08, 0x02, 0x00, 0x00, // 0x55: addq 0x208, %rsp
0x41, 0x5f, // 0x5C: popq %r15
0x41, 0x5e, // 0x5E: popq %r14
0x41, 0x5d, // 0x60: popq %r13
0x41, 0x5c, // 0x62: popq %r12
0x41, 0x5b, // 0x64: popq %r11
0x41, 0x5a, // 0x66: popq %r10
0x41, 0x59, // 0x68: popq %r9
0x41, 0x58, // 0x6a: popq %r8
0x5f, // 0x6c: popq %rdi
0x5e, // 0x6d: popq %rsi
0x5a, // 0x6e: popq %rdx
0x59, // 0x6f: popq %rcx
0x5b, // 0x70: popq %rbx
0x58, // 0x71: popq %rax
0x5d, // 0x72: popq %rbp
0xc3, // 0x73: retq
};
const unsigned ReentryFnAddrOffset = 0x3a;
const unsigned ReentryCtxAddrOffset = 0x28;
memcpy(ResolverWorkingMem, ResolverCode, sizeof(ResolverCode));
memcpy(ResolverWorkingMem + ReentryFnAddrOffset, &ReentryFnAddr,
sizeof(uint64_t));
memcpy(ResolverWorkingMem + ReentryCtxAddrOffset, &ReentryCtxAddr,
sizeof(uint64_t));
}
void OrcI386::writeResolverCode(char *ResolverWorkingMem,
JITTargetAddress ResolverTargetAddress,
JITTargetAddress ReentryFnAddr,
JITTargetAddress ReentryCtxAddr) {
assert((ReentryFnAddr >> 32) == 0 && "ReentryFnAddr out of range");
assert((ReentryCtxAddr >> 32) == 0 && "ReentryCtxAddr out of range");
const uint8_t ResolverCode[] = {
// resolver_entry:
0x55, // 0x00: pushl %ebp
0x89, 0xe5, // 0x01: movl %esp, %ebp
0x54, // 0x03: pushl %esp
0x83, 0xe4, 0xf0, // 0x04: andl $-0x10, %esp
0x50, // 0x07: pushl %eax
0x53, // 0x08: pushl %ebx
0x51, // 0x09: pushl %ecx
0x52, // 0x0a: pushl %edx
0x56, // 0x0b: pushl %esi
0x57, // 0x0c: pushl %edi
0x81, 0xec, 0x18, 0x02, 0x00, 0x00, // 0x0d: subl $0x218, %esp
0x0f, 0xae, 0x44, 0x24, 0x10, // 0x13: fxsave 0x10(%esp)
0x8b, 0x75, 0x04, // 0x18: movl 0x4(%ebp), %esi
0x83, 0xee, 0x05, // 0x1b: subl $0x5, %esi
0x89, 0x74, 0x24, 0x04, // 0x1e: movl %esi, 0x4(%esp)
0xc7, 0x04, 0x24, 0x00, 0x00, 0x00,
0x00, // 0x22: movl <cbmgr>, (%esp)
0xb8, 0x00, 0x00, 0x00, 0x00, // 0x29: movl <reentry>, %eax
0xff, 0xd0, // 0x2e: calll *%eax
0x89, 0x45, 0x04, // 0x30: movl %eax, 0x4(%ebp)
0x0f, 0xae, 0x4c, 0x24, 0x10, // 0x33: fxrstor 0x10(%esp)
0x81, 0xc4, 0x18, 0x02, 0x00, 0x00, // 0x38: addl $0x218, %esp
0x5f, // 0x3e: popl %edi
0x5e, // 0x3f: popl %esi
0x5a, // 0x40: popl %edx
0x59, // 0x41: popl %ecx
0x5b, // 0x42: popl %ebx
0x58, // 0x43: popl %eax
0x8b, 0x65, 0xfc, // 0x44: movl -0x4(%ebp), %esp
0x5d, // 0x48: popl %ebp
0xc3 // 0x49: retl
};
const unsigned ReentryFnAddrOffset = 0x2a;
const unsigned ReentryCtxAddrOffset = 0x25;
memcpy(ResolverWorkingMem, ResolverCode, sizeof(ResolverCode));
memcpy(ResolverWorkingMem + ReentryFnAddrOffset, &ReentryFnAddr,
sizeof(uint32_t));
memcpy(ResolverWorkingMem + ReentryCtxAddrOffset, &ReentryCtxAddr,
sizeof(uint32_t));
}
void OrcI386::writeTrampolines(char *TrampolineWorkingMem,
