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tenfourfox/tools/profiler/lul/LulMain.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/. */
#include "LulMain.h"
#include <string.h>
#include <stdlib.h>
#include <stdio.h>
#include <algorithm> // std::sort
#include <string>
#include "mozilla/Assertions.h"
#include "mozilla/ArrayUtils.h"
#include "mozilla/DebugOnly.h"
#include "mozilla/MemoryChecking.h"
#include "mozilla/Snprintf.h"
#include "LulCommonExt.h"
#include "LulElfExt.h"
#include "LulMainInt.h"
#include "platform-linux-lul.h" // for gettid()
// Set this to 1 for verbose logging
#define DEBUG_MAIN 0
namespace lul {
using std::string;
using std::vector;
using std::pair;
using mozilla::DebugOnly;
// WARNING WARNING WARNING WARNING WARNING WARNING WARNING WARNING
//
// Some functions in this file are marked RUNS IN NO-MALLOC CONTEXT.
// Any such function -- and, hence, the transitive closure of those
// reachable from it -- must not do any dynamic memory allocation.
// Doing so risks deadlock. There is exactly one root function for
// the transitive closure: Lul::Unwind.
//
// WARNING WARNING WARNING WARNING WARNING WARNING WARNING WARNING
////////////////////////////////////////////////////////////////
// RuleSet //
////////////////////////////////////////////////////////////////
static const char*
NameOf_DW_REG(int16_t aReg)
{
switch (aReg) {
case DW_REG_CFA: return "cfa";
#if defined(LUL_ARCH_x64) || defined(LUL_ARCH_x86)
case DW_REG_INTEL_XBP: return "xbp";
case DW_REG_INTEL_XSP: return "xsp";
case DW_REG_INTEL_XIP: return "xip";
#elif defined(LUL_ARCH_arm)
case DW_REG_ARM_R7: return "r7";
case DW_REG_ARM_R11: return "r11";
case DW_REG_ARM_R12: return "r12";
case DW_REG_ARM_R13: return "r13";
case DW_REG_ARM_R14: return "r14";
case DW_REG_ARM_R15: return "r15";
#else
# error "Unsupported arch"
#endif
default: return "???";
}
}
string
LExpr::ShowRule(const char* aNewReg) const
{
char buf[64];
string res = string(aNewReg) + "=";
switch (mHow) {
case UNKNOWN:
res += "Unknown";
break;
case NODEREF:
snprintf_literal(buf, "%s+%d",
NameOf_DW_REG(mReg), (int)mOffset);
res += buf;
break;
case DEREF:
snprintf_literal(buf, "*(%s+%d)",
NameOf_DW_REG(mReg), (int)mOffset);
res += buf;
break;
case PFXEXPR:
snprintf_literal(buf, "PfxExpr-at-%d", (int)mOffset);
res += buf;
break;
default:
res += "???";
break;
}
return res;
}
void
RuleSet::Print(void(*aLog)(const char*)) const
{
char buf[96];
snprintf_literal(buf, "[%llx .. %llx]: let ",
(unsigned long long int)mAddr,
(unsigned long long int)(mAddr + mLen - 1));
string res = string(buf);
res += mCfaExpr.ShowRule("cfa");
res += " in";
// For each reg we care about, print the recovery expression.
#if defined(LUL_ARCH_x64) || defined(LUL_ARCH_x86)
res += mXipExpr.ShowRule(" RA");
res += mXspExpr.ShowRule(" SP");
res += mXbpExpr.ShowRule(" BP");
#elif defined(LUL_ARCH_arm)
res += mR15expr.ShowRule(" R15");
res += mR7expr .ShowRule(" R7" );
res += mR11expr.ShowRule(" R11");
res += mR12expr.ShowRule(" R12");
res += mR13expr.ShowRule(" R13");
res += mR14expr.ShowRule(" R14");
#else
# error "Unsupported arch"
#endif
aLog(res.c_str());
}
LExpr*
RuleSet::ExprForRegno(DW_REG_NUMBER aRegno) {
switch (aRegno) {
case DW_REG_CFA: return &mCfaExpr;
# if defined(LUL_ARCH_x64) || defined(LUL_ARCH_x86)
case DW_REG_INTEL_XIP: return &mXipExpr;
case DW_REG_INTEL_XSP: return &mXspExpr;
case DW_REG_INTEL_XBP: return &mXbpExpr;
# elif defined(LUL_ARCH_arm)
case DW_REG_ARM_R15: return &mR15expr;
case DW_REG_ARM_R14: return &mR14expr;
case DW_REG_ARM_R13: return &mR13expr;
case DW_REG_ARM_R12: return &mR12expr;
case DW_REG_ARM_R11: return &mR11expr;
case DW_REG_ARM_R7: return &mR7expr;
# else
# error "Unknown arch"
# endif
default: return nullptr;
}
}
RuleSet::RuleSet()
{
mAddr = 0;
mLen = 0;
// The only other fields are of type LExpr and those are initialised
// by LExpr::LExpr().
}
////////////////////////////////////////////////////////////////
// SecMap //
////////////////////////////////////////////////////////////////
// See header file LulMainInt.h for comments about invariants.
SecMap::SecMap(void(*aLog)(const char*))
: mSummaryMinAddr(1)
, mSummaryMaxAddr(0)
, mUsable(true)
, mLog(aLog)
{}
SecMap::~SecMap() {
mRuleSets.clear();
}
// RUNS IN NO-MALLOC CONTEXT
RuleSet*
SecMap::FindRuleSet(uintptr_t ia) {
// Binary search mRuleSets to find one that brackets |ia|.
// lo and hi need to be signed, else the loop termination tests
// don't work properly. Note that this works correctly even when
// mRuleSets.size() == 0.
// Can't do this until the array has been sorted and preened.
MOZ_ASSERT(mUsable);
long int lo = 0;
long int hi = (long int)mRuleSets.size() - 1;
while (true) {
// current unsearched space is from lo to hi, inclusive.
if (lo > hi) {
// not found
return nullptr;
}
long int mid = lo + ((hi - lo) / 2);
RuleSet* mid_ruleSet = &mRuleSets[mid];
uintptr_t mid_minAddr = mid_ruleSet->mAddr;
uintptr_t mid_maxAddr = mid_minAddr + mid_ruleSet->mLen - 1;
if (ia < mid_minAddr) { hi = mid-1; continue; }
if (ia > mid_maxAddr) { lo = mid+1; continue; }
MOZ_ASSERT(mid_minAddr <= ia && ia <= mid_maxAddr);
return mid_ruleSet;
}
// NOTREACHED
}
// Add a RuleSet to the collection. The rule is copied in. Calling
// this makes the map non-searchable.
void
SecMap::AddRuleSet(const RuleSet* rs) {
mUsable = false;
mRuleSets.push_back(*rs);
}
// Add a PfxInstr to the vector of such instrs, and return the index
// in the vector. Calling this makes the map non-searchable.
uint32_t
SecMap::AddPfxInstr(PfxInstr pfxi) {
mUsable = false;
mPfxInstrs.push_back(pfxi);
return mPfxInstrs.size() - 1;
}
static bool
CmpRuleSetsByAddrLE(const RuleSet& rs1, const RuleSet& rs2) {
return rs1.mAddr < rs2.mAddr;
}
// Prepare the map for searching. Completely remove any which don't
// fall inside the specified range [start, +len).
void
SecMap::PrepareRuleSets(uintptr_t aStart, size_t aLen)
{
if (mRuleSets.empty()) {
return;
}
MOZ_ASSERT(aLen > 0);
if (aLen == 0) {
// This should never happen.
mRuleSets.clear();
return;
}
// Sort by start addresses.
std::sort(mRuleSets.begin(), mRuleSets.end(), CmpRuleSetsByAddrLE);
// Detect any entry not completely contained within [start, +len).
// Set its length to zero, so that the next pass will remove it.
for (size_t i = 0; i < mRuleSets.size(); ++i) {
RuleSet* rs = &mRuleSets[i];
if (rs->mLen > 0 &&
(rs->mAddr < aStart || rs->mAddr + rs->mLen > aStart + aLen)) {
rs->mLen = 0;
}
}
// Iteratively truncate any overlaps and remove any zero length
// entries that might result, or that may have been present
// initially. Unless the input is seriously screwy, this is
// expected to iterate only once.
while (true) {
size_t i;
size_t n = mRuleSets.size();
size_t nZeroLen = 0;
if (n == 0) {
break;
}
for (i = 1; i < n; ++i) {
RuleSet* prev = &mRuleSets[i-1];
RuleSet* here = &mRuleSets[i];
MOZ_ASSERT(prev->mAddr <= here->mAddr);
if (prev->mAddr + prev->mLen > here->mAddr) {
prev->mLen = here->mAddr - prev->mAddr;
}
if (prev->mLen == 0)
nZeroLen++;
}
if (mRuleSets[n-1].mLen == 0) {
nZeroLen++;
}
// At this point, the entries are in-order and non-overlapping.
