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/*
* Copyright (c) 2010, 2012 ARM Limited
* All rights reserved
*
* The license below extends only to copyright in the software and shall
* not be construed as granting a license to any other intellectual
* property including but not limited to intellectual property relating
* to a hardware implementation of the functionality of the software
* licensed hereunder. You may use the software subject to the license
* terms below provided that you ensure that this notice is replicated
* unmodified and in its entirety in all distributions of the software,
* modified or unmodified, in source code or in binary form.
*
* Copyright (c) 2007-2008 The Florida State University
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met: redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer;
* redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution;
* neither the name of the copyright holders nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* Authors: Stephen Hines
* Ali Saidi
*/
#include "arch/arm/process.hh"
#include "arch/arm/isa_traits.hh"
#include "arch/arm/types.hh"
#include "base/loader/elf_object.hh"
#include "base/loader/object_file.hh"
#include "base/misc.hh"
#include "cpu/thread_context.hh"
#include "debug/Stack.hh"
#include "mem/page_table.hh"
#include "sim/byteswap.hh"
#include "sim/process_impl.hh"
#include "sim/syscall_return.hh"
#include "sim/system.hh"
using namespace std;
using namespace ArmISA;
ArmProcess::ArmProcess(ProcessParams *params, ObjectFile *objFile,
ObjectFile::Arch _arch)
: Process(params, objFile), arch(_arch)
{
}
ArmProcess32::ArmProcess32(ProcessParams *params, ObjectFile *objFile,
ObjectFile::Arch _arch)
: ArmProcess(params, objFile, _arch)
{
stack_base = 0xbf000000L;
// Set pointer for next thread stack. Reserve 8M for main stack.
next_thread_stack_base = stack_base - (8 * 1024 * 1024);
// Set up break point (Top of Heap)
brk_point = objFile->dataBase() + objFile->dataSize() + objFile->bssSize();
brk_point = roundUp(brk_point, PageBytes);
// Set up region for mmaps. For now, start at bottom of kuseg space.
mmap_end = 0x40000000L;
}
ArmProcess64::ArmProcess64(ProcessParams *params, ObjectFile *objFile,
ObjectFile::Arch _arch)
: ArmProcess(params, objFile, _arch)
{
stack_base = 0x7fffff0000L;
// Set pointer for next thread stack. Reserve 8M for main stack.
next_thread_stack_base = stack_base - (8 * 1024 * 1024);
// Set up break point (Top of Heap)
brk_point = objFile->dataBase() + objFile->dataSize() + objFile->bssSize();
brk_point = roundUp(brk_point, PageBytes);
// Set up region for mmaps. For now, start at bottom of kuseg space.
mmap_end = 0x4000000000L;
}
void
ArmProcess32::initState()
{
Process::initState();
argsInit<uint32_t>(PageBytes, INTREG_SP);
for (int i = 0; i < contextIds.size(); i++) {
ThreadContext * tc = system->getThreadContext(contextIds[i]);
CPACR cpacr = tc->readMiscReg(MISCREG_CPACR);
// Enable the floating point coprocessors.
cpacr.cp10 = 0x3;
cpacr.cp11 = 0x3;
tc->setMiscReg(MISCREG_CPACR, cpacr);
// Generically enable floating point support.
FPEXC fpexc = tc->readMiscReg(MISCREG_FPEXC);
fpexc.en = 1;
tc->setMiscReg(MISCREG_FPEXC, fpexc);
}
}
void
ArmProcess64::initState()
{
Process::initState();
argsInit<uint64_t>(PageBytes, INTREG_SP0);
for (int i = 0; i < contextIds.size(); i++) {
ThreadContext * tc = system->getThreadContext(contextIds[i]);
CPSR cpsr = tc->readMiscReg(MISCREG_CPSR);
cpsr.mode = MODE_EL0T;
tc->setMiscReg(MISCREG_CPSR, cpsr);
CPACR cpacr = tc->readMiscReg(MISCREG_CPACR_EL1);
// Enable the floating point coprocessors.
cpacr.cp10 = 0x3;
cpacr.cp11 = 0x3;
tc->setMiscReg(MISCREG_CPACR_EL1, cpacr);
// Generically enable floating point support.