JITTargetAddress TrampolineBlockTargetAddress,
JITTargetAddress ResolverAddr,
unsigned NumTrampolines) {
assert((ResolverAddr >> 32) == 0 && "ResolverAddr out of range");
uint64_t CallRelImm = 0xF1C4C400000000e8;
uint64_t ResolverRel = ResolverAddr - TrampolineBlockTargetAddress - 5;
uint64_t *Trampolines = reinterpret_cast<uint64_t *>(TrampolineWorkingMem);
for (unsigned I = 0; I < NumTrampolines; ++I, ResolverRel -= TrampolineSize)
Trampolines[I] = CallRelImm | (ResolverRel << 8);
}
void OrcI386::writeIndirectStubsBlock(
char *StubsBlockWorkingMem, JITTargetAddress StubsBlockTargetAddress,
JITTargetAddress PointersBlockTargetAddress, unsigned NumStubs) {
assert((StubsBlockTargetAddress >> 32) == 0 &&
"StubsBlockTargetAddress is out of range");
assert((PointersBlockTargetAddress >> 32) == 0 &&
"PointersBlockTargetAddress is out of range");
// Stub format is:
//
// .section __orc_stubs
// stub1:
// jmpq *ptr1
// .byte 0xC4 ; <- Invalid opcode padding.
// .byte 0xF1
// stub2:
// jmpq *ptr2
//
// ...
//
// .section __orc_ptrs
// ptr1:
// .quad 0x0
// ptr2:
// .quad 0x0
//
// ...
assert(stubAndPointerRangesOk<OrcI386>(
StubsBlockTargetAddress, PointersBlockTargetAddress, NumStubs) &&
"PointersBlock is out of range");
uint64_t *Stub = reinterpret_cast<uint64_t *>(StubsBlockWorkingMem);
uint64_t PtrAddr = PointersBlockTargetAddress;
for (unsigned I = 0; I < NumStubs; ++I, PtrAddr += 4)
Stub[I] = 0xF1C40000000025ff | (PtrAddr << 16);
}
void OrcMips32_Base::writeResolverCode(char *ResolverWorkingMem,
JITTargetAddress ResolverTargetAddress,
JITTargetAddress ReentryFnAddr,
JITTargetAddress ReentryCtxAddr,
bool isBigEndian) {
const uint32_t ResolverCode[] = {
// resolver_entry:
0x27bdff98, // 0x00: addiu $sp,$sp,-104
0xafa20000, // 0x04: sw $v0,0($sp)
0xafa30004, // 0x08: sw $v1,4($sp)
0xafa40008, // 0x0c: sw $a0,8($sp)
0xafa5000c, // 0x10: sw $a1,12($sp)
0xafa60010, // 0x14: sw $a2,16($sp)
0xafa70014, // 0x18: sw $a3,20($sp)
0xafb00018, // 0x1c: sw $s0,24($sp)
0xafb1001c, // 0x20: sw $s1,28($sp)
0xafb20020, // 0x24: sw $s2,32($sp)
0xafb30024, // 0x28: sw $s3,36($sp)
0xafb40028, // 0x2c: sw $s4,40($sp)
0xafb5002c, // 0x30: sw $s5,44($sp)
0xafb60030, // 0x34: sw $s6,48($sp)
0xafb70034, // 0x38: sw $s7,52($sp)
0xafa80038, // 0x3c: sw $t0,56($sp)
0xafa9003c, // 0x40: sw $t1,60($sp)
0xafaa0040, // 0x44: sw $t2,64($sp)
0xafab0044, // 0x48: sw $t3,68($sp)
0xafac0048, // 0x4c: sw $t4,72($sp)
0xafad004c, // 0x50: sw $t5,76($sp)
0xafae0050, // 0x54: sw $t6,80($sp)
0xafaf0054, // 0x58: sw $t7,84($sp)
0xafb80058, // 0x5c: sw $t8,88($sp)
0xafb9005c, // 0x60: sw $t9,92($sp)
0xafbe0060, // 0x64: sw $fp,96($sp)
0xafbf0064, // 0x68: sw $ra,100($sp)
// JIT re-entry ctx addr.
