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//===-- xray_mips.cpp -------------------------------------------*- C++ -*-===//
//
// 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
//
//===----------------------------------------------------------------------===//
//
// This file is a part of XRay, a dynamic runtime instrumentation system.
//
// Implementation of MIPS-specific routines (32-bit).
//
//===----------------------------------------------------------------------===//
#include "sanitizer_common/sanitizer_common.h"
#include "xray_defs.h"
#include "xray_interface_internal.h"
#include <atomic>
namespace __xray {
// The machine codes for some instructions used in runtime patching.
enum PatchOpcodes : uint32_t {
PO_ADDIU = 0x24000000, // addiu rt, rs, imm
PO_SW = 0xAC000000, // sw rt, offset(sp)
PO_LUI = 0x3C000000, // lui rs, %hi(address)
PO_ORI = 0x34000000, // ori rt, rs, %lo(address)
PO_JALR = 0x0000F809, // jalr rs
PO_LW = 0x8C000000, // lw rt, offset(address)
PO_B44 = 0x1000000b, // b #44
PO_NOP = 0x0, // nop
};
enum RegNum : uint32_t {
RN_T0 = 0x8,
RN_T9 = 0x19,
RN_RA = 0x1F,
RN_SP = 0x1D,
};
inline static uint32_t encodeInstruction(uint32_t Opcode, uint32_t Rs,
uint32_t Rt,
uint32_t Imm) XRAY_NEVER_INSTRUMENT {
return (Opcode | Rs << 21 | Rt << 16 | Imm);
}
inline static uint32_t
encodeSpecialInstruction(uint32_t Opcode, uint32_t Rs, uint32_t Rt, uint32_t Rd,
uint32_t Imm) XRAY_NEVER_INSTRUMENT {
return (Rs << 21 | Rt << 16 | Rd << 11 | Imm << 6 | Opcode);
}
inline static bool patchSled(const bool Enable, const uint32_t FuncId,
const XRaySledEntry &Sled,
void (*TracingHook)()) XRAY_NEVER_INSTRUMENT {
// When |Enable| == true,
// We replace the following compile-time stub (sled):
//
// xray_sled_n:
// B .tmpN
// 11 NOPs (44 bytes)
// .tmpN
// ADDIU T9, T9, 44
//
// With the following runtime patch:
//
// xray_sled_n (32-bit):
// addiu sp, sp, -8 ;create stack frame
// nop
// sw ra, 4(sp) ;save return address
// sw t9, 0(sp) ;save register t9
// lui t9, %hi(__xray_FunctionEntry/Exit)
// ori t9, t9, %lo(__xray_FunctionEntry/Exit)
// lui t0, %hi(function_id)
// jalr t9 ;call Tracing hook
// ori t0, t0, %lo(function_id) ;pass function id (delay slot)
// lw t9, 0(sp) ;restore register t9
// lw ra, 4(sp) ;restore return address
// addiu sp, sp, 8 ;delete stack frame
//
// We add 44 bytes to t9 because we want to adjust the function pointer to
// the actual start of function i.e. the address just after the noop sled.
// We do this because gp displacement relocation is emitted at the start of
// of the function i.e after the nop sled and to correctly calculate the
// global offset table address, t9 must hold the address of the instruction
// containing the gp displacement relocation.
// FIXME: Is this correct for the static relocation model?
//
// Replacement of the first 4-byte instruction should be the last and atomic
// operation, so that the user code which reaches the sled concurrently
// either jumps over the whole sled, or executes the whole sled when the
// latter is ready.
//
// When |Enable|==false, we set back the first instruction in the sled to be
// B #44
uint32_t *Address = reinterpret_cast<uint32_t *>(Sled.address());
if (Enable) {
uint32_t LoTracingHookAddr =
reinterpret_cast<int32_t>(TracingHook) & 0xffff;
uint32_t HiTracingHookAddr =
(reinterpret_cast<int32_t>(TracingHook) >> 16) & 0xffff;
uint32_t LoFunctionID = FuncId & 0xffff;
uint32_t HiFunctionID = (FuncId >> 16) & 0xffff;
Address[2] = encodeInstruction(PatchOpcodes::PO_SW, RegNum::RN_SP,
RegNum::RN_RA, 0x4);
Address[3] = encodeInstruction(PatchOpcodes::PO_SW, RegNum::RN_SP,
RegNum::RN_T9, 0x0);
Address[4] = encodeInstruction(PatchOpcodes::PO_LUI, 0x0, RegNum::RN_T9,
HiTracingHookAddr);
Address[5] = encodeInstruction(PatchOpcodes::PO_ORI, RegNum::RN_T9,
RegNum::RN_T9, LoTracingHookAddr);
Address[6] = encodeInstruction(PatchOpcodes::PO_LUI, 0x0, RegNum::RN_T0,
HiFunctionID);
Address[7] = encodeSpecialInstruction(PatchOpcodes::PO_JALR, RegNum::RN_T9,
0x0, RegNum::RN_RA, 0X0);
Address[8] = encodeInstruction(PatchOpcodes::PO_ORI, RegNum::RN_T0,
RegNum::RN_T0, LoFunctionID);
Address[9] = encodeInstruction(PatchOpcodes::PO_LW, RegNum::RN_SP,
RegNum::RN_T9, 0x0);
Address[10] = encodeInstruction(PatchOpcodes::PO_LW, RegNum::RN_SP,
RegNum::RN_RA, 0x4);
Address[11] = encodeInstruction(PatchOpcodes::PO_ADDIU, RegNum::RN_SP,
RegNum::RN_SP, 0x8);
uint32_t CreateStackSpaceInstr = encodeInstruction(
PatchOpcodes::PO_ADDIU, RegNum::RN_SP, RegNum::RN_SP, 0xFFF8);
std::atomic_store_explicit(
reinterpret_cast<std::atomic<uint32_t> *>(Address),
uint32_t(CreateStackSpaceInstr), std::memory_order_release);
} else {
std::atomic_store_explicit(
reinterpret_cast<std::atomic<uint32_t> *>(Address),
uint32_t(PatchOpcodes::PO_B44), std::memory_order_release);
}
return true;
}
bool patchFunctionEntry(const bool Enable, const uint32_t FuncId,
const XRaySledEntry &Sled,
void (*Trampoline)()) XRAY_NEVER_INSTRUMENT {
return patchSled(Enable, FuncId, Sled, Trampoline);
}
bool patchFunctionExit(const bool Enable, const uint32_t FuncId,
const XRaySledEntry &Sled) XRAY_NEVER_INSTRUMENT {
return patchSled(Enable, FuncId, Sled, __xray_FunctionExit);
}
bool patchFunctionTailExit(const bool Enable, const uint32_t FuncId,
const XRaySledEntry &Sled) XRAY_NEVER_INSTRUMENT {
// FIXME: In the future we'd need to distinguish between non-tail exits and
// tail exits for better information preservation.
return patchSled(Enable, FuncId, Sled, __xray_FunctionExit);
}
bool patchCustomEvent(const bool Enable, const uint32_t FuncId,
const XRaySledEntry &Sled) XRAY_NEVER_INSTRUMENT {
// FIXME: Implement in mips?
return false;
}
bool patchTypedEvent(const bool Enable, const uint32_t FuncId,
const XRaySledEntry &Sled) XRAY_NEVER_INSTRUMENT {
// FIXME: Implement in mips?
return false;
}
} // namespace __xray
extern "C" void __xray_ArgLoggerEntry() XRAY_NEVER_INSTRUMENT {
// FIXME: this will have to be implemented in the trampoline assembly file
}
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