libunwindstack/Regs.cpp - android_system_core - Gitiles

 /*
  * Copyright (C) 2016 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include <assert.h>
 #include <elf.h>
 #include <stdint.h>
 #include <sys/ptrace.h>
 #include <sys/uio.h>

 #include <vector>

 #include "Elf.h"
 #include "ElfInterface.h"
 #include "Machine.h"
 #include "MapInfo.h"
 #include "Regs.h"
 #include "User.h"

 template <typename AddressType>
 uint64_t RegsTmpl<AddressType>::GetRelPc(Elf* elf, const MapInfo* map_info) {
   uint64_t load_bias = 0;
   if (elf->valid()) {
     load_bias = elf->interface()->load_bias();
   }

   return pc_ - map_info->start + load_bias + map_info->elf_offset;
 }

 template <typename AddressType>
 bool RegsTmpl<AddressType>::GetReturnAddressFromDefault(Memory* memory, uint64_t* value) {
   switch (return_loc_.type) {
   case LOCATION_REGISTER:
     assert(return_loc_.value < total_regs_);
     *value = regs_[return_loc_.value];
     return true;
   case LOCATION_SP_OFFSET:
     AddressType return_value;
     if (!memory->Read(sp_ + return_loc_.value, &return_value, sizeof(return_value))) {
       return false;
     }
     *value = return_value;
     return true;
   case LOCATION_UNKNOWN:
   default:
     return false;
   }
 }

 RegsArm::RegsArm() : RegsTmpl<uint32_t>(ARM_REG_LAST, ARM_REG_SP,
                                         Location(LOCATION_REGISTER, ARM_REG_LR)) {
 }

 uint64_t RegsArm::GetAdjustedPc(uint64_t rel_pc, Elf* elf) {
   if (!elf->valid()) {
     return rel_pc;
   }

   uint64_t load_bias = elf->interface()->load_bias();
   if (rel_pc < load_bias) {
     return rel_pc;
   }
   uint64_t adjusted_rel_pc = rel_pc - load_bias;

   if (adjusted_rel_pc < 5) {
     return rel_pc;
   }

   if (adjusted_rel_pc & 1) {
     // This is a thumb instruction, it could be 2 or 4 bytes.
     uint32_t value;
     if (rel_pc < 5 || !elf->memory()->Read(adjusted_rel_pc - 5, &value, sizeof(value)) ||
         (value & 0xe000f000) != 0xe000f000) {
       return rel_pc - 2;
     }
   }
   return rel_pc - 4;
 }

 RegsArm64::RegsArm64() : RegsTmpl<uint64_t>(ARM64_REG_LAST, ARM64_REG_SP,
                                             Location(LOCATION_REGISTER, ARM64_REG_LR)) {
 }

 uint64_t RegsArm64::GetAdjustedPc(uint64_t rel_pc, Elf* elf) {
   if (!elf->valid()) {
     return rel_pc;
   }

   if (rel_pc < 4) {
     return rel_pc;
   }
   return rel_pc - 4;
 }

 RegsX86::RegsX86() : RegsTmpl<uint32_t>(X86_REG_LAST, X86_REG_SP,
                                         Location(LOCATION_SP_OFFSET, -4)) {
 }

 uint64_t RegsX86::GetAdjustedPc(uint64_t rel_pc, Elf* elf) {
   if (!elf->valid()) {
     return rel_pc;
   }

   if (rel_pc == 0) {
     return 0;
   }
   return rel_pc - 1;
 }

 RegsX86_64::RegsX86_64() : RegsTmpl<uint64_t>(X86_64_REG_LAST, X86_64_REG_SP,
                                               Location(LOCATION_SP_OFFSET, -8)) {
 }

 uint64_t RegsX86_64::GetAdjustedPc(uint64_t rel_pc, Elf* elf) {
   if (!elf->valid()) {
     return rel_pc;
   }

   if (rel_pc == 0) {
     return 0;
   }

   return rel_pc - 1;
 }

 static Regs* ReadArm(void* remote_data) {
   arm_user_regs* user = reinterpret_cast<arm_user_regs*>(remote_data);

