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// Copyright (c) 2010 Google Inc.
// 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 Google Inc. 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.
// exploitability_win.cc: Windows specific exploitability engine.
//
// Provides a guess at the exploitability of the crash for the Windows
// platform given a minidump and process_state.
//
// Author: Cris Neckar
#include <vector>
#include "processor/exploitability_win.h"
#include "common/scoped_ptr.h"
#include "google_breakpad/common/minidump_exception_win32.h"
#include "google_breakpad/processor/minidump.h"
#include "processor/disassembler_x86.h"
#include "processor/logging.h"
#include "third_party/libdisasm/libdis.h"
namespace google_breakpad {
// The cutoff that we use to judge if and address is likely an offset
// from various interesting addresses.
static const uint64_t kProbableNullOffset = 4096;
static const uint64_t kProbableStackOffset = 8192;
// The various cutoffs for the different ratings.
static const size_t kHighCutoff = 100;
static const size_t kMediumCutoff = 80;
static const size_t kLowCutoff = 50;
static const size_t kInterestingCutoff = 25;
// Predefined incremental values for conditional weighting.
static const size_t kTinyBump = 5;
static const size_t kSmallBump = 20;
static const size_t kMediumBump = 50;
static const size_t kLargeBump = 70;
static const size_t kHugeBump = 90;
// The maximum number of bytes to disassemble past the program counter.
static const size_t kDisassembleBytesBeyondPC = 2048;
ExploitabilityWin::ExploitabilityWin(Minidump *dump,
ProcessState *process_state)
: Exploitability(dump, process_state) { }
ExploitabilityRating ExploitabilityWin::CheckPlatformExploitability() {
MinidumpException *exception = dump_->GetException();
if (!exception) {
BPLOG(INFO) << "Minidump does not have exception record.";
return EXPLOITABILITY_ERR_PROCESSING;
}
const MDRawExceptionStream *raw_exception = exception->exception();
if (!raw_exception) {
BPLOG(INFO) << "Could not obtain raw exception info.";
return EXPLOITABILITY_ERR_PROCESSING;
}
const MinidumpContext *context = exception->GetContext();
if (!context) {
BPLOG(INFO) << "Could not obtain exception context.";
return EXPLOITABILITY_ERR_PROCESSING;
}
MinidumpMemoryList *memory_list = dump_->GetMemoryList();
bool memory_available = true;
if (!memory_list) {
BPLOG(INFO) << "Minidump memory segments not available.";
memory_available = false;
}
uint64_t address = process_state_->crash_address();
uint32_t exception_code = raw_exception->exception_record.exception_code;
uint32_t exploitability_weight = 0;
uint64_t stack_ptr = 0;
uint64_t instruction_ptr = 0;
switch (context->GetContextCPU()) {
case MD_CONTEXT_X86:
stack_ptr = context->GetContextX86()->esp;
instruction_ptr = context->GetContextX86()->eip;
break;
case MD_CONTEXT_AMD64:