gecko/tools/profiler/EHABIStackWalk.cpp

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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/*
* This is an implementation of stack unwinding according to a subset
* of the ARM Exception Handling ABI, as described in:
* http://infocenter.arm.com/help/topic/com.arm.doc.ihi0038a/IHI0038A_ehabi.pdf
*
* This handles only the ARM-defined "personality routines" (chapter
* 9), and don't track the value of FP registers, because profiling
* needs only chain of PC/SP values.
*
* Because the exception handling info may not be accurate for all
* possible places where an async signal could occur (e.g., in a
* prologue or epilogue), this bounds-checks all stack accesses.
*
* This file uses "struct" for structures in the exception tables and
* "class" otherwise. We should avoid violating the C++11
* standard-layout rules in the former.
*/
#include "EHABIStackWalk.h"
#include "shared-libraries.h"
#include "platform.h"
#include "mozilla/Atomics.h"
#include "mozilla/Attributes.h"
#include "mozilla/DebugOnly.h"
#include "mozilla/Endian.h"
#include <algorithm>
#include <elf.h>
#include <stdint.h>
#include <vector>
#include <string>
#ifndef PT_ARM_EXIDX
#define PT_ARM_EXIDX 0x70000001
#endif
namespace mozilla {
struct EHEntry;
class EHState {
// Note that any core register can be used as a "frame pointer" to
// influence the unwinding process, so this must track all of them.
uint32_t mRegs[16];
public:
bool unwind(const EHEntry *aEntry, const void *stackBase);
uint32_t &operator[](int i) { return mRegs[i]; }
const uint32_t &operator[](int i) const { return mRegs[i]; }
EHState(const mcontext_t &);
};
enum {
R_SP = 13,
R_LR = 14,
R_PC = 15
};
class EHEntryHandle {
const EHEntry *mValue;
public:
EHEntryHandle(const EHEntry *aEntry) : mValue(aEntry) { }
const EHEntry *value() const { return mValue; }
};
class EHTable {
uint32_t mStartPC;
uint32_t mEndPC;
uint32_t mLoadOffset;
// In principle we should be able to binary-search the index section in
// place, but the ICS toolchain's linker is noncompliant and produces
// indices that aren't entirely sorted (e.g., libc). So we have this:
std::vector<EHEntryHandle> mEntries;
std::string mName;
public:
EHTable(const void *aELF, size_t aSize, const std::string &aName);
const EHEntry *lookup(uint32_t aPC) const;
bool isValid() const { return mEntries.size() > 0; }
const std::string &name() const { return mName; }
uint32_t startPC() const { return mStartPC; }
uint32_t endPC() const { return mEndPC; }
uint32_t loadOffset() const { return mLoadOffset; }
};
class EHAddrSpace {
std::vector<uint32_t> mStarts;
std::vector<EHTable> mTables;
static mozilla::Atomic<const EHAddrSpace*> sCurrent;
public:
explicit EHAddrSpace(const std::vector<EHTable>& aTables);
const EHTable *lookup(uint32_t aPC) const;
static void Update();
static const EHAddrSpace *Get();
};
void EHABIStackWalkInit()
{
EHAddrSpace::Update();
}
size_t EHABIStackWalk(const mcontext_t &aContext, void *stackBase,
void **aSPs, void **aPCs, const size_t aNumFrames)
{
const EHAddrSpace *space = EHAddrSpace::Get();
EHState state(aContext);
size_t count = 0;
while (count < aNumFrames) {
uint32_t pc = state[R_PC], sp = state[R_SP];
aPCs[count] = reinterpret_cast<void *>(pc);
aSPs[count] = reinterpret_cast<void *>(sp);
count++;
if (!space)
break;
// TODO: cache these lookups. Binary-searching libxul is
// expensive (possibly more expensive than doing the actual
// unwind), and even a small cache should help.