// If none of them are zero-length, we are done.
if (nZeroLen == 0) {
break;
}
// Slide back the entries to remove the zero length ones.
size_t j = 0; // The write-point.
for (i = 0; i < n; ++i) {
if (mRuleSets[i].mLen == 0) {
continue;
}
if (j != i) mRuleSets[j] = mRuleSets[i];
++j;
}
MOZ_ASSERT(i == n);
MOZ_ASSERT(nZeroLen <= n);
MOZ_ASSERT(j == n - nZeroLen);
while (nZeroLen > 0) {
mRuleSets.pop_back();
nZeroLen--;
}
MOZ_ASSERT(mRuleSets.size() == j);
}
size_t n = mRuleSets.size();
#ifdef DEBUG
// Do a final check on the rules: their address ranges must be
// ascending, non overlapping, non zero sized.
if (n > 0) {
MOZ_ASSERT(mRuleSets[0].mLen > 0);
for (size_t i = 1; i < n; ++i) {
RuleSet* prev = &mRuleSets[i-1];
RuleSet* here = &mRuleSets[i];
MOZ_ASSERT(prev->mAddr < here->mAddr);
MOZ_ASSERT(here->mLen > 0);
MOZ_ASSERT(prev->mAddr + prev->mLen <= here->mAddr);
}
}
#endif
// Set the summary min and max address values.
if (n == 0) {
// Use the values defined in comments in the class declaration.
mSummaryMinAddr = 1;
mSummaryMaxAddr = 0;
} else {
mSummaryMinAddr = mRuleSets[0].mAddr;
mSummaryMaxAddr = mRuleSets[n-1].mAddr + mRuleSets[n-1].mLen - 1;
}
char buf[150];
snprintf_literal(buf,
"PrepareRuleSets: %d entries, smin/smax 0x%llx, 0x%llx\n",
(int)n, (unsigned long long int)mSummaryMinAddr,
(unsigned long long int)mSummaryMaxAddr);
buf[sizeof(buf)-1] = 0;
mLog(buf);
// Is now usable for binary search.
mUsable = true;
if (0) {
mLog("\nRulesets after preening\n");
for (size_t i = 0; i < mRuleSets.size(); ++i) {
mRuleSets[i].Print(mLog);
mLog("\n");
}
mLog("\n");
}
}
bool SecMap::IsEmpty() {
return mRuleSets.empty();
}
////////////////////////////////////////////////////////////////
// SegArray //
////////////////////////////////////////////////////////////////
// A SegArray holds a set of address ranges that together exactly
// cover an address range, with no overlaps or holes. Each range has
// an associated value, which in this case has been specialised to be
// a simple boolean. The representation is kept to minimal canonical
// form in which adjacent ranges with the same associated value are
// merged together. Each range is represented by a |struct Seg|.
//
// SegArrays are used to keep track of which parts of the address
// space are known to contain instructions.
class SegArray {
public:
void add(uintptr_t lo, uintptr_t hi, bool val) {
if (lo > hi) {
return;
}
split_at(lo);
if (hi < UINTPTR_MAX) {
split_at(hi+1);
}
std::vector<Seg>::size_type iLo, iHi, i;
iLo = find(lo);
iHi = find(hi);
for (i = iLo; i <= iHi; ++i) {
mSegs[i].val = val;
}
preen();
}
// RUNS IN NO-MALLOC CONTEXT
bool getBoundingCodeSegment(/*OUT*/uintptr_t* rx_min,
/*OUT*/uintptr_t* rx_max, uintptr_t addr) {
std::vector<Seg>::size_type i = find(addr);
if (!mSegs[i].val) {
return false;
}
*rx_min = mSegs[i].lo;
*rx_max = mSegs[i].hi;
return true;
}
SegArray() {
Seg s(0, UINTPTR_MAX, false);
mSegs.push_back(s);
}
private:
struct Seg {
Seg(uintptr_t lo, uintptr_t hi, bool val) : lo(lo), hi(hi), val(val) {}
uintptr_t lo;
uintptr_t hi;
bool val;
};
void preen() {
for (std::vector<Seg>::iterator iter = mSegs.begin();
iter < mSegs.end()-1;
++iter) {
if (iter[0].val != iter[1].val) {
continue;
}
iter[0].hi = iter[1].hi;
mSegs.erase(iter+1);
// Back up one, so as not to miss an opportunity to merge
// with the entry after this one.
--iter;
}
}
// RUNS IN NO-MALLOC CONTEXT
std::vector<Seg>::size_type find(uintptr_t a) {
long int lo = 0;
long int hi = (long int)mSegs.size();
while (true) {
// The unsearched space is lo .. hi inclusive.
if (lo > hi) {
// Not found. This can't happen.
return (std::vector<Seg>::size_type)(-1);
}
long int mid = lo + ((hi - lo) / 2);
uintptr_t mid_lo = mSegs[mid].lo;
uintptr_t mid_hi = mSegs[mid].hi;
if (a < mid_lo) { hi = mid-1; continue; }
if (a > mid_hi) { lo = mid+1; continue; }
return (std::vector<Seg>::size_type)mid;
}
}
void split_at(uintptr_t a) {
std::vector<Seg>::size_type i = find(a);
if (mSegs[i].lo == a) {
return;
}
mSegs.insert( mSegs.begin()+i+1, mSegs[i] );
mSegs[i].hi = a-1;
mSegs[i+1].lo = a;
}
void show() {
printf("<< %d entries:\n", (int)mSegs.size());
for (std::vector<Seg>::iterator iter = mSegs.begin();
iter < mSegs.end();
++iter) {
printf(" %016llx %016llx %s\n",
(unsigned long long int)(*iter).lo,
(unsigned long long int)(*iter).hi,
(*iter).val ? "true" : "false");
}
printf(">>\n");
}
std::vector<Seg> mSegs;
};
////////////////////////////////////////////////////////////////
// PriMap //
////////////////////////////////////////////////////////////////
class PriMap {
public:
explicit PriMap(void (*aLog)(const char*))
: mLog(aLog)
{}
~PriMap() {
for (std::vector<SecMap*>::iterator iter = mSecMaps.begin();
iter != mSecMaps.end();
++iter) {
delete *iter;
}
mSecMaps.clear();
}
// RUNS IN NO-MALLOC CONTEXT
pair<const RuleSet*, const vector<PfxInstr>*>
Lookup(uintptr_t ia)
{
SecMap* sm = FindSecMap(ia);
return pair<const RuleSet*, const vector<PfxInstr>*>
(sm ? sm->FindRuleSet(ia) : nullptr,
sm ? sm->GetPfxInstrs() : nullptr);
}
// Add a secondary map. No overlaps allowed w.r.t. existing
// secondary maps.
void AddSecMap(SecMap* aSecMap) {
// We can't add an empty SecMap to the PriMap. But that's OK
// since we'd never be able to find anything in it anyway.
if (aSecMap->IsEmpty()) {
return;
}
// Iterate through the SecMaps and find the right place for this
// one. At the same time, ensure that the in-order
// non-overlapping invariant is preserved (and, generally, holds).
// FIXME: this gives a cost that is O(N^2) in the total number of
// shared objects in the system. ToDo: better.
MOZ_ASSERT(aSecMap->mSummaryMinAddr <= aSecMap->mSummaryMaxAddr);
size_t num_secMaps = mSecMaps.size();
uintptr_t i;
for (i = 0; i < num_secMaps; ++i) {
SecMap* sm_i = mSecMaps[i];
MOZ_ASSERT(sm_i->mSummaryMinAddr <= sm_i->mSummaryMaxAddr);
if (aSecMap->mSummaryMinAddr < sm_i->mSummaryMaxAddr) {
// |aSecMap| needs to be inserted immediately before mSecMaps[i].
break;
}
}
MOZ_ASSERT(i <= num_secMaps);
if (i == num_secMaps) {
// It goes at the end.
mSecMaps.push_back(aSecMap);
} else {
std::vector<SecMap*>::iterator iter = mSecMaps.begin() + i;
mSecMaps.insert(iter, aSecMap);
}
char buf[100];
snprintf_literal(buf, "AddSecMap: now have %d SecMaps\n",
(int)mSecMaps.size());
buf[sizeof(buf)-1] = 0;
mLog(buf);
}
// Remove and delete any SecMaps in the mapping, that intersect
// with the specified address range.
void RemoveSecMapsInRange(uintptr_t avma_min, uintptr_t avma_max) {
MOZ_ASSERT(avma_min <= avma_max);
size_t num_secMaps = mSecMaps.size();
if (num_secMaps > 0) {
intptr_t i;
// Iterate from end to start over the vector, so as to ensure
// that the special case where |avma_min| and |avma_max| denote
// the entire address space, can be completed in time proportional
// to the number of elements in the map.
for (i = (intptr_t)num_secMaps-1; i >= 0; i--) {
SecMap* sm_i = mSecMaps[i];
if (sm_i->mSummaryMaxAddr < avma_min ||
avma_max < sm_i->mSummaryMinAddr) {
// There's no overlap. Move on.
continue;
}
// We need to remove mSecMaps[i] and slide all those above it
// downwards to cover the hole.
mSecMaps.erase(mSecMaps.begin() + i);
delete sm_i;
}
}
}
// Return the number of currently contained SecMaps.
size_t CountSecMaps() {
return mSecMaps.size();
}
// Assess heuristically whether the given address is an instruction
// immediately following a call instruction.