FPEXC fpexc = tc->readMiscReg(MISCREG_FPEXC);
fpexc.en = 1;
tc->setMiscReg(MISCREG_FPEXC, fpexc);
}
}
template <class IntType>
void
ArmProcess::argsInit(int pageSize, IntRegIndex spIndex)
{
int intSize = sizeof(IntType);
typedef AuxVector<IntType> auxv_t;
std::vector<auxv_t> auxv;
string filename;
if (argv.size() < 1)
filename = "";
else
filename = argv[0];
//We want 16 byte alignment
uint64_t align = 16;
// Patch the ld_bias for dynamic executables.
updateBias();
// load object file into target memory
objFile->loadSections(initVirtMem);
enum ArmCpuFeature {
Arm_Swp = 1 << 0,
Arm_Half = 1 << 1,
Arm_Thumb = 1 << 2,
Arm_26Bit = 1 << 3,
Arm_FastMult = 1 << 4,
Arm_Fpa = 1 << 5,
Arm_Vfp = 1 << 6,
Arm_Edsp = 1 << 7,
Arm_Java = 1 << 8,
Arm_Iwmmxt = 1 << 9,
Arm_Crunch = 1 << 10,
Arm_ThumbEE = 1 << 11,
Arm_Neon = 1 << 12,
Arm_Vfpv3 = 1 << 13,
Arm_Vfpv3d16 = 1 << 14
};
//Setup the auxilliary vectors. These will already have endian conversion.
//Auxilliary vectors are loaded only for elf formatted executables.
ElfObject * elfObject = dynamic_cast<ElfObject *>(objFile);
if (elfObject) {
if (objFile->getOpSys() == ObjectFile::Linux) {
IntType features =
Arm_Swp |
Arm_Half |
Arm_Thumb |
// Arm_26Bit |
Arm_FastMult |
// Arm_Fpa |
Arm_Vfp |
Arm_Edsp |
// Arm_Java |
// Arm_Iwmmxt |
// Arm_Crunch |
Arm_ThumbEE |
Arm_Neon |
Arm_Vfpv3 |
Arm_Vfpv3d16 |
0;
//Bits which describe the system hardware capabilities
//XXX Figure out what these should be
auxv.push_back(auxv_t(M5_AT_HWCAP, features));
//Frequency at which times() increments
auxv.push_back(auxv_t(M5_AT_CLKTCK, 0x64));
//Whether to enable "secure mode" in the executable
auxv.push_back(auxv_t(M5_AT_SECURE, 0));
// Pointer to 16 bytes of random data
auxv.push_back(auxv_t(M5_AT_RANDOM, 0));
//The filename of the program
auxv.push_back(auxv_t(M5_AT_EXECFN, 0));
//The string "v71" -- ARM v7 architecture
auxv.push_back(auxv_t(M5_AT_PLATFORM, 0));
}
//The system page size
auxv.push_back(auxv_t(M5_AT_PAGESZ, ArmISA::PageBytes));
// For statically linked executables, this is the virtual address of the
// program header tables if they appear in the executable image
auxv.push_back(auxv_t(M5_AT_PHDR, elfObject->programHeaderTable()));
// This is the size of a program header entry from the elf file.
auxv.push_back(auxv_t(M5_AT_PHENT, elfObject->programHeaderSize()));
// This is the number of program headers from the original elf file.
auxv.push_back(auxv_t(M5_AT_PHNUM, elfObject->programHeaderCount()));
// This is the base address of the ELF interpreter; it should be
// zero for static executables or contain the base address for
// dynamic executables.
auxv.push_back(auxv_t(M5_AT_BASE, getBias()));
//XXX Figure out what this should be.
auxv.push_back(auxv_t(M5_AT_FLAGS, 0));
//The entry point to the program
auxv.push_back(auxv_t(M5_AT_ENTRY, objFile->entryPoint()));
//Different user and group IDs
auxv.push_back(auxv_t(M5_AT_UID, uid()));
auxv.push_back(auxv_t(M5_AT_EUID, euid()));
auxv.push_back(auxv_t(M5_AT_GID, gid()));
auxv.push_back(auxv_t(M5_AT_EGID, egid()));
}
//Figure out how big the initial stack nedes to be
// A sentry NULL void pointer at the top of the stack.