0x00000000, // 0x6c: lui $a0,ctx
0x00000000, // 0x70: addiu $a0,$a0,ctx
0x03e02825, // 0x74: move $a1, $ra
0x24a5ffec, // 0x78: addiu $a1,$a1,-20
// JIT re-entry fn addr:
0x00000000, // 0x7c: lui $t9,reentry
0x00000000, // 0x80: addiu $t9,$t9,reentry
0x0320f809, // 0x84: jalr $t9
0x00000000, // 0x88: nop
0x8fbf0064, // 0x8c: lw $ra,100($sp)
0x8fbe0060, // 0x90: lw $fp,96($sp)
0x8fb9005c, // 0x94: lw $t9,92($sp)
0x8fb80058, // 0x98: lw $t8,88($sp)
0x8faf0054, // 0x9c: lw $t7,84($sp)
0x8fae0050, // 0xa0: lw $t6,80($sp)
0x8fad004c, // 0xa4: lw $t5,76($sp)
0x8fac0048, // 0xa8: lw $t4,72($sp)
0x8fab0044, // 0xac: lw $t3,68($sp)
0x8faa0040, // 0xb0: lw $t2,64($sp)
0x8fa9003c, // 0xb4: lw $t1,60($sp)
0x8fa80038, // 0xb8: lw $t0,56($sp)
0x8fb70034, // 0xbc: lw $s7,52($sp)
0x8fb60030, // 0xc0: lw $s6,48($sp)
0x8fb5002c, // 0xc4: lw $s5,44($sp)
0x8fb40028, // 0xc8: lw $s4,40($sp)
0x8fb30024, // 0xcc: lw $s3,36($sp)
0x8fb20020, // 0xd0: lw $s2,32($sp)
0x8fb1001c, // 0xd4: lw $s1,28($sp)
0x8fb00018, // 0xd8: lw $s0,24($sp)
0x8fa70014, // 0xdc: lw $a3,20($sp)
0x8fa60010, // 0xe0: lw $a2,16($sp)
0x8fa5000c, // 0xe4: lw $a1,12($sp)
0x8fa40008, // 0xe8: lw $a0,8($sp)
0x27bd0068, // 0xec: addiu $sp,$sp,104
0x0300f825, // 0xf0: move $ra, $t8
0x03200008, // 0xf4: jr $t9
0x00000000, // 0xf8: move $t9, $v0/v1
};
const unsigned ReentryFnAddrOffset = 0x7c; // JIT re-entry fn addr lui
const unsigned ReentryCtxAddrOffset = 0x6c; // JIT re-entry context addr lui
const unsigned Offsett = 0xf8;
memcpy(ResolverWorkingMem, ResolverCode, sizeof(ResolverCode));
// Depending on endian return value will be in v0 or v1.