// RUNS IN NO-MALLOC CONTEXT
bool MaybeIsReturnPoint(TaggedUWord aInstrAddr, SegArray* aSegArray) {
if (!aInstrAddr.Valid()) {
return false;
}
uintptr_t ia = aInstrAddr.Value();
// Assume that nobody would be crazy enough to put code in the
// first or last page.
if (ia < 4096 || ((uintptr_t)(-ia)) < 4096) {
return false;
}
// See if it falls inside a known r-x mapped area. Poking around
// outside such places risks segfaulting.
uintptr_t insns_min, insns_max;
bool b = aSegArray->getBoundingCodeSegment(&insns_min, &insns_max, ia);
if (!b) {
// no code (that we know about) at this address
return false;
}
// |ia| falls within an r-x range. So we can
// safely poke around in [insns_min, insns_max].
#if defined(LUL_ARCH_x64) || defined(LUL_ARCH_x86)
// Is the previous instruction recognisably a CALL? This is
// common for the 32- and 64-bit versions, except for the
// simm32(%rip) case, which is 64-bit only.
//
// For all other cases, the 64 bit versions are either identical
// to the 32 bit versions, or have an optional extra leading REX.W
// byte (0x41). Since the extra 0x41 is optional we have to
// ignore it, with the convenient result that the same matching
// logic works for both 32- and 64-bit cases.
uint8_t* p = (uint8_t*)ia;
# if defined(LUL_ARCH_x64)
// CALL simm32(%rip) == FF15 simm32
if (ia - 6 >= insns_min && p[-6] == 0xFF && p[-5] == 0x15) {
return true;
}
# endif
// CALL rel32 == E8 rel32 (both 32- and 64-bit)
if (ia - 5 >= insns_min && p[-5] == 0xE8) {
return true;
}
// CALL *%eax .. CALL *%edi == FFD0 .. FFD7 (32-bit)
// CALL *%rax .. CALL *%rdi == FFD0 .. FFD7 (64-bit)
// CALL *%r8 .. CALL *%r15 == 41FFD0 .. 41FFD7 (64-bit)
if (ia - 2 >= insns_min &&
p[-2] == 0xFF && p[-1] >= 0xD0 && p[-1] <= 0xD7) {
return true;
}
// Almost all of the remaining cases that occur in practice are
// of the form CALL *simm8(reg) or CALL *simm32(reg).
//
// 64 bit cases:
//
// call *simm8(%rax) FF50 simm8
// call *simm8(%rcx) FF51 simm8
// call *simm8(%rdx) FF52 simm8
// call *simm8(%rbx) FF53 simm8
// call *simm8(%rsp) FF5424 simm8
// call *simm8(%rbp) FF55 simm8
// call *simm8(%rsi) FF56 simm8
// call *simm8(%rdi) FF57 simm8
//
// call *simm8(%r8) 41FF50 simm8
// call *simm8(%r9) 41FF51 simm8
// call *simm8(%r10) 41FF52 simm8
// call *simm8(%r11) 41FF53 simm8
// call *simm8(%r12) 41FF5424 simm8
// call *simm8(%r13) 41FF55 simm8
// call *simm8(%r14) 41FF56 simm8
// call *simm8(%r15) 41FF57 simm8
//
// call *simm32(%rax) FF90 simm32
// call *simm32(%rcx) FF91 simm32
// call *simm32(%rdx) FF92 simm32
// call *simm32(%rbx) FF93 simm32
// call *simm32(%rsp) FF9424 simm32
// call *simm32(%rbp) FF95 simm32
// call *simm32(%rsi) FF96 simm32
// call *simm32(%rdi) FF97 simm32
//
// call *simm32(%r8) 41FF90 simm32
// call *simm32(%r9) 41FF91 simm32
// call *simm32(%r10) 41FF92 simm32
// call *simm32(%r11) 41FF93 simm32
// call *simm32(%r12) 41FF9424 simm32
// call *simm32(%r13) 41FF95 simm32
// call *simm32(%r14) 41FF96 simm32
// call *simm32(%r15) 41FF97 simm32
//
// 32 bit cases:
//
// call *simm8(%eax) FF50 simm8
// call *simm8(%ecx) FF51 simm8
// call *simm8(%edx) FF52 simm8
// call *simm8(%ebx) FF53 simm8
// call *simm8(%esp) FF5424 simm8
// call *simm8(%ebp) FF55 simm8
// call *simm8(%esi) FF56 simm8
// call *simm8(%edi) FF57 simm8
//
// call *simm32(%eax) FF90 simm32
// call *simm32(%ecx) FF91 simm32
// call *simm32(%edx) FF92 simm32
// call *simm32(%ebx) FF93 simm32
// call *simm32(%esp) FF9424 simm32
// call *simm32(%ebp) FF95 simm32
// call *simm32(%esi) FF96 simm32
// call *simm32(%edi) FF97 simm32
if (ia - 3 >= insns_min &&
p[-3] == 0xFF &&
(p[-2] >= 0x50 && p[-2] <= 0x57 && p[-2] != 0x54)) {
// imm8 case, not including %esp/%rsp
return true;
}
if (ia - 4 >= insns_min &&
p[-4] == 0xFF && p[-3] == 0x54 && p[-2] == 0x24) {
// imm8 case for %esp/%rsp
return true;
}
if (ia - 6 >= insns_min &&
p[-6] == 0xFF &&
(p[-5] >= 0x90 && p[-5] <= 0x97 && p[-5] != 0x94)) {
// imm32 case, not including %esp/%rsp
return true;
}
if (ia - 7 >= insns_min &&
p[-7] == 0xFF && p[-6] == 0x94 && p[-5] == 0x24) {
// imm32 case for %esp/%rsp
return true;
}
#elif defined(LUL_ARCH_arm)
if (ia & 1) {
uint16_t w0 = 0, w1 = 0;
// The return address has its lowest bit set, indicating a return
// to Thumb code.
ia &= ~(uintptr_t)1;
if (ia - 2 >= insns_min && ia - 1 <= insns_max) {
w1 = *(uint16_t*)(ia - 2);
}
if (ia - 4 >= insns_min && ia - 1 <= insns_max) {
w0 = *(uint16_t*)(ia - 4);
}
// Is it a 32-bit Thumb call insn?
// BL simm26 (Encoding T1)
if ((w0 & 0xF800) == 0xF000 && (w1 & 0xC000) == 0xC000) {
return true;
}
// BLX simm26 (Encoding T2)
if ((w0 & 0xF800) == 0xF000 && (w1 & 0xC000) == 0xC000) {
return true;
}
// Other possible cases:
// (BLX Rm, Encoding T1).
// BLX Rm (encoding T1, 16 bit, inspect w1 and ignore w0.)
// 0100 0111 1 Rm 000
} else {
// Returning to ARM code.
uint32_t a0 = 0;
if ((ia & 3) == 0 && ia - 4 >= insns_min && ia - 1 <= insns_max) {
a0 = *(uint32_t*)(ia - 4);
}
// Leading E forces unconditional only -- fix. It could be
// anything except F, which is the deprecated NV code.
// BL simm26 (Encoding A1)
if ((a0 & 0xFF000000) == 0xEB000000) {
return true;
}
// Other possible cases:
// BLX simm26 (Encoding A2)
//if ((a0 & 0xFE000000) == 0xFA000000)
// return true;
// BLX (register) (A1): BLX <c> <Rm>
// cond 0001 0010 1111 1111 1111 0011 Rm
// again, cond can be anything except NV (0xF)
}
#else
# error "Unsupported arch"
#endif
// Not an insn we recognise.
return false;
}
private:
// RUNS IN NO-MALLOC CONTEXT
SecMap* FindSecMap(uintptr_t ia) {
// Binary search mSecMaps to find one that brackets |ia|.