const EHTable *table = space->lookup(pc);
if (!table)
break;
const EHEntry *entry = table->lookup(pc);
if (!entry)
break;
if (!state.unwind(entry, stackBase))
break;
}
return count;
}
struct PRel31 {
uint32_t mBits;
bool topBit() const { return mBits & 0x80000000; }
uint32_t value() const { return mBits & 0x7fffffff; }
int32_t offset() const { return (static_cast<int32_t>(mBits) << 1) >> 1; }
const void *compute() const {
return reinterpret_cast<const char *>(this) + offset();
}
private:
PRel31(const PRel31 &copied) MOZ_DELETE;
PRel31() MOZ_DELETE;
};
struct EHEntry {
PRel31 startPC;
PRel31 exidx;
private:
EHEntry(const EHEntry &copied) MOZ_DELETE;
EHEntry() MOZ_DELETE;
};
class EHInterp {
public:
// Note that stackLimit is exclusive and stackBase is inclusive
// (i.e, stackLimit < SP <= stackBase), following the convention
// set by the AAPCS spec.
EHInterp(EHState &aState, const EHEntry *aEntry,
uint32_t aStackLimit, uint32_t aStackBase)
: mState(aState),
mStackLimit(aStackLimit),
mStackBase(aStackBase),
mNextWord(0),
mWordsLeft(0),
mFailed(false)
{
const PRel31 &exidx = aEntry->exidx;
uint32_t firstWord;
if (exidx.mBits == 1) { // EXIDX_CANTUNWIND
mFailed = true;
return;
}
if (exidx.topBit()) {
firstWord = exidx.mBits;
} else {
mNextWord = reinterpret_cast<const uint32_t *>(exidx.compute());
firstWord = *mNextWord++;
}
switch (firstWord >> 24) {
case 0x80: // short
mWord = firstWord << 8;
mBytesLeft = 3;
break;
case 0x81: case 0x82: // long; catch descriptor size ignored
mWord = firstWord << 16;
mBytesLeft = 2;
mWordsLeft = (firstWord >> 16) & 0xff;
break;
default:
// unknown personality
mFailed = true;
}
}
bool unwind();
private:
// TODO: GCC has been observed not CSEing repeated reads of
// mState[R_SP] with writes to mFailed between them, suggesting that
// it hasn't determined that they can't alias and is thus missing
// optimization opportunities. So, we may want to flatten EHState
// into this class; this may also make the code simpler.
EHState &mState;
uint32_t mStackLimit;
uint32_t mStackBase;
const uint32_t *mNextWord;
uint32_t mWord;
uint8_t mWordsLeft;
uint8_t mBytesLeft;
bool mFailed;
enum {
I_ADDSP = 0x00, // 0sxxxxxx (subtract if s)
M_ADDSP = 0x80,
I_POPMASK = 0x80, // 1000iiii iiiiiiii (if any i set)
M_POPMASK = 0xf0,
I_MOVSP = 0x90, // 1001nnnn
M_MOVSP = 0xf0,
I_POPN = 0xa0, // 1010lnnn
M_POPN = 0xf0,
I_FINISH = 0xb0, // 10110000
I_POPLO = 0xb1, // 10110001 0000iiii (if any i set)
I_ADDSPBIG = 0xb2, // 10110010 uleb128
I_POPFDX = 0xb3, // 10110011 sssscccc
I_POPFDX8 = 0xb8, // 10111nnn
M_POPFDX8 = 0xf8,
// "Intel Wireless MMX" extensions omitted.
I_POPFDD = 0xc8, // 1100100h sssscccc
M_POPFDD = 0xfe,
I_POPFDD8 = 0xd0, // 11010nnn
M_POPFDD8 = 0xf8
};
uint8_t next() {
if (mBytesLeft == 0) {
if (mWordsLeft == 0) {
return I_FINISH;
}
mWordsLeft--;
mWord = *mNextWord++;
mBytesLeft = 4;
}
mBytesLeft--;
mWord = (mWord << 8) | (mWord >> 24); // rotate
return mWord;
}
uint32_t &vSP() { return mState[R_SP]; }
uint32_t *ptrSP() { return reinterpret_cast<uint32_t *>(vSP()); }
void checkStackBase() { if (vSP() > mStackBase) mFailed = true; }
void checkStackLimit() { if (vSP() <= mStackLimit) mFailed = true; }
void checkStackAlign() { if ((vSP() & 3) != 0) mFailed = true; }
void checkStack() {
checkStackBase();
checkStackLimit();
checkStackAlign();
}
void popRange(uint8_t first, uint8_t last, uint16_t mask) {
bool hasSP = false;
uint32_t tmpSP;
if (mask == 0)
mFailed = true;
for (uint8_t r = first; r <= last; ++r) {
if (mask & 1) {
if (r == R_SP) {
hasSP = true;
tmpSP = *ptrSP();
} else
mState[r] = *ptrSP();
vSP() += 4;
checkStackBase();
if (mFailed)
return;
}
mask >>= 1;
}
if (hasSP) {
vSP() = tmpSP;
checkStack();
}
}
};
bool EHState::unwind(const EHEntry *aEntry, const void *stackBasePtr) {
// The unwinding program cannot set SP to less than the initial value.