uint32_t MoveVxT9 = isBigEndian ? 0x0060c825 : 0x0040c825;
memcpy(ResolverWorkingMem + Offsett, &MoveVxT9, sizeof(MoveVxT9));
uint32_t ReentryCtxLUi =
0x3c040000 | (((ReentryCtxAddr + 0x8000) >> 16) & 0xFFFF);
uint32_t ReentryCtxADDiu = 0x24840000 | ((ReentryCtxAddr)&0xFFFF);
memcpy(ResolverWorkingMem + ReentryCtxAddrOffset, &ReentryCtxLUi,
sizeof(ReentryCtxLUi));
memcpy(ResolverWorkingMem + ReentryCtxAddrOffset + 4, &ReentryCtxADDiu,
sizeof(ReentryCtxADDiu));
uint32_t ReentryFnLUi =
0x3c190000 | (((ReentryFnAddr + 0x8000) >> 16) & 0xFFFF);
uint32_t ReentryFnADDiu = 0x27390000 | ((ReentryFnAddr)&0xFFFF);
memcpy(ResolverWorkingMem + ReentryFnAddrOffset, &ReentryFnLUi,
sizeof(ReentryFnLUi));
memcpy(ResolverWorkingMem + ReentryFnAddrOffset + 4, &ReentryFnADDiu,
sizeof(ReentryFnADDiu));
}
void OrcMips32_Base::writeTrampolines(
char *TrampolineBlockWorkingMem,
JITTargetAddress TrampolineBlockTargetAddress,
JITTargetAddress ResolverAddr, unsigned NumTrampolines) {
assert((ResolverAddr >> 32) == 0 && "ResolverAddr out of range");
uint32_t *Trampolines =
reinterpret_cast<uint32_t *>(TrampolineBlockWorkingMem);
uint32_t RHiAddr = ((ResolverAddr + 0x8000) >> 16);
for (unsigned I = 0; I < NumTrampolines; ++I) {
// move $t8,$ra
// lui $t9,ResolverAddr
// addiu $t9,$t9,ResolverAddr
// jalr $t9
// nop
Trampolines[5 * I + 0] = 0x03e0c025;
Trampolines[5 * I + 1] = 0x3c190000 | (RHiAddr & 0xFFFF);
Trampolines[5 * I + 2] = 0x27390000 | (ResolverAddr & 0xFFFF);
Trampolines[5 * I + 3] = 0x0320f809;
Trampolines[5 * I + 4] = 0x00000000;
}
}
void OrcMips32_Base::writeIndirectStubsBlock(
char *StubsBlockWorkingMem, JITTargetAddress StubsBlockTargetAddress,
JITTargetAddress PointersBlockTargetAddress, unsigned NumStubs) {
assert((StubsBlockTargetAddress >> 32) == 0 &&
"InitialPtrVal is out of range");
// Stub format is:
//
// .section __orc_stubs
// stub1:
// lui $t9, ptr1
// lw $t9, %lo(ptr1)($t9)
// jr $t9
// stub2:
// lui $t9, ptr2
// lw $t9,%lo(ptr1)($t9)
// jr $t9
//
// ...
//
// .section __orc_ptrs
// ptr1:
// .word 0x0
// ptr2:
// .word 0x0
//
// i..
assert(stubAndPointerRangesOk<OrcAArch64>(
StubsBlockTargetAddress, PointersBlockTargetAddress, NumStubs) &&
"PointersBlock is out of range");
// Populate the stubs page stubs and mark it executable.
uint32_t *Stub = reinterpret_cast<uint32_t *>(StubsBlockWorkingMem);
uint64_t PtrAddr = PointersBlockTargetAddress;
for (unsigned I = 0; I < NumStubs; ++I) {
uint32_t HiAddr = ((PtrAddr + 0x8000) >> 16);
Stub[4 * I + 0] = 0x3c190000 | (HiAddr & 0xFFFF); // lui $t9,ptr1
Stub[4 * I + 1] = 0x8f390000 | (PtrAddr & 0xFFFF); // lw $t9,%lo(ptr1)($t9)
Stub[4 * I + 2] = 0x03200008; // jr $t9