// lo and hi need to be signed, else the loop termination tests
// don't work properly.
long int lo = 0;
long int hi = (long int)mSecMaps.size() - 1;
while (true) {
// current unsearched space is from lo to hi, inclusive.
if (lo > hi) {
// not found
return nullptr;
}
long int mid = lo + ((hi - lo) / 2);
SecMap* mid_secMap = mSecMaps[mid];
uintptr_t mid_minAddr = mid_secMap->mSummaryMinAddr;
uintptr_t mid_maxAddr = mid_secMap->mSummaryMaxAddr;
if (ia < mid_minAddr) { hi = mid-1; continue; }
if (ia > mid_maxAddr) { lo = mid+1; continue; }
MOZ_ASSERT(mid_minAddr <= ia && ia <= mid_maxAddr);
return mid_secMap;
}
// NOTREACHED
}
private:
// sorted array of per-object ranges, non overlapping, non empty
std::vector<SecMap*> mSecMaps;
// a logging sink, for debugging.
void (*mLog)(const char*);
};
////////////////////////////////////////////////////////////////
// LUL //
////////////////////////////////////////////////////////////////
#define LUL_LOG(_str) \
do { \
char buf[200]; \
snprintf_literal(buf, \
"LUL: pid %d tid %d lul-obj %p: %s", \
getpid(), gettid(), this, (_str)); \
buf[sizeof(buf)-1] = 0; \
mLog(buf); \
} while (0)
LUL::LUL(void (*aLog)(const char*))
: mLog(aLog)
, mAdminMode(true)
, mAdminThreadId(gettid())
, mPriMap(new PriMap(aLog))
, mSegArray(new SegArray())
, mUSU(new UniqueStringUniverse())
{
LUL_LOG("LUL::LUL: Created object");
}
LUL::~LUL()
{
LUL_LOG("LUL::~LUL: Destroyed object");
delete mPriMap;
delete mSegArray;
mLog = nullptr;
delete mUSU;
}
void
LUL::MaybeShowStats()
{
// This is racey in the sense that it can't guarantee that
// n_new == n_new_Context + n_new_CFI + n_new_Scanned
// if it should happen that mStats is updated by some other thread
// in between computation of n_new and n_new_{Context,CFI,Scanned}.
// But it's just stats printing, so we don't really care.
uint32_t n_new = mStats - mStatsPrevious;
if (n_new >= 5000) {
uint32_t n_new_Context = mStats.mContext - mStatsPrevious.mContext;
uint32_t n_new_CFI = mStats.mCFI - mStatsPrevious.mCFI;
uint32_t n_new_Scanned = mStats.mScanned - mStatsPrevious.mScanned;
mStatsPrevious = mStats;
char buf[200];
snprintf_literal(buf,
"LUL frame stats: TOTAL %5u"
" CTX %4u CFI %4u SCAN %4u",
n_new, n_new_Context, n_new_CFI, n_new_Scanned);
buf[sizeof(buf)-1] = 0;
mLog(buf);
}
}
void
LUL::EnableUnwinding()
{
LUL_LOG("LUL::EnableUnwinding");
// Don't assert for Admin mode here. That is, tolerate a call here
// if we are already in Unwinding mode.
MOZ_ASSERT(gettid() == mAdminThreadId);
mAdminMode = false;
}
void
LUL::NotifyAfterMap(uintptr_t aRXavma, size_t aSize,
const char* aFileName, const void* aMappedImage)
{
MOZ_ASSERT(mAdminMode);
MOZ_ASSERT(gettid() == mAdminThreadId);
mLog(":\n");
char buf[200];
snprintf_literal(buf, "NotifyMap %llx %llu %s\n",
(unsigned long long int)aRXavma, (unsigned long long int)aSize,
aFileName);
buf[sizeof(buf)-1] = 0;
mLog(buf);
// Ignore obviously-stupid notifications.
if (aSize > 0) {
// Here's a new mapping, for this object.
SecMap* smap = new SecMap(mLog);
// Read CFI or EXIDX unwind data into |smap|.
if (!aMappedImage) {
(void)lul::ReadSymbolData(
string(aFileName), std::vector<string>(), smap,
(void*)aRXavma, aSize, mUSU, mLog);
} else {
(void)lul::ReadSymbolDataInternal(
(const uint8_t*)aMappedImage,
string(aFileName), std::vector<string>(), smap,
(void*)aRXavma, aSize, mUSU, mLog);
}
mLog("NotifyMap .. preparing entries\n");
smap->PrepareRuleSets(aRXavma, aSize);
snprintf_literal(buf,
"NotifyMap got %lld entries\n", (long long int)smap->Size());
buf[sizeof(buf)-1] = 0;
mLog(buf);
// Add it to the primary map (the top level set of mapped objects).
mPriMap->AddSecMap(smap);
// Tell the segment array about the mapping, so that the stack
// scan and __kernel_syscall mechanisms know where valid code is.
mSegArray->add(aRXavma, aRXavma + aSize - 1, true);
}
}
void
LUL::NotifyExecutableArea(uintptr_t aRXavma, size_t aSize)
{
MOZ_ASSERT(mAdminMode);
MOZ_ASSERT(gettid() == mAdminThreadId);
mLog(":\n");
char buf[200];
snprintf_literal(buf, "NotifyExecutableArea %llx %llu\n",
(unsigned long long int)aRXavma, (unsigned long long int)aSize);
buf[sizeof(buf)-1] = 0;
mLog(buf);
// Ignore obviously-stupid notifications.
if (aSize > 0) {
// Tell the segment array about the mapping, so that the stack
// scan and __kernel_syscall mechanisms know where valid code is.
mSegArray->add(aRXavma, aRXavma + aSize - 1, true);
}
}
void
LUL::NotifyBeforeUnmap(uintptr_t aRXavmaMin, uintptr_t aRXavmaMax)
{
MOZ_ASSERT(mAdminMode);
MOZ_ASSERT(gettid() == mAdminThreadId);
mLog(":\n");
char buf[100];
snprintf_literal(buf, "NotifyUnmap %016llx-%016llx\n",
(unsigned long long int)aRXavmaMin,
(unsigned long long int)aRXavmaMax);
buf[sizeof(buf)-1] = 0;
mLog(buf);
MOZ_ASSERT(aRXavmaMin <= aRXavmaMax);
// Remove from the primary map, any secondary maps that intersect
// with the address range. Also delete the secondary maps.
mPriMap->RemoveSecMapsInRange(aRXavmaMin, aRXavmaMax);
// Tell the segment array that the address range no longer
// contains valid code.
mSegArray->add(aRXavmaMin, aRXavmaMax, false);
snprintf_literal(buf, "NotifyUnmap: now have %d SecMaps\n",
(int)mPriMap->CountSecMaps());
buf[sizeof(buf)-1] = 0;
mLog(buf);
}
size_t
LUL::CountMappings()
{
MOZ_ASSERT(mAdminMode);
MOZ_ASSERT(gettid() == mAdminThreadId);
return mPriMap->CountSecMaps();
}
// RUNS IN NO-MALLOC CONTEXT
static
TaggedUWord DerefTUW(TaggedUWord aAddr, const StackImage* aStackImg)
{
if (!aAddr.Valid()) {
return TaggedUWord();
}
if (aAddr.Value() < aStackImg->mStartAvma) {
return TaggedUWord();
}
if (aAddr.Value() + sizeof(uintptr_t) > aStackImg->mStartAvma
+ aStackImg->mLen) {
return TaggedUWord();
}
return TaggedUWord(*(uintptr_t*)(aStackImg->mContents + aAddr.Value()
- aStackImg->mStartAvma));
}
// RUNS IN NO-MALLOC CONTEXT
static
TaggedUWord EvaluateReg(int16_t aReg, const UnwindRegs* aOldRegs,
TaggedUWord aCFA)
{
switch (aReg) {
case DW_REG_CFA: return aCFA;
#if defined(LUL_ARCH_x64) || defined(LUL_ARCH_x86)
case DW_REG_INTEL_XBP: return aOldRegs->xbp;
case DW_REG_INTEL_XSP: return aOldRegs->xsp;
case DW_REG_INTEL_XIP: return aOldRegs->xip;
#elif defined(LUL_ARCH_arm)
case DW_REG_ARM_R7: return aOldRegs->r7;
case DW_REG_ARM_R11: return aOldRegs->r11;
case DW_REG_ARM_R12: return aOldRegs->r12;
case DW_REG_ARM_R13: return aOldRegs->r13;
case DW_REG_ARM_R14: return aOldRegs->r14;
case DW_REG_ARM_R15: return aOldRegs->r15;
#else
# error "Unsupported arch"
#endif
default: MOZ_ASSERT(0); return TaggedUWord();
}
}
// RUNS IN NO-MALLOC CONTEXT
// See prototype for comment.