uint32_t stackLimit = mRegs[R_SP] - 4;
uint32_t stackBase = reinterpret_cast<uint32_t>(stackBasePtr);
EHInterp interp(*this, aEntry, stackLimit, stackBase);
return interp.unwind();
}
bool EHInterp::unwind() {
mState[R_PC] = 0;
checkStack();
while (!mFailed) {
uint8_t insn = next();
#if DEBUG_EHABI_UNWIND
LOGF("unwind insn = %02x", (unsigned)insn);
#endif
// Try to put the common cases first.
// 00xxxxxx: vsp = vsp + (xxxxxx << 2) + 4
// 01xxxxxx: vsp = vsp - (xxxxxx << 2) - 4
if ((insn & M_ADDSP) == I_ADDSP) {
uint32_t offset = ((insn & 0x3f) << 2) + 4;
if (insn & 0x40) {
vSP() -= offset;
checkStackLimit();
} else {
vSP() += offset;
checkStackBase();
}
continue;
}
// 10100nnn: Pop r4-r[4+nnn]
// 10101nnn: Pop r4-r[4+nnn], r14
if ((insn & M_POPN) == I_POPN) {
uint8_t n = (insn & 0x07) + 1;
bool lr = insn & 0x08;
uint32_t *ptr = ptrSP();
vSP() += (n + (lr ? 1 : 0)) * 4;
checkStackBase();
for (uint8_t r = 4; r < 4 + n; ++r)
mState[r] = *ptr++;
if (lr)
mState[R_LR] = *ptr++;
continue;
}
// 1011000: Finish
if (insn == I_FINISH) {
if (mState[R_PC] == 0) {
mState[R_PC] = mState[R_LR];
// Non-standard change (bug 916106): Prevent the caller from
// re-using LR. Since the caller is by definition not a leaf
// routine, it will have to restore LR from somewhere to
// return to its own caller, so we can safely zero it here.
// This makes a difference only if an error in unwinding
// (e.g., caused by starting from within a prologue/epilogue)
// causes us to load a pointer to a leaf routine as LR; if we
// don't do something, we'll go into an infinite loop of
// "returning" to that same function.
mState[R_LR] = 0;
}
return true;
}
// 1001nnnn: Set vsp = r[nnnn]
if ((insn & M_MOVSP) == I_MOVSP) {
vSP() = mState[insn & 0x0f];
checkStack();
continue;
}
// 11001000 sssscccc: Pop VFP regs D[16+ssss]-D[16+ssss+cccc] (as FLDMFDD)
// 11001001 sssscccc: Pop VFP regs D[ssss]-D[ssss+cccc] (as FLDMFDD)
if ((insn & M_POPFDD) == I_POPFDD) {
uint8_t n = (next() & 0x0f) + 1;
// Note: if the 16+ssss+cccc > 31, the encoding is reserved.
// As the space is currently unused, we don't try to check.
vSP() += 8 * n;
checkStackBase();
continue;
}
// 11010nnn: Pop VFP regs D[8]-D[8+nnn] (as FLDMFDD)
if ((insn & M_POPFDD8) == I_POPFDD8) {
uint8_t n = (insn & 0x07) + 1;
vSP() += 8 * n;
checkStackBase();
continue;
}
// 10110010 uleb128: vsp = vsp + 0x204 + (uleb128 << 2)
if (insn == I_ADDSPBIG) {
uint32_t acc = 0;
uint8_t shift = 0;
uint8_t byte;
do {
if (shift >= 32)
return false;
byte = next();
acc |= (byte & 0x7f) << shift;
shift += 7;
} while (byte & 0x80);
uint32_t offset = 0x204 + (acc << 2);
// The calculations above could have overflowed.