Stub[4 * I + 3] = 0x00000000; // nop
PtrAddr += 4;
}
}
void OrcMips64::writeResolverCode(char *ResolverWorkingMem,
JITTargetAddress ResolverTargetAddress,
JITTargetAddress ReentryFnAddr,
JITTargetAddress ReentryCtxAddr) {
const uint32_t ResolverCode[] = {
//resolver_entry:
0x67bdff30, // 0x00: daddiu $sp,$sp,-208
0xffa20000, // 0x04: sd v0,0(sp)
0xffa30008, // 0x08: sd v1,8(sp)
0xffa40010, // 0x0c: sd a0,16(sp)
0xffa50018, // 0x10: sd a1,24(sp)
0xffa60020, // 0x14: sd a2,32(sp)
0xffa70028, // 0x18: sd a3,40(sp)
0xffa80030, // 0x1c: sd a4,48(sp)
0xffa90038, // 0x20: sd a5,56(sp)
0xffaa0040, // 0x24: sd a6,64(sp)
0xffab0048, // 0x28: sd a7,72(sp)
0xffac0050, // 0x2c: sd t0,80(sp)
0xffad0058, // 0x30: sd t1,88(sp)
0xffae0060, // 0x34: sd t2,96(sp)
0xffaf0068, // 0x38: sd t3,104(sp)
0xffb00070, // 0x3c: sd s0,112(sp)
0xffb10078, // 0x40: sd s1,120(sp)
0xffb20080, // 0x44: sd s2,128(sp)
0xffb30088, // 0x48: sd s3,136(sp)
0xffb40090, // 0x4c: sd s4,144(sp)
0xffb50098, // 0x50: sd s5,152(sp)
0xffb600a0, // 0x54: sd s6,160(sp)
0xffb700a8, // 0x58: sd s7,168(sp)
0xffb800b0, // 0x5c: sd t8,176(sp)
0xffb900b8, // 0x60: sd t9,184(sp)
0xffbe00c0, // 0x64: sd fp,192(sp)
0xffbf00c8, // 0x68: sd ra,200(sp)
// JIT re-entry ctx addr.
0x00000000, // 0x6c: lui $a0,heighest(ctx)
0x00000000, // 0x70: daddiu $a0,$a0,heigher(ctx)
0x00000000, // 0x74: dsll $a0,$a0,16
0x00000000, // 0x78: daddiu $a0,$a0,hi(ctx)
0x00000000, // 0x7c: dsll $a0,$a0,16
0x00000000, // 0x80: daddiu $a0,$a0,lo(ctx)
0x03e02825, // 0x84: move $a1, $ra
0x64a5ffdc, // 0x88: daddiu $a1,$a1,-36
// JIT re-entry fn addr:
0x00000000, // 0x8c: lui $t9,reentry
0x00000000, // 0x90: daddiu $t9,$t9,reentry
0x00000000, // 0x94: dsll $t9,$t9,
0x00000000, // 0x98: daddiu $t9,$t9,
0x00000000, // 0x9c: dsll $t9,$t9,
0x00000000, // 0xa0: daddiu $t9,$t9,
0x0320f809, // 0xa4: jalr $t9
0x00000000, // 0xa8: nop
0xdfbf00c8, // 0xac: ld ra, 200(sp)
0xdfbe00c0, // 0xb0: ld fp, 192(sp)
0xdfb900b8, // 0xb4: ld t9, 184(sp)
0xdfb800b0, // 0xb8: ld t8, 176(sp)
0xdfb700a8, // 0xbc: ld s7, 168(sp)
0xdfb600a0, // 0xc0: ld s6, 160(sp)
0xdfb50098, // 0xc4: ld s5, 152(sp)
0xdfb40090, // 0xc8: ld s4, 144(sp)
0xdfb30088, // 0xcc: ld s3, 136(sp)
0xdfb20080, // 0xd0: ld s2, 128(sp)
0xdfb10078, // 0xd4: ld s1, 120(sp)
0xdfb00070, // 0xd8: ld s0, 112(sp)
0xdfaf0068, // 0xdc: ld t3, 104(sp)
0xdfae0060, // 0xe0: ld t2, 96(sp)
0xdfad0058, // 0xe4: ld t1, 88(sp)
0xdfac0050, // 0xe8: ld t0, 80(sp)
0xdfab0048, // 0xec: ld a7, 72(sp)
0xdfaa0040, // 0xf0: ld a6, 64(sp)
0xdfa90038, // 0xf4: ld a5, 56(sp)
0xdfa80030, // 0xf8: ld a4, 48(sp)
0xdfa70028, // 0xfc: ld a3, 40(sp)