TaggedUWord EvaluatePfxExpr(int32_t start,
const UnwindRegs* aOldRegs,
TaggedUWord aCFA, const StackImage* aStackImg,
const vector<PfxInstr>& aPfxInstrs)
{
// A small evaluation stack, and a stack pointer, which points to
// the highest numbered in-use element.
const int N_STACK = 10;
TaggedUWord stack[N_STACK];
int stackPointer = -1;
for (int i = 0; i < N_STACK; i++)
stack[i] = TaggedUWord();
# define PUSH(_tuw) \
do { \
if (stackPointer >= N_STACK-1) goto fail; /* overflow */ \
stack[++stackPointer] = (_tuw); \
} while (0)
# define POP(_lval) \
do { \
if (stackPointer < 0) goto fail; /* underflow */ \
_lval = stack[stackPointer--]; \
} while (0)
// Cursor in the instruction sequence.
size_t curr = start + 1;
// Check the start point is sane.
size_t nInstrs = aPfxInstrs.size();
if (start < 0 || (size_t)start >= nInstrs)
goto fail;
{
// The instruction sequence must start with PX_Start. If not,
// something is seriously wrong.
PfxInstr first = aPfxInstrs[start];
if (first.mOpcode != PX_Start)
goto fail;
// Push the CFA on the stack to start with (or not), as required by
// the original DW_OP_*expression* CFI.
if (first.mOperand != 0)
PUSH(aCFA);
}
while (true) {
if (curr >= nInstrs)
goto fail; // ran off the end of the sequence
PfxInstr pfxi = aPfxInstrs[curr++];
if (pfxi.mOpcode == PX_End)
break; // we're done
switch (pfxi.mOpcode) {
case PX_Start:
// This should appear only at the start of the sequence.
goto fail;
case PX_End:
// We just took care of that, so we shouldn't see it again.
MOZ_ASSERT(0);
goto fail;
case PX_SImm32:
PUSH(TaggedUWord((intptr_t)pfxi.mOperand));
break;
case PX_DwReg: {
DW_REG_NUMBER reg = (DW_REG_NUMBER)pfxi.mOperand;
MOZ_ASSERT(reg != DW_REG_CFA);
PUSH(EvaluateReg(reg, aOldRegs, aCFA));
break;
}
case PX_Deref: {
TaggedUWord addr;
POP(addr);
PUSH(DerefTUW(addr, aStackImg));
break;
}
case PX_Add: {
TaggedUWord x, y;
POP(x); POP(y); PUSH(y + x);
break;
}
case PX_Sub: {
TaggedUWord x, y;
POP(x); POP(y); PUSH(y - x);
break;
}
case PX_And: {
TaggedUWord x, y;
POP(x); POP(y); PUSH(y & x);
break;
}
case PX_Or: {
TaggedUWord x, y;
POP(x); POP(y); PUSH(y | x);
break;
}
case PX_CmpGES: {
TaggedUWord x, y;
POP(x); POP(y); PUSH(y.CmpGEs(x));
break;
}
case PX_Shl: {
TaggedUWord x, y;
POP(x); POP(y); PUSH(y << x);
break;
}
default:
MOZ_ASSERT(0);
goto fail;
}
} // while (true)
// Evaluation finished. The top value on the stack is the result.
if (stackPointer >= 0) {
return stack[stackPointer];
}
// Else fall through
fail:
return TaggedUWord();
# undef PUSH
# undef POP
}
// RUNS IN NO-MALLOC CONTEXT
TaggedUWord LExpr::EvaluateExpr(const UnwindRegs* aOldRegs,
TaggedUWord aCFA, const StackImage* aStackImg,
const vector<PfxInstr>* aPfxInstrs) const
{
switch (mHow) {
case UNKNOWN:
return TaggedUWord();
case NODEREF: {
TaggedUWord tuw = EvaluateReg(mReg, aOldRegs, aCFA);
tuw = tuw + TaggedUWord((intptr_t)mOffset);
return tuw;
}
case DEREF: {
TaggedUWord tuw = EvaluateReg(mReg, aOldRegs, aCFA);
tuw = tuw + TaggedUWord((intptr_t)mOffset);
return DerefTUW(tuw, aStackImg);
}
case PFXEXPR: {
MOZ_ASSERT(aPfxInstrs);
if (!aPfxInstrs) {
return TaggedUWord();
}
return EvaluatePfxExpr(mOffset, aOldRegs, aCFA, aStackImg, *aPfxInstrs);
}
default:
MOZ_ASSERT(0);
return TaggedUWord();
}
}
// RUNS IN NO-MALLOC CONTEXT
static
void UseRuleSet(/*MOD*/UnwindRegs* aRegs,
const StackImage* aStackImg, const RuleSet* aRS,
const vector<PfxInstr>* aPfxInstrs)
{
// Take a copy of regs, since we'll need to refer to the old values
// whilst computing the new ones.
UnwindRegs old_regs = *aRegs;
// Mark all the current register values as invalid, so that the
// caller can see, on our return, which ones have been computed
// anew. If we don't even manage to compute a new PC value, then
// the caller will have to abandon the unwind.
// FIXME: Create and use instead: aRegs->SetAllInvalid();
#if defined(LUL_ARCH_x64) || defined(LUL_ARCH_x86)
aRegs->xbp = TaggedUWord();
aRegs->xsp = TaggedUWord();
aRegs->xip = TaggedUWord();
#elif defined(LUL_ARCH_arm)
aRegs->r7 = TaggedUWord();
aRegs->r11 = TaggedUWord();
aRegs->r12 = TaggedUWord();
aRegs->r13 = TaggedUWord();
aRegs->r14 = TaggedUWord();
aRegs->r15 = TaggedUWord();
#else
# error "Unsupported arch"
#endif
// This is generally useful.
const TaggedUWord inval = TaggedUWord();
// First, compute the CFA.
TaggedUWord cfa
= aRS->mCfaExpr.EvaluateExpr(&old_regs,
inval/*old cfa*/, aStackImg, aPfxInstrs);
// If we didn't manage to compute the CFA, well .. that's ungood,
// but keep going anyway. It'll be OK provided none of the register
// value rules mention the CFA. In any case, compute the new values
// for each register that we're tracking.
#if defined(LUL_ARCH_x64) || defined(LUL_ARCH_x86)
aRegs->xbp
= aRS->mXbpExpr.EvaluateExpr(&old_regs, cfa, aStackImg, aPfxInstrs);
aRegs->xsp
= aRS->mXspExpr.EvaluateExpr(&old_regs, cfa, aStackImg, aPfxInstrs);
aRegs->xip
= aRS->mXipExpr.EvaluateExpr(&old_regs, cfa, aStackImg, aPfxInstrs);
#elif defined(LUL_ARCH_arm)
aRegs->r7
= aRS->mR7expr .EvaluateExpr(&old_regs, cfa, aStackImg, aPfxInstrs);
aRegs->r11
= aRS->mR11expr.EvaluateExpr(&old_regs, cfa, aStackImg, aPfxInstrs);
aRegs->r12
= aRS->mR12expr.EvaluateExpr(&old_regs, cfa, aStackImg, aPfxInstrs);
aRegs->r13
= aRS->mR13expr.EvaluateExpr(&old_regs, cfa, aStackImg, aPfxInstrs);
aRegs->r14
= aRS->mR14expr.EvaluateExpr(&old_regs, cfa, aStackImg, aPfxInstrs);
aRegs->r15
= aRS->mR15expr.EvaluateExpr(&old_regs, cfa, aStackImg, aPfxInstrs);
#else
# error "Unsupported arch"
#endif
// We're done. Any regs for which we didn't manage to compute a
// new value will now be marked as invalid.