// But the one we care about is this:
if (vSP() + offset < vSP())
mFailed = true;
vSP() += offset;
// ...so that this is the only other check needed:
checkStackBase();
continue;
}
// 1000iiii iiiiiiii (i not all 0): Pop under masks {r15-r12}, {r11-r4}
if ((insn & M_POPMASK) == I_POPMASK) {
popRange(4, 15, ((insn & 0x0f) << 8) | next());
continue;
}
// 1011001 0000iiii (i not all 0): Pop under mask {r3-r0}
if (insn == I_POPLO) {
popRange(0, 3, next() & 0x0f);
continue;
}
// 10110011 sssscccc: Pop VFP regs D[ssss]-D[ssss+cccc] (as FLDMFDX)
if (insn == I_POPFDX) {
uint8_t n = (next() & 0x0f) + 1;
vSP() += 8 * n + 4;
checkStackBase();
continue;
}
// 10111nnn: Pop VFP regs D[8]-D[8+nnn] (as FLDMFDX)
if ((insn & M_POPFDX8) == I_POPFDX8) {
uint8_t n = (insn & 0x07) + 1;
vSP() += 8 * n + 4;
checkStackBase();
continue;
}
// unhandled instruction
#ifdef DEBUG_EHABI_UNWIND
LOGF("Unhandled EHABI instruction 0x%02x", insn);
#endif
mFailed = true;
}
return false;
}
bool operator<(const EHTable &lhs, const EHTable &rhs) {
return lhs.startPC() < rhs.endPC();
}
// Async signal unsafe.
EHAddrSpace::EHAddrSpace(const std::vector<EHTable>& aTables)
: mTables(aTables)
{
std::sort(mTables.begin(), mTables.end());
DebugOnly<uint32_t> lastEnd = 0;
for (std::vector<EHTable>::iterator i = mTables.begin();
i != mTables.end(); ++i) {
MOZ_ASSERT(i->startPC() >= lastEnd);
mStarts.push_back(i->startPC());
lastEnd = i->endPC();
}
}
const EHTable *EHAddrSpace::lookup(uint32_t aPC) const {
ptrdiff_t i = (std::upper_bound(mStarts.begin(), mStarts.end(), aPC)
- mStarts.begin()) - 1;
if (i < 0 || aPC >= mTables[i].endPC())
return 0;
return &mTables[i];
}
bool operator<(const EHEntryHandle &lhs, const EHEntryHandle &rhs) {
return lhs.value()->startPC.compute() < rhs.value()->startPC.compute();
}
const EHEntry *EHTable::lookup(uint32_t aPC) const {
MOZ_ASSERT(aPC >= mStartPC);
if (aPC >= mEndPC)
return nullptr;
std::vector<EHEntryHandle>::const_iterator begin = mEntries.begin();
std::vector<EHEntryHandle>::const_iterator end = mEntries.end();
MOZ_ASSERT(begin < end);
if (aPC < reinterpret_cast<uint32_t>(begin->value()->startPC.compute()))
return nullptr;
while (end - begin > 1) {
std::vector<EHEntryHandle>::const_iterator mid = begin + (end - begin) / 2;
if (aPC < reinterpret_cast<uint32_t>(mid->value()->startPC.compute()))
end = mid;
else
begin = mid;
}
return begin->value();
}
#if MOZ_LITTLE_ENDIAN
static const unsigned char hostEndian = ELFDATA2LSB;
#elif MOZ_BIG_ENDIAN
static const unsigned char hostEndian = ELFDATA2MSB;
#else
#error "No endian?"
#endif
// Async signal unsafe. (Note use of std::vector::reserve.)