   RegsArm* regs = new RegsArm();
   memcpy(regs->RawData(), &user->regs[0], ARM_REG_LAST * sizeof(uint32_t));

   regs->set_pc(user->regs[ARM_REG_PC]);
   regs->set_sp(user->regs[ARM_REG_SP]);

   return regs;
 }

 static Regs* ReadArm64(void* remote_data) {
   arm64_user_regs* user = reinterpret_cast<arm64_user_regs*>(remote_data);

   RegsArm64* regs = new RegsArm64();
   memcpy(regs->RawData(), &user->regs[0], (ARM64_REG_R31 + 1) * sizeof(uint64_t));
   regs->set_pc(user->pc);
   regs->set_sp(user->sp);

   return regs;
 }

 static Regs* ReadX86(void* remote_data) {
   x86_user_regs* user = reinterpret_cast<x86_user_regs*>(remote_data);

   RegsX86* regs = new RegsX86();
   (*regs)[X86_REG_EAX] = user->eax;
   (*regs)[X86_REG_EBX] = user->ebx;
   (*regs)[X86_REG_ECX] = user->ecx;
   (*regs)[X86_REG_EDX] = user->edx;
   (*regs)[X86_REG_EBP] = user->ebp;
   (*regs)[X86_REG_EDI] = user->edi;
   (*regs)[X86_REG_ESI] = user->esi;
   (*regs)[X86_REG_ESP] = user->esp;
   (*regs)[X86_REG_EIP] = user->eip;

   regs->set_pc(user->eip);
   regs->set_sp(user->esp);

   return regs;
 }

 static Regs* ReadX86_64(void* remote_data) {
   x86_64_user_regs* user = reinterpret_cast<x86_64_user_regs*>(remote_data);

   RegsX86_64* regs = new RegsX86_64();
   (*regs)[X86_64_REG_RAX] = user->rax;
   (*regs)[X86_64_REG_RBX] = user->rbx;
   (*regs)[X86_64_REG_RCX] = user->rcx;
   (*regs)[X86_64_REG_RDX] = user->rdx;
   (*regs)[X86_64_REG_R8] = user->r8;
   (*regs)[X86_64_REG_R9] = user->r9;
   (*regs)[X86_64_REG_R10] = user->r10;
   (*regs)[X86_64_REG_R11] = user->r11;
   (*regs)[X86_64_REG_R12] = user->r12;
   (*regs)[X86_64_REG_R13] = user->r13;
   (*regs)[X86_64_REG_R14] = user->r14;
   (*regs)[X86_64_REG_R15] = user->r15;
   (*regs)[X86_64_REG_RDI] = user->rdi;
   (*regs)[X86_64_REG_RSI] = user->rsi;
   (*regs)[X86_64_REG_RBP] = user->rbp;
   (*regs)[X86_64_REG_RSP] = user->rsp;
   (*regs)[X86_64_REG_RIP] = user->rip;

   regs->set_pc(user->rip);
   regs->set_sp(user->rsp);

   return regs;
 }

 // This function assumes that reg_data is already aligned to a 64 bit value.
 // If not this could crash with an unaligned access.
 Regs* Regs::RemoteGet(pid_t pid, uint32_t* machine_type) {
   // Make the buffer large enough to contain the largest registers type.
   std::vector<uint64_t> buffer(MAX_USER_REGS_SIZE / sizeof(uint64_t));
   struct iovec io;
   io.iov_base = buffer.data();
   io.iov_len = buffer.size() * sizeof(uint64_t);

   if (ptrace(PTRACE_GETREGSET, pid, NT_PRSTATUS, reinterpret_cast<void*>(&io)) == -1) {
     return nullptr;
   }

   switch (io.iov_len) {
   case sizeof(x86_user_regs):
     *machine_type = EM_386;
     return ReadX86(buffer.data());
   case sizeof(x86_64_user_regs):
     *machine_type = EM_X86_64;
     return ReadX86_64(buffer.data());
   case sizeof(arm_user_regs):
     *machine_type = EM_ARM;
     return ReadArm(buffer.data());
   case sizeof(arm64_user_regs):
     *machine_type = EM_AARCH64;
     return ReadArm64(buffer.data());
   }
   return nullptr;
 }
	/*
	* Copyright (C) 2016 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include <assert.h>
	#include <elf.h>
	#include <stdint.h>
	#include <sys/ptrace.h>
	#include <sys/uio.h>