}
// RUNS IN NO-MALLOC CONTEXT
void
LUL::Unwind(/*OUT*/uintptr_t* aFramePCs,
/*OUT*/uintptr_t* aFrameSPs,
/*OUT*/size_t* aFramesUsed,
/*OUT*/size_t* aScannedFramesAcquired,
size_t aFramesAvail,
size_t aScannedFramesAllowed,
UnwindRegs* aStartRegs, StackImage* aStackImg)
{
MOZ_ASSERT(!mAdminMode);
/////////////////////////////////////////////////////////
// BEGIN UNWIND
*aFramesUsed = 0;
UnwindRegs regs = *aStartRegs;
TaggedUWord last_valid_sp = TaggedUWord();
// Stack-scan control
unsigned int n_scanned_frames = 0; // # s-s frames recovered so far
static const int NUM_SCANNED_WORDS = 50; // max allowed scan length
while (true) {
if (DEBUG_MAIN) {
char buf[300];
mLog("\n");
#if defined(LUL_ARCH_x64) || defined(LUL_ARCH_x86)
snprintf_literal(buf,
"LoopTop: rip %d/%llx rsp %d/%llx rbp %d/%llx\n",
(int)regs.xip.Valid(), (unsigned long long int)regs.xip.Value(),
(int)regs.xsp.Valid(), (unsigned long long int)regs.xsp.Value(),
(int)regs.xbp.Valid(), (unsigned long long int)regs.xbp.Value());
buf[sizeof(buf)-1] = 0;
mLog(buf);
#elif defined(LUL_ARCH_arm)
snprintf_literal(buf,
"LoopTop: r15 %d/%llx r7 %d/%llx r11 %d/%llx"
" r12 %d/%llx r13 %d/%llx r14 %d/%llx\n",
(int)regs.r15.Valid(), (unsigned long long int)regs.r15.Value(),
(int)regs.r7.Valid(), (unsigned long long int)regs.r7.Value(),
(int)regs.r11.Valid(), (unsigned long long int)regs.r11.Value(),
(int)regs.r12.Valid(), (unsigned long long int)regs.r12.Value(),
(int)regs.r13.Valid(), (unsigned long long int)regs.r13.Value(),
(int)regs.r14.Valid(), (unsigned long long int)regs.r14.Value());
buf[sizeof(buf)-1] = 0;
mLog(buf);
#else
# error "Unsupported arch"
#endif
}
#if defined(LUL_ARCH_x64) || defined(LUL_ARCH_x86)
TaggedUWord ia = regs.xip;
TaggedUWord sp = regs.xsp;
#elif defined(LUL_ARCH_arm)
TaggedUWord ia = (*aFramesUsed == 0 ? regs.r15 : regs.r14);
TaggedUWord sp = regs.r13;
#else
# error "Unsupported arch"
#endif
if (*aFramesUsed >= aFramesAvail) {
break;
}
// If we don't have a valid value for the PC, give up.
if (!ia.Valid()) {
break;
}
// If this is the innermost frame, record the SP value, which
// presumably is valid. If this isn't the innermost frame, and we
// have a valid SP value, check that its SP value isn't less that
// the one we've seen so far, so as to catch potential SP value
// cycles.
if (*aFramesUsed == 0) {
last_valid_sp = sp;
} else {
MOZ_ASSERT(last_valid_sp.Valid());
if (sp.Valid()) {
if (sp.Value() < last_valid_sp.Value()) {
// Hmm, SP going in the wrong direction. Let's stop.
break;
}
// Remember where we got to.
last_valid_sp = sp;
}
}
// For the innermost frame, the IA value is what we need. For all
// other frames, it's actually the return address, so back up one
// byte so as to get it into the calling instruction.
aFramePCs[*aFramesUsed] = ia.Value() - (*aFramesUsed == 0 ? 0 : 1);
aFrameSPs[*aFramesUsed] = sp.Valid() ? sp.Value() : 0;
(*aFramesUsed)++;
// Find the RuleSet for the current IA, if any. This will also
// query the backing (secondary) maps if it isn't found in the
// thread-local cache.
// If this isn't the innermost frame, back up into the calling insn.
if (*aFramesUsed > 1) {
ia = ia + TaggedUWord((uintptr_t)(-1));
}
pair<const RuleSet*, const vector<PfxInstr>*> ruleset_and_pfxinstrs
= mPriMap->Lookup(ia.Value());
const RuleSet* ruleset = ruleset_and_pfxinstrs.first;
const vector<PfxInstr>* pfxinstrs = ruleset_and_pfxinstrs.second;
if (DEBUG_MAIN) {
char buf[100];
snprintf_literal(buf, "ruleset for 0x%llx = %p\n",
(unsigned long long int)ia.Value(), ruleset);
buf[sizeof(buf)-1] = 0;
mLog(buf);
}
/////////////////////////////////////////////
////
// On 32 bit x86-linux, syscalls are often done via the VDSO
// function __kernel_vsyscall, which doesn't have a corresponding
// object that we can read debuginfo from. That effectively kills
// off all stack traces for threads blocked in syscalls. Hence
// special-case by looking at the code surrounding the program
// counter.
//
// 0xf7757420 <__kernel_vsyscall+0>: push %ecx
// 0xf7757421 <__kernel_vsyscall+1>: push %edx
// 0xf7757422 <__kernel_vsyscall+2>: push %ebp
// 0xf7757423 <__kernel_vsyscall+3>: mov %esp,%ebp
// 0xf7757425 <__kernel_vsyscall+5>: sysenter
// 0xf7757427 <__kernel_vsyscall+7>: nop
// 0xf7757428 <__kernel_vsyscall+8>: nop
// 0xf7757429 <__kernel_vsyscall+9>: nop
// 0xf775742a <__kernel_vsyscall+10>: nop
// 0xf775742b <__kernel_vsyscall+11>: nop
// 0xf775742c <__kernel_vsyscall+12>: nop
// 0xf775742d <__kernel_vsyscall+13>: nop
// 0xf775742e <__kernel_vsyscall+14>: int $0x80
// 0xf7757430 <__kernel_vsyscall+16>: pop %ebp
// 0xf7757431 <__kernel_vsyscall+17>: pop %edx
// 0xf7757432 <__kernel_vsyscall+18>: pop %ecx
// 0xf7757433 <__kernel_vsyscall+19>: ret
//
// In cases where the sampled thread is blocked in a syscall, its
// program counter will point at "pop %ebp". Hence we look for
// the sequence "int $0x80; pop %ebp; pop %edx; pop %ecx; ret", and
// the corresponding register-recovery actions are:
// new_ebp = *(old_esp + 0)
// new eip = *(old_esp + 12)
// new_esp = old_esp + 16
//
// It may also be the case that the program counter points two
// nops before the "int $0x80", viz, is __kernel_vsyscall+12, in
// the case where the syscall has been restarted but the thread
// hasn't been rescheduled. The code below doesn't handle that;
// it could easily be made to.
//
#if defined(LUL_PLAT_x86_android) || defined(LUL_PLAT_x86_linux)
if (!ruleset && *aFramesUsed == 1 && ia.Valid() && sp.Valid()) {
uintptr_t insns_min, insns_max;
uintptr_t eip = ia.Value();
bool b = mSegArray->getBoundingCodeSegment(&insns_min, &insns_max, eip);
if (b && eip - 2 >= insns_min && eip + 3 <= insns_max) {
uint8_t* eipC = (uint8_t*)eip;
if (eipC[-2] == 0xCD && eipC[-1] == 0x80 && eipC[0] == 0x5D &&
eipC[1] == 0x5A && eipC[2] == 0x59 && eipC[3] == 0xC3) {
TaggedUWord sp_plus_0 = sp;
TaggedUWord sp_plus_12 = sp;
TaggedUWord sp_plus_16 = sp;
sp_plus_12 = sp_plus_12 + TaggedUWord(12);
sp_plus_16 = sp_plus_16 + TaggedUWord(16);
TaggedUWord new_ebp = DerefTUW(sp_plus_0, aStackImg);
TaggedUWord new_eip = DerefTUW(sp_plus_12, aStackImg);
TaggedUWord new_esp = sp_plus_16;
if (new_ebp.Valid() && new_eip.Valid() && new_esp.Valid()) {
regs.xbp = new_ebp;
regs.xip = new_eip;
regs.xsp = new_esp;
continue;
}
}
}
}
#endif
////
/////////////////////////////////////////////
// So, do we have a ruleset for this address? If so, use it now.
if (ruleset) {
if (DEBUG_MAIN) {
ruleset->Print(mLog); mLog("\n");
}
// Use the RuleSet to compute the registers for the previous
// frame. |regs| is modified in-place.
UseRuleSet(&regs, aStackImg, ruleset, pfxinstrs);
} else {
// There's no RuleSet for the specified address, so see if
// it's possible to get anywhere by stack-scanning.
// Use stack scanning frugally.
if (n_scanned_frames++ >= aScannedFramesAllowed) {
break;
}
// We can't scan the stack without a valid, aligned stack pointer.
if (!sp.IsAligned()) {
break;
}
bool scan_succeeded = false;
for (int i = 0; i < NUM_SCANNED_WORDS; ++i) {
TaggedUWord aWord = DerefTUW(sp, aStackImg);
// aWord is something we fished off the stack. It should be
// valid, unless we overran the stack bounds.
if (!aWord.Valid()) {
break;
}
// Now, does aWord point inside a text section and immediately
// after something that looks like a call instruction?
if (mPriMap->MaybeIsReturnPoint(aWord, mSegArray)) {
// Yes it does. Update the unwound registers heuristically,
// using the same schemes as Breakpad does.
scan_succeeded = true;
(*aScannedFramesAcquired)++;
#if defined(LUL_ARCH_x64) || defined(LUL_ARCH_x86)
// The same logic applies for the 32- and 64-bit cases.