EHTable::EHTable(const void *aELF, size_t aSize, const std::string &aName)
: mStartPC(~0), // largest uint32_t
mEndPC(0),
mName(aName)
{
const uint32_t base = reinterpret_cast<uint32_t>(aELF);
if (aSize < sizeof(Elf32_Ehdr))
return;
const Elf32_Ehdr &file = *(reinterpret_cast<Elf32_Ehdr *>(base));
if (memcmp(&file.e_ident[EI_MAG0], ELFMAG, SELFMAG) != 0 ||
file.e_ident[EI_CLASS] != ELFCLASS32 ||
file.e_ident[EI_DATA] != hostEndian ||
file.e_ident[EI_VERSION] != EV_CURRENT ||
file.e_ident[EI_OSABI] != ELFOSABI_SYSV ||
#ifdef EI_ABIVERSION
file.e_ident[EI_ABIVERSION] != 0 ||
#endif
file.e_machine != EM_ARM ||
file.e_version != EV_CURRENT)
// e_flags?
return;
MOZ_ASSERT(file.e_phoff + file.e_phnum * file.e_phentsize <= aSize);
const Elf32_Phdr *exidxHdr = 0, *zeroHdr = 0;
for (unsigned i = 0; i < file.e_phnum; ++i) {
const Elf32_Phdr &phdr =
*(reinterpret_cast<Elf32_Phdr *>(base + file.e_phoff
+ i * file.e_phentsize));
if (phdr.p_type == PT_ARM_EXIDX) {
exidxHdr = &phdr;
} else if (phdr.p_type == PT_LOAD) {
if (phdr.p_offset == 0) {
zeroHdr = &phdr;
}
if (phdr.p_flags & PF_X) {
mStartPC = std::min(mStartPC, phdr.p_vaddr);
mEndPC = std::max(mEndPC, phdr.p_vaddr + phdr.p_memsz);
}
}
}
if (!exidxHdr)
return;
if (!zeroHdr)
return;
mLoadOffset = base - zeroHdr->p_vaddr;
mStartPC += mLoadOffset;
mEndPC += mLoadOffset;
// Create a sorted index of the index to work around linker bugs.
const EHEntry *startTable =
reinterpret_cast<const EHEntry *>(mLoadOffset + exidxHdr->p_vaddr);
const EHEntry *endTable =
reinterpret_cast<const EHEntry *>(mLoadOffset + exidxHdr->p_vaddr
+ exidxHdr->p_memsz);
mEntries.reserve(endTable - startTable);
for (const EHEntry *i = startTable; i < endTable; ++i)
mEntries.push_back(i);
std::sort(mEntries.begin(), mEntries.end());
}
mozilla::Atomic<const EHAddrSpace*> EHAddrSpace::sCurrent(nullptr);
// Async signal safe; can fail if Update() hasn't returned yet.
const EHAddrSpace *EHAddrSpace::Get() {
return sCurrent;
}
// Collect unwinding information from loaded objects. Calls after the
// first have no effect. Async signal unsafe.
void EHAddrSpace::Update() {
const EHAddrSpace *space = sCurrent;
if (space)
return;
SharedLibraryInfo info = SharedLibraryInfo::GetInfoForSelf();
std::vector<EHTable> tables;
for (size_t i = 0; i < info.GetSize(); ++i) {
const SharedLibrary &lib = info.GetEntry(i);
if (lib.GetOffset() != 0)
// TODO: if it has a name, and we haven't seen a mapping of
// offset 0 for that file, try opening it and reading the
// headers instead. The only thing I've seen so far that's
// linked so as to need that treatment is the dynamic linker
// itself.
continue;
EHTable tab(reinterpret_cast<const void *>(lib.GetStart()),
lib.GetEnd() - lib.GetStart(), lib.GetName());
if (tab.isValid())
tables.push_back(tab);
}
space = new EHAddrSpace(tables);
if (!sCurrent.compareExchange(nullptr, space)) {
delete space;
space = sCurrent;
}
}
EHState::EHState(const mcontext_t &context) {
#ifdef linux
mRegs[0] = context.arm_r0;
mRegs[1] = context.arm_r1;
mRegs[2] = context.arm_r2;
mRegs[3] = context.arm_r3;
mRegs[4] = context.arm_r4;
mRegs[5] = context.arm_r5;
mRegs[6] = context.arm_r6;
mRegs[7] = context.arm_r7;
mRegs[8] = context.arm_r8;
mRegs[9] = context.arm_r9;
mRegs[10] = context.arm_r10;
mRegs[11] = context.arm_fp;
mRegs[12] = context.arm_ip;
mRegs[13] = context.arm_sp;
mRegs[14] = context.arm_lr;
mRegs[15] = context.arm_pc;
#else
# error "Unhandled OS for ARM EHABI unwinding"
#endif
}
} // namespace mozilla