0xdfa60020, // 0x100: ld a2, 32(sp)
0xdfa50018, // 0x104: ld a1, 24(sp)
0xdfa40010, // 0x108: ld a0, 16(sp)
0xdfa30008, // 0x10c: ld v1, 8(sp)
0x67bd00d0, // 0x110: daddiu $sp,$sp,208
0x0300f825, // 0x114: move $ra, $t8
0x03200008, // 0x118: jr $t9
0x0040c825, // 0x11c: move $t9, $v0
};
const unsigned ReentryFnAddrOffset = 0x8c; // JIT re-entry fn addr lui
const unsigned ReentryCtxAddrOffset = 0x6c; // JIT re-entry ctx addr lui
memcpy(ResolverWorkingMem, ResolverCode, sizeof(ResolverCode));
uint32_t ReentryCtxLUi =
0x3c040000 | (((ReentryCtxAddr + 0x800080008000) >> 48) & 0xFFFF);
uint32_t ReentryCtxDADDiu =
0x64840000 | (((ReentryCtxAddr + 0x80008000) >> 32) & 0xFFFF);
uint32_t ReentryCtxDSLL = 0x00042438;
uint32_t ReentryCtxDADDiu2 =
0x64840000 | ((((ReentryCtxAddr + 0x8000) >> 16) & 0xFFFF));
uint32_t ReentryCtxDSLL2 = 0x00042438;
uint32_t ReentryCtxDADDiu3 = 0x64840000 | ((ReentryCtxAddr)&0xFFFF);
memcpy(ResolverWorkingMem + ReentryCtxAddrOffset, &ReentryCtxLUi,
sizeof(ReentryCtxLUi));
memcpy(ResolverWorkingMem + (ReentryCtxAddrOffset + 4), &ReentryCtxDADDiu,
sizeof(ReentryCtxDADDiu));
memcpy(ResolverWorkingMem + (ReentryCtxAddrOffset + 8), &ReentryCtxDSLL,
sizeof(ReentryCtxDSLL));
memcpy(ResolverWorkingMem + (ReentryCtxAddrOffset + 12), &ReentryCtxDADDiu2,
sizeof(ReentryCtxDADDiu2));
memcpy(ResolverWorkingMem + (ReentryCtxAddrOffset + 16), &ReentryCtxDSLL2,
sizeof(ReentryCtxDSLL2));
memcpy(ResolverWorkingMem + (ReentryCtxAddrOffset + 20), &ReentryCtxDADDiu3,
sizeof(ReentryCtxDADDiu3));
uint32_t ReentryFnLUi =
0x3c190000 | (((ReentryFnAddr + 0x800080008000) >> 48) & 0xFFFF);
uint32_t ReentryFnDADDiu =
0x67390000 | (((ReentryFnAddr + 0x80008000) >> 32) & 0xFFFF);
uint32_t ReentryFnDSLL = 0x0019cc38;
uint32_t ReentryFnDADDiu2 =
0x67390000 | (((ReentryFnAddr + 0x8000) >> 16) & 0xFFFF);
uint32_t ReentryFnDSLL2 = 0x0019cc38;
uint32_t ReentryFnDADDiu3 = 0x67390000 | ((ReentryFnAddr)&0xFFFF);
memcpy(ResolverWorkingMem + ReentryFnAddrOffset, &ReentryFnLUi,
sizeof(ReentryFnLUi));
memcpy(ResolverWorkingMem + (ReentryFnAddrOffset + 4), &ReentryFnDADDiu,
sizeof(ReentryFnDADDiu));
memcpy(ResolverWorkingMem + (ReentryFnAddrOffset + 8), &ReentryFnDSLL,
sizeof(ReentryFnDSLL));
memcpy(ResolverWorkingMem + (ReentryFnAddrOffset + 12), &ReentryFnDADDiu2,
sizeof(ReentryFnDADDiu2));
memcpy(ResolverWorkingMem + (ReentryFnAddrOffset + 16), &ReentryFnDSLL2,
sizeof(ReentryFnDSLL2));
memcpy(ResolverWorkingMem + (ReentryFnAddrOffset + 20), &ReentryFnDADDiu3,
sizeof(ReentryFnDADDiu3));
}
void OrcMips64::writeTrampolines(char *TrampolineBlockWorkingMem,
JITTargetAddress TrampolineBlockTargetAddress,
JITTargetAddress ResolverAddr,