int sentry_size = intSize;
string platform = "v71";
int platform_size = platform.size() + 1;
// Bytes for AT_RANDOM above, we'll just keep them 0
int aux_random_size = 16; // as per the specification
// The aux vectors are put on the stack in two groups. The first group are
// the vectors that are generated as the elf is loaded. The second group
// are the ones that were computed ahead of time and include the platform
// string.
int aux_data_size = filename.size() + 1;
int env_data_size = 0;
for (int i = 0; i < envp.size(); ++i) {
env_data_size += envp[i].size() + 1;
}
int arg_data_size = 0;
for (int i = 0; i < argv.size(); ++i) {
arg_data_size += argv[i].size() + 1;
}
int info_block_size =
sentry_size + env_data_size + arg_data_size +
aux_data_size + platform_size + aux_random_size;
//Each auxilliary vector is two 4 byte words
int aux_array_size = intSize * 2 * (auxv.size() + 1);
int envp_array_size = intSize * (envp.size() + 1);
int argv_array_size = intSize * (argv.size() + 1);
int argc_size = intSize;
//Figure out the size of the contents of the actual initial frame
int frame_size =
info_block_size +
aux_array_size +
envp_array_size +
argv_array_size +
argc_size;
//There needs to be padding after the auxiliary vector data so that the
//very bottom of the stack is aligned properly.
int partial_size = frame_size;
int aligned_partial_size = roundUp(partial_size, align);
int aux_padding = aligned_partial_size - partial_size;
int space_needed = frame_size + aux_padding;
stack_min = stack_base - space_needed;
stack_min = roundDown(stack_min, align);
stack_size = stack_base - stack_min;
// map memory
allocateMem(roundDown(stack_min, pageSize), roundUp(stack_size, pageSize));
// map out initial stack contents
IntType sentry_base = stack_base - sentry_size;
IntType aux_data_base = sentry_base - aux_data_size;
IntType env_data_base = aux_data_base - env_data_size;
IntType arg_data_base = env_data_base - arg_data_size;
IntType platform_base = arg_data_base - platform_size;
IntType aux_random_base = platform_base - aux_random_size;
IntType auxv_array_base = aux_random_base - aux_array_size - aux_padding;
IntType envp_array_base = auxv_array_base - envp_array_size;
IntType argv_array_base = envp_array_base - argv_array_size;
IntType argc_base = argv_array_base - argc_size;
DPRINTF(Stack, "The addresses of items on the initial stack:\n");
DPRINTF(Stack, "0x%x - aux data\n", aux_data_base);
DPRINTF(Stack, "0x%x - env data\n", env_data_base);
DPRINTF(Stack, "0x%x - arg data\n", arg_data_base);
DPRINTF(Stack, "0x%x - random data\n", aux_random_base);
DPRINTF(Stack, "0x%x - platform base\n", platform_base);
DPRINTF(Stack, "0x%x - auxv array\n", auxv_array_base);
DPRINTF(Stack, "0x%x - envp array\n", envp_array_base);
DPRINTF(Stack, "0x%x - argv array\n", argv_array_base);
DPRINTF(Stack, "0x%x - argc \n", argc_base);
DPRINTF(Stack, "0x%x - stack min\n", stack_min);
// write contents to stack
// figure out argc
IntType argc = argv.size();
IntType guestArgc = ArmISA::htog(argc);
//Write out the sentry void *
IntType sentry_NULL = 0;
initVirtMem.writeBlob(sentry_base,
(uint8_t*)&sentry_NULL, sentry_size);
//Fix up the aux vectors which point to other data
for (int i = auxv.size() - 1; i >= 0; i--) {
if (auxv[i].a_type == M5_AT_PLATFORM) {
auxv[i].a_val = platform_base;
initVirtMem.writeString(platform_base, platform.c_str());
} else if (auxv[i].a_type == M5_AT_EXECFN) {
auxv[i].a_val = aux_data_base;
initVirtMem.writeString(aux_data_base, filename.c_str());
} else if (auxv[i].a_type == M5_AT_RANDOM) {
auxv[i].a_val = aux_random_base;
// Just leave the value 0, we don't want randomness
}
}
//Copy the aux stuff
for (int x = 0; x < auxv.size(); x++) {
initVirtMem.writeBlob(auxv_array_base + x * 2 * intSize,
(uint8_t*)&(auxv[x].a_type), intSize);
initVirtMem.writeBlob(auxv_array_base + (x * 2 + 1) * intSize,
(uint8_t*)&(auxv[x].a_val), intSize);
}
//Write out the terminating zeroed auxilliary vector
const uint64_t zero = 0;
initVirtMem.writeBlob(auxv_array_base + 2 * intSize * auxv.size(),
(uint8_t*)&zero, 2 * intSize);
copyStringArray(envp, envp_array_base, env_data_base, initVirtMem);
copyStringArray(argv, argv_array_base, arg_data_base, initVirtMem);
initVirtMem.writeBlob(argc_base, (uint8_t*)&guestArgc, intSize);
ThreadContext *tc = system->getThreadContext(contextIds[0]);
//Set the stack pointer register
tc->setIntReg(spIndex, stack_min);
//A pointer to a function to run when the program exits. We'll set this
//to zero explicitly to make sure this isn't used.