// Register names of the form xsp etc refer to (eg) esp in
// the 32-bit case and rsp in the 64-bit case.
# if defined(LUL_ARCH_x64)
const int wordSize = 8;
# else
const int wordSize = 4;
# endif
// The return address -- at XSP -- will have been pushed by
// the CALL instruction. So the caller's XSP value
// immediately before and after that CALL instruction is the
// word above XSP.
regs.xsp = sp + TaggedUWord(wordSize);
// aWord points at the return point, so back up one byte
// to put it in the calling instruction.
regs.xip = aWord + TaggedUWord((uintptr_t)(-1));
// Computing a new value from the frame pointer is more tricky.
if (regs.xbp.Valid() &&
sp.Valid() && regs.xbp.Value() == sp.Value() - wordSize) {
// One possibility is that the callee begins with the standard
// preamble "push %xbp; mov %xsp, %xbp". In which case, the
// (1) caller's XBP value will be at the word below XSP, and
// (2) the current (callee's) XBP will point at that word:
regs.xbp = DerefTUW(regs.xbp, aStackImg);
} else if (regs.xbp.Valid() &&
sp.Valid() && regs.xbp.Value() >= sp.Value() + wordSize) {
// If that didn't work out, maybe the callee didn't change
// XBP, so it still holds the caller's value. For that to
// be plausible, XBP will need to have a value at least
// higher than XSP since that holds the purported return
// address. In which case do nothing, since XBP already
// holds the "right" value.
} else {
// Mark XBP as invalid, so that subsequent unwind iterations
// don't assume it holds valid data.
regs.xbp = TaggedUWord();
}
// Move on to the next word up the stack
sp = sp + TaggedUWord(wordSize);
#elif defined(LUL_ARCH_arm)
// Set all registers to be undefined, except for SP(R13) and
// PC(R15).
// aWord points either at the return point, if returning to
// ARM code, or one insn past the return point if returning
// to Thumb code. In both cases, aWord-2 is guaranteed to
// fall within the calling instruction.
regs.r15 = aWord + TaggedUWord((uintptr_t)(-2));
// Make SP be the word above the location where the return
// address was found.
regs.r13 = sp + TaggedUWord(4);
// All other regs are undefined.
regs.r7 = regs.r11 = regs.r12 = regs.r14 = TaggedUWord();
// Move on to the next word up the stack
sp = sp + TaggedUWord(4);
#else
# error "Unknown plat"
#endif
break;
}
} // for (int i = 0; i < NUM_SCANNED_WORDS; i++)
// We tried to make progress by scanning the stack, but failed.
// So give up -- fall out of the top level unwind loop.
if (!scan_succeeded) {
break;
}
}
} // top level unwind loop
// END UNWIND
/////////////////////////////////////////////////////////
}
////////////////////////////////////////////////////////////////
// LUL Unit Testing //
////////////////////////////////////////////////////////////////
static const int LUL_UNIT_TEST_STACK_SIZE = 16384;
// This function is innermost in the test call sequence. It uses LUL
// to unwind, and compares the result with the sequence specified in
// the director string. These need to agree in order for the test to
// pass. In order not to screw up the results, this function needs
// to have a not-very big stack frame, since we're only presenting
// the innermost LUL_UNIT_TEST_STACK_SIZE bytes of stack to LUL, and
// that chunk unavoidably includes the frame for this function.
//
// This function must not be inlined into its callers. Doing so will
// cause the expected-vs-actual backtrace consistency checking to
// fail. Prints summary results to |aLUL|'s logging sink and also
// returns a boolean indicating whether or not the test passed.
static __attribute__((noinline))
bool GetAndCheckStackTrace(LUL* aLUL, const char* dstring)
{
// Get hold of the current unwind-start registers.
UnwindRegs startRegs;
memset(&startRegs, 0, sizeof(startRegs));
#if defined(LUL_PLAT_x64_linux)
volatile uintptr_t block[3];
MOZ_ASSERT(sizeof(block) == 24);
__asm__ __volatile__(
"leaq 0(%%rip), %%r15" "\n\t"
"movq %%r15, 0(%0)" "\n\t"
"movq %%rsp, 8(%0)" "\n\t"
"movq %%rbp, 16(%0)" "\n"
: : "r"(&block[0]) : "memory", "r15"
);
startRegs.xip = TaggedUWord(block[0]);
startRegs.xsp = TaggedUWord(block[1]);
startRegs.xbp = TaggedUWord(block[2]);
const uintptr_t REDZONE_SIZE = 128;
uintptr_t start = block[1] - REDZONE_SIZE;
#elif defined(LUL_PLAT_x86_linux) || defined(LUL_PLAT_x86_android)
volatile uintptr_t block[3];
MOZ_ASSERT(sizeof(block) == 12);
__asm__ __volatile__(
".byte 0xE8,0x00,0x00,0x00,0x00"/*call next insn*/ "\n\t"
"popl %%edi" "\n\t"
"movl %%edi, 0(%0)" "\n\t"
"movl %%esp, 4(%0)" "\n\t"
"movl %%ebp, 8(%0)" "\n"
: : "r"(&block[0]) : "memory", "edi"
);
startRegs.xip = TaggedUWord(block[0]);
startRegs.xsp = TaggedUWord(block[1]);
startRegs.xbp = TaggedUWord(block[2]);
const uintptr_t REDZONE_SIZE = 0;
uintptr_t start = block[1] - REDZONE_SIZE;
#elif defined(LUL_PLAT_arm_android)
volatile uintptr_t block[6];
MOZ_ASSERT(sizeof(block) == 24);
__asm__ __volatile__(
"mov r0, r15" "\n\t"
"str r0, [%0, #0]" "\n\t"
"str r14, [%0, #4]" "\n\t"
"str r13, [%0, #8]" "\n\t"
"str r12, [%0, #12]" "\n\t"
"str r11, [%0, #16]" "\n\t"
"str r7, [%0, #20]" "\n"
: : "r"(&block[0]) : "memory", "r0"
);
startRegs.r15 = TaggedUWord(block[0]);
startRegs.r14 = TaggedUWord(block[1]);
startRegs.r13 = TaggedUWord(block[2]);
startRegs.r12 = TaggedUWord(block[3]);
startRegs.r11 = TaggedUWord(block[4]);
startRegs.r7 = TaggedUWord(block[5]);
const uintptr_t REDZONE_SIZE = 0;
uintptr_t start = block[1] - REDZONE_SIZE;
#else
# error "Unsupported platform"
#endif
// Get hold of the innermost LUL_UNIT_TEST_STACK_SIZE bytes of the
// stack.
uintptr_t end = start + LUL_UNIT_TEST_STACK_SIZE;
uintptr_t ws = sizeof(void*);
start &= ~(ws-1);
end &= ~(ws-1);
uintptr_t nToCopy = end - start;
if (nToCopy > lul::N_STACK_BYTES) {
nToCopy = lul::N_STACK_BYTES;
}
MOZ_ASSERT(nToCopy <= lul::N_STACK_BYTES);
StackImage* stackImg = new StackImage();
stackImg->mLen = nToCopy;
stackImg->mStartAvma = start;
if (nToCopy > 0) {
MOZ_MAKE_MEM_DEFINED((void*)start, nToCopy);
memcpy(&stackImg->mContents[0], (void*)start, nToCopy);
}
// Unwind it.
const int MAX_TEST_FRAMES = 64;
uintptr_t framePCs[MAX_TEST_FRAMES];
uintptr_t frameSPs[MAX_TEST_FRAMES];
size_t framesAvail = mozilla::ArrayLength(framePCs);
size_t framesUsed = 0;
size_t scannedFramesAllowed = 0;
size_t scannedFramesAcquired = 0;
aLUL->Unwind( &framePCs[0], &frameSPs[0],
&framesUsed, &scannedFramesAcquired,
framesAvail, scannedFramesAllowed,
&startRegs, stackImg );
delete stackImg;
//if (0) {
// // Show what we have.