	#include <vector>

	#include "Elf.h"
	#include "ElfInterface.h"
	#include "Machine.h"
	#include "MapInfo.h"
	#include "Regs.h"
	#include "User.h"

	template <typename AddressType>
	uint64_t RegsTmpl<AddressType>::GetRelPc(Elf* elf, const MapInfo* map_info) {
	uint64_t load_bias = 0;
	if (elf->valid()) {
	load_bias = elf->interface()->load_bias();
	}

	return pc_ - map_info->start + load_bias + map_info->elf_offset;
	}

	template <typename AddressType>
	bool RegsTmpl<AddressType>::GetReturnAddressFromDefault(Memory* memory, uint64_t* value) {
	switch (return_loc_.type) {
	case LOCATION_REGISTER:
	assert(return_loc_.value < total_regs_);
	*value = regs_[return_loc_.value];
	return true;
	case LOCATION_SP_OFFSET:
	AddressType return_value;
	if (!memory->Read(sp_ + return_loc_.value, &return_value, sizeof(return_value))) {
	return false;
	}
	*value = return_value;
	return true;
	case LOCATION_UNKNOWN:
	default:
	return false;
	}
	}

	RegsArm::RegsArm() : RegsTmpl<uint32_t>(ARM_REG_LAST, ARM_REG_SP,
	Location(LOCATION_REGISTER, ARM_REG_LR)) {
	}

	uint64_t RegsArm::GetAdjustedPc(uint64_t rel_pc, Elf* elf) {
	if (!elf->valid()) {
	return rel_pc;
	}

	uint64_t load_bias = elf->interface()->load_bias();
	if (rel_pc < load_bias) {
	return rel_pc;
	}
	uint64_t adjusted_rel_pc = rel_pc - load_bias;

	if (adjusted_rel_pc < 5) {
	return rel_pc;
	}

	if (adjusted_rel_pc & 1) {
	// This is a thumb instruction, it could be 2 or 4 bytes.
	uint32_t value;
	if (rel_pc < 5 \|\| !elf->memory()->Read(adjusted_rel_pc - 5, &value, sizeof(value)) \|\|
	(value & 0xe000f000) != 0xe000f000) {
	return rel_pc - 2;
	}
	}
	return rel_pc - 4;
	}

	RegsArm64::RegsArm64() : RegsTmpl<uint64_t>(ARM64_REG_LAST, ARM64_REG_SP,
	Location(LOCATION_REGISTER, ARM64_REG_LR)) {
	}

	uint64_t RegsArm64::GetAdjustedPc(uint64_t rel_pc, Elf* elf) {
	if (!elf->valid()) {
	return rel_pc;
	}

	if (rel_pc < 4) {
	return rel_pc;
	}
	return rel_pc - 4;
	}

	RegsX86::RegsX86() : RegsTmpl<uint32_t>(X86_REG_LAST, X86_REG_SP,
	Location(LOCATION_SP_OFFSET, -4)) {
	}

	uint64_t RegsX86::GetAdjustedPc(uint64_t rel_pc, Elf* elf) {
	if (!elf->valid()) {
	return rel_pc;
	}

	if (rel_pc == 0) {
	return 0;
	}
	return rel_pc - 1;
	}

	RegsX86_64::RegsX86_64() : RegsTmpl<uint64_t>(X86_64_REG_LAST, X86_64_REG_SP,
	Location(LOCATION_SP_OFFSET, -8)) {
	}

	uint64_t RegsX86_64::GetAdjustedPc(uint64_t rel_pc, Elf* elf) {
	if (!elf->valid()) {
	return rel_pc;
	}

	if (rel_pc == 0) {
	return 0;
	}

	return rel_pc - 1;
	}

	static Regs* ReadArm(void* remote_data) {
	arm_user_regs* user = reinterpret_cast<arm_user_regs*>(remote_data);