unsigned NumTrampolines) {
uint32_t *Trampolines =
reinterpret_cast<uint32_t *>(TrampolineBlockWorkingMem);
uint64_t HeighestAddr = ((ResolverAddr + 0x800080008000) >> 48);
uint64_t HeigherAddr = ((ResolverAddr + 0x80008000) >> 32);
uint64_t HiAddr = ((ResolverAddr + 0x8000) >> 16);
for (unsigned I = 0; I < NumTrampolines; ++I) {
Trampolines[10 * I + 0] = 0x03e0c025; // move $t8,$ra
Trampolines[10 * I + 1] = 0x3c190000 | (HeighestAddr & 0xFFFF); // lui $t9,resolveAddr
Trampolines[10 * I + 2] = 0x67390000 | (HeigherAddr & 0xFFFF); // daddiu $t9,$t9,%higher(resolveAddr)
Trampolines[10 * I + 3] = 0x0019cc38; // dsll $t9,$t9,16
Trampolines[10 * I + 4] = 0x67390000 | (HiAddr & 0xFFFF); // daddiu $t9,$t9,%hi(ptr)
Trampolines[10 * I + 5] = 0x0019cc38; // dsll $t9,$t9,16
Trampolines[10 * I + 6] =
0x67390000 | (ResolverAddr & 0xFFFF); // daddiu $t9,$t9,%lo(ptr)
Trampolines[10 * I + 7] = 0x0320f809; // jalr $t9
Trampolines[10 * I + 8] = 0x00000000; // nop
Trampolines[10 * I + 9] = 0x00000000; // nop
}
}
void OrcMips64::writeIndirectStubsBlock(
char *StubsBlockWorkingMem, JITTargetAddress StubsBlockTargetAddress,
JITTargetAddress PointersBlockTargetAddress, unsigned NumStubs) {
// Stub format is:
//
// .section __orc_stubs
// stub1:
// lui $t9,ptr1
// dsll $t9,$t9,16
// daddiu $t9,$t9,%hi(ptr)
// dsll $t9,$t9,16
// ld $t9,%lo(ptr)
// jr $t9
// stub2:
// lui $t9,ptr1
// dsll $t9,$t9,16
// daddiu $t9,$t9,%hi(ptr)
// dsll $t9,$t9,16
// ld $t9,%lo(ptr)
// jr $t9
//
// ...
//
// .section __orc_ptrs
// ptr1:
// .dword 0x0
// ptr2:
// .dword 0x0
//
// ...
assert(stubAndPointerRangesOk<OrcAArch64>(
StubsBlockTargetAddress, PointersBlockTargetAddress, NumStubs) &&
"PointersBlock is out of range");
// Populate the stubs page stubs and mark it executable.
uint32_t *Stub = reinterpret_cast<uint32_t *>(StubsBlockWorkingMem);
uint64_t PtrAddr = PointersBlockTargetAddress;
for (unsigned I = 0; I < NumStubs; ++I, PtrAddr += 8) {
uint64_t HeighestAddr = ((PtrAddr + 0x800080008000) >> 48);
uint64_t HeigherAddr = ((PtrAddr + 0x80008000) >> 32);
uint64_t HiAddr = ((PtrAddr + 0x8000) >> 16);
Stub[8 * I + 0] = 0x3c190000 | (HeighestAddr & 0xFFFF); // lui $t9,ptr1
Stub[8 * I + 1] = 0x67390000 | (HeigherAddr & 0xFFFF); // daddiu $t9,$t9,%higher(ptr)
Stub[8 * I + 2] = 0x0019cc38; // dsll $t9,$t9,16
Stub[8 * I + 3] = 0x67390000 | (HiAddr & 0xFFFF); // daddiu $t9,$t9,%hi(ptr)
Stub[8 * I + 4] = 0x0019cc38; // dsll $t9,$t9,16
Stub[8 * I + 5] = 0xdf390000 | (PtrAddr & 0xFFFF); // ld $t9,%lo(ptr)
Stub[8 * I + 6] = 0x03200008; // jr $t9
Stub[8 * I + 7] = 0x00000000; // nop
}
}
} // End namespace orc.
} // End namespace llvm.