// fprintf(stderr, "Got %d frames:\n", (int)framesUsed);
// for (size_t i = 0; i < framesUsed; i++) {
// fprintf(stderr, " [%2d] SP %p PC %p\n",
// (int)i, (void*)frameSPs[i], (void*)framePCs[i]);
// }
// fprintf(stderr, "\n");
//}
// Check to see if there's a consistent binding between digits in
// the director string ('1' .. '8') and the PC values acquired by
// the unwind. If there isn't, the unwinding has failed somehow.
uintptr_t binding[8]; // binding for '1' .. binding for '8'
memset((void*)binding, 0, sizeof(binding));
// The general plan is to work backwards along the director string
// and forwards along the framePCs array. Doing so corresponds to
// working outwards from the innermost frame of the recursive test set.
const char* cursor = dstring;
// Find the end. This leaves |cursor| two bytes past the first
// character we want to look at -- see comment below.
while (*cursor) cursor++;
// Counts the number of consistent frames.
size_t nConsistent = 0;
// Iterate back to the start of the director string. The starting
// points are a bit complex. We can't use framePCs[0] because that
// contains the PC in this frame (above). We can't use framePCs[1]
// because that will contain the PC at return point in the recursive
// test group (TestFn[1-8]) for their call "out" to this function,
// GetAndCheckStackTrace. Although LUL will compute a correct
// return address, that will not be the same return address as for a
// recursive call out of the the function to another function in the
// group. Hence we can only start consistency checking at
// framePCs[2].
//
// To be consistent, then, we must ignore the last element in the
// director string as that corresponds to framePCs[1]. Hence the
// start points are: framePCs[2] and the director string 2 bytes
// before the terminating zero.
//
// Also as a result of this, the number of consistent frames counted
// will always be one less than the length of the director string
// (not including its terminating zero).
size_t frameIx;
for (cursor = cursor-2, frameIx = 2;
cursor >= dstring && frameIx < framesUsed;
cursor--, frameIx++) {
char c = *cursor;
uintptr_t pc = framePCs[frameIx];
// If this doesn't hold, the director string is ill-formed.
MOZ_ASSERT(c >= '1' && c <= '8');
int n = ((int)c) - ((int)'1');
if (binding[n] == 0) {
// There's no binding for |c| yet, so install |pc| and carry on.
binding[n] = pc;
nConsistent++;
continue;
}
// There's a pre-existing binding for |c|. Check it's consistent.
if (binding[n] != pc) {
// Not consistent. Give up now.
break;
}
// Consistent. Keep going.
nConsistent++;
}
// So, did we succeed?
bool passed = nConsistent+1 == strlen(dstring);
// Show the results.
char buf[200];
snprintf_literal(buf, "LULUnitTest: dstring = %s\n", dstring);
buf[sizeof(buf)-1] = 0;
aLUL->mLog(buf);
snprintf_literal(buf,
"LULUnitTest: %d consistent, %d in dstring: %s\n",
(int)nConsistent, (int)strlen(dstring),
passed ? "PASS" : "FAIL");
buf[sizeof(buf)-1] = 0;
aLUL->mLog(buf);
return passed;
}
// Macro magic to create a set of 8 mutually recursive functions with
// varying frame sizes. These will recurse amongst themselves as
// specified by |strP|, the directory string, and call
// GetAndCheckStackTrace when the string becomes empty, passing it the
// original value of the string. This checks the result, printing
// results on |aLUL|'s logging sink, and also returns a boolean
// indicating whether or not the results are acceptable (correct).
#define DECL_TEST_FN(NAME) \
bool NAME(LUL* aLUL, const char* strPorig, const char* strP);
#define GEN_TEST_FN(NAME, FRAMESIZE) \
bool NAME(LUL* aLUL, const char* strPorig, const char* strP) { \
volatile char space[FRAMESIZE]; \
memset((char*)&space[0], 0, sizeof(space)); \
if (*strP == '\0') { \
/* We've come to the end of the director string. */ \
/* Take a stack snapshot. */ \
return GetAndCheckStackTrace(aLUL, strPorig); \
} else { \
/* Recurse onwards. This is a bit subtle. The obvious */ \
/* thing to do here is call onwards directly, from within the */ \
/* arms of the case statement. That gives a problem in that */ \
/* there will be multiple return points inside each function when */ \
/* unwinding, so it will be difficult to check for consistency */ \
/* against the director string. Instead, we make an indirect */ \
/* call, so as to guarantee that there is only one call site */ \
/* within each function. This does assume that the compiler */ \
/* won't transform it back to the simple direct-call form. */ \
/* To discourage it from doing so, the call is bracketed with */ \
/* __asm__ __volatile__ sections so as to make it not-movable. */ \
bool (*nextFn)(LUL*, const char*, const char*) = NULL; \
switch (*strP) { \
case '1': nextFn = TestFn1; break; \
case '2': nextFn = TestFn2; break; \
case '3': nextFn = TestFn3; break; \
case '4': nextFn = TestFn4; break; \
case '5': nextFn = TestFn5; break; \
case '6': nextFn = TestFn6; break; \
case '7': nextFn = TestFn7; break; \
case '8': nextFn = TestFn8; break; \
default: nextFn = TestFn8; break; \
} \
__asm__ __volatile__("":::"cc","memory"); \
bool passed = nextFn(aLUL, strPorig, strP+1); \
__asm__ __volatile__("":::"cc","memory"); \
return passed; \
} \
}
// The test functions are mutually recursive, so it is necessary to
// declare them before defining them.
DECL_TEST_FN(TestFn1)
DECL_TEST_FN(TestFn2)
DECL_TEST_FN(TestFn3)
DECL_TEST_FN(TestFn4)
DECL_TEST_FN(TestFn5)
DECL_TEST_FN(TestFn6)
DECL_TEST_FN(TestFn7)
DECL_TEST_FN(TestFn8)
GEN_TEST_FN(TestFn1, 123)
GEN_TEST_FN(TestFn2, 456)
GEN_TEST_FN(TestFn3, 789)
GEN_TEST_FN(TestFn4, 23)
GEN_TEST_FN(TestFn5, 47)
GEN_TEST_FN(TestFn6, 117)
GEN_TEST_FN(TestFn7, 1)
GEN_TEST_FN(TestFn8, 99)
// This starts the test sequence going. Call here to generate a
// sequence of calls as directed by the string |dstring|. The call
// sequence will, from its innermost frame, finish by calling
// GetAndCheckStackTrace() and passing it |dstring|.
// GetAndCheckStackTrace() will unwind the stack, check consistency
// of those results against |dstring|, and print a pass/fail message
// to aLUL's logging sink. It also updates the counters in *aNTests
// and aNTestsPassed.
__attribute__((noinline)) void
TestUnw(/*OUT*/int* aNTests, /*OUT*/int*aNTestsPassed,
LUL* aLUL, const char* dstring)
{
// Ensure that the stack has at least this much space on it. This
// makes it safe to saw off the top LUL_UNIT_TEST_STACK_SIZE bytes
// and hand it to LUL. Safe in the sense that no segfault can
// happen because the stack is at least this big. This is all
// somewhat dubious in the sense that a sufficiently clever compiler
// (clang, for one) can figure out that space[] is unused and delete
// it from the frame. Hence the somewhat elaborate hoop jumping to
// fill it up before the call and to at least appear to use the
// value afterwards.
int i;
volatile char space[LUL_UNIT_TEST_STACK_SIZE];
for (i = 0; i < LUL_UNIT_TEST_STACK_SIZE; i++) {
space[i] = (char)(i & 0x7F);
}
// Really run the test.
bool passed = TestFn1(aLUL, dstring, dstring);
// Appear to use space[], by visiting the value to compute some kind
// of checksum, and then (apparently) using the checksum.
int sum = 0;
for (i = 0; i < LUL_UNIT_TEST_STACK_SIZE; i++) {
// If this doesn't fool LLVM, I don't know what will.
sum += space[i] - 3*i;
}
__asm__ __volatile__("" : : "r"(sum));
// Update the counters.
(*aNTests)++;
if (passed) {
(*aNTestsPassed)++;
}
}
void
RunLulUnitTests(/*OUT*/int* aNTests, /*OUT*/int*aNTestsPassed, LUL* aLUL)
{
aLUL->mLog(":\n");
aLUL->mLog("LULUnitTest: BEGIN\n");
*aNTests = *aNTestsPassed = 0;
TestUnw(aNTests, aNTestsPassed, aLUL, "11111111");
TestUnw(aNTests, aNTestsPassed, aLUL, "11222211");
TestUnw(aNTests, aNTestsPassed, aLUL, "111222333");
TestUnw(aNTests, aNTestsPassed, aLUL, "1212121231212331212121212121212");
TestUnw(aNTests, aNTestsPassed, aLUL, "31415827271828325332173258");
TestUnw(aNTests, aNTestsPassed, aLUL,
"123456781122334455667788777777777777777777777");
aLUL->mLog("LULUnitTest: END\n");
aLUL->mLog(":\n");
}
} // namespace lul
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