	RegsArm* regs = new RegsArm();
	memcpy(regs->RawData(), &user->regs[0], ARM_REG_LAST * sizeof(uint32_t));

	regs->set_pc(user->regs[ARM_REG_PC]);
	regs->set_sp(user->regs[ARM_REG_SP]);

	return regs;
	}

	static Regs* ReadArm64(void* remote_data) {
	arm64_user_regs* user = reinterpret_cast<arm64_user_regs*>(remote_data);

	RegsArm64* regs = new RegsArm64();
	memcpy(regs->RawData(), &user->regs[0], (ARM64_REG_R31 + 1) * sizeof(uint64_t));
	regs->set_pc(user->pc);
	regs->set_sp(user->sp);

	return regs;
	}

	static Regs* ReadX86(void* remote_data) {
	x86_user_regs* user = reinterpret_cast<x86_user_regs*>(remote_data);

	RegsX86* regs = new RegsX86();
	(*regs)[X86_REG_EAX] = user->eax;
	(*regs)[X86_REG_EBX] = user->ebx;
	(*regs)[X86_REG_ECX] = user->ecx;
	(*regs)[X86_REG_EDX] = user->edx;
	(*regs)[X86_REG_EBP] = user->ebp;
	(*regs)[X86_REG_EDI] = user->edi;
	(*regs)[X86_REG_ESI] = user->esi;
	(*regs)[X86_REG_ESP] = user->esp;
	(*regs)[X86_REG_EIP] = user->eip;

	regs->set_pc(user->eip);
	regs->set_sp(user->esp);

	return regs;
	}

	static Regs* ReadX86_64(void* remote_data) {
	x86_64_user_regs* user = reinterpret_cast<x86_64_user_regs*>(remote_data);

	RegsX86_64* regs = new RegsX86_64();
	(*regs)[X86_64_REG_RAX] = user->rax;
	(*regs)[X86_64_REG_RBX] = user->rbx;
	(*regs)[X86_64_REG_RCX] = user->rcx;
	(*regs)[X86_64_REG_RDX] = user->rdx;
	(*regs)[X86_64_REG_R8] = user->r8;
	(*regs)[X86_64_REG_R9] = user->r9;
	(*regs)[X86_64_REG_R10] = user->r10;
	(*regs)[X86_64_REG_R11] = user->r11;
	(*regs)[X86_64_REG_R12] = user->r12;
	(*regs)[X86_64_REG_R13] = user->r13;
	(*regs)[X86_64_REG_R14] = user->r14;
	(*regs)[X86_64_REG_R15] = user->r15;
	(*regs)[X86_64_REG_RDI] = user->rdi;
	(*regs)[X86_64_REG_RSI] = user->rsi;
	(*regs)[X86_64_REG_RBP] = user->rbp;
	(*regs)[X86_64_REG_RSP] = user->rsp;
	(*regs)[X86_64_REG_RIP] = user->rip;

	regs->set_pc(user->rip);
	regs->set_sp(user->rsp);

	return regs;
	}

	// This function assumes that reg_data is already aligned to a 64 bit value.
	// If not this could crash with an unaligned access.
	Regs* Regs::RemoteGet(pid_t pid, uint32_t* machine_type) {
	// Make the buffer large enough to contain the largest registers type.
	std::vector<uint64_t> buffer(MAX_USER_REGS_SIZE / sizeof(uint64_t));
	struct iovec io;
	io.iov_base = buffer.data();
	io.iov_len = buffer.size() * sizeof(uint64_t);

	if (ptrace(PTRACE_GETREGSET, pid, NT_PRSTATUS, reinterpret_cast<void*>(&io)) == -1) {
	return nullptr;
	}

	switch (io.iov_len) {
	case sizeof(x86_user_regs):
	*machine_type = EM_386;
	return ReadX86(buffer.data());
	case sizeof(x86_64_user_regs):
	*machine_type = EM_X86_64;
	return ReadX86_64(buffer.data());
	case sizeof(arm_user_regs):
	*machine_type = EM_ARM;
	return ReadArm(buffer.data());
	case sizeof(arm64_user_regs):
	*machine_type = EM_AARCH64;
	return ReadArm64(buffer.data());
	}
	return nullptr;
	}