tc->setIntReg(ArgumentReg0, 0);
//Set argument regs 1 and 2 to argv[0] and envp[0] respectively
if (argv.size() > 0) {
tc->setIntReg(ArgumentReg1, arg_data_base + arg_data_size -
argv[argv.size() - 1].size() - 1);
} else {
tc->setIntReg(ArgumentReg1, 0);
}
if (envp.size() > 0) {
tc->setIntReg(ArgumentReg2, env_data_base + env_data_size -
envp[envp.size() - 1].size() - 1);
} else {
tc->setIntReg(ArgumentReg2, 0);
}
PCState pc;
pc.thumb(arch == ObjectFile::Thumb);
pc.nextThumb(pc.thumb());
pc.aarch64(arch == ObjectFile::Arm64);
pc.nextAArch64(pc.aarch64());
pc.set(getStartPC() & ~mask(1));
tc->pcState(pc);
//Align the "stack_min" to a page boundary.
stack_min = roundDown(stack_min, pageSize);
}
ArmISA::IntReg
ArmProcess32::getSyscallArg(ThreadContext *tc, int &i)
{
assert(i < 6);
return tc->readIntReg(ArgumentReg0 + i++);
}
ArmISA::IntReg
ArmProcess64::getSyscallArg(ThreadContext *tc, int &i)
{
assert(i < 8);
return tc->readIntReg(ArgumentReg0 + i++);
}
ArmISA::IntReg
ArmProcess32::getSyscallArg(ThreadContext *tc, int &i, int width)
{
assert(width == 32 || width == 64);
if (width == 32)
return getSyscallArg(tc, i);
// 64 bit arguments are passed starting in an even register
if (i % 2 != 0)
i++;
// Registers r0-r6 can be used
assert(i < 5);
uint64_t val;
val = tc->readIntReg(ArgumentReg0 + i++);
val |= ((uint64_t)tc->readIntReg(ArgumentReg0 + i++) << 32);
return val;
}
ArmISA::IntReg
ArmProcess64::getSyscallArg(ThreadContext *tc, int &i, int width)
{
return getSyscallArg(tc, i);
}
void
ArmProcess32::setSyscallArg(ThreadContext *tc, int i, ArmISA::IntReg val)
{
assert(i < 6);
tc->setIntReg(ArgumentReg0 + i, val);
}
void
ArmProcess64::setSyscallArg(ThreadContext *tc, int i, ArmISA::IntReg val)
{
assert(i < 8);
tc->setIntReg(ArgumentReg0 + i, val);
}
void
ArmProcess32::setSyscallReturn(ThreadContext *tc, SyscallReturn sysret)
{
if (objFile->getOpSys() == ObjectFile::FreeBSD) {
// Decode return value
if (sysret.encodedValue() >= 0)
// FreeBSD checks the carry bit to determine if syscall is succeeded
tc->setCCReg(CCREG_C, 0);
else {
sysret = -sysret.encodedValue();
}
}
tc->setIntReg(ReturnValueReg, sysret.encodedValue());
}
void
ArmProcess64::setSyscallReturn(ThreadContext *tc, SyscallReturn sysret)
{
if (objFile->getOpSys() == ObjectFile::FreeBSD) {
// Decode return value
if (sysret.encodedValue() >= 0)
// FreeBSD checks the carry bit to determine if syscall is succeeded
tc->setCCReg(CCREG_C, 0);
else {
sysret = -sysret.encodedValue();
}
}
tc->setIntReg(ReturnValueReg, sysret.encodedValue());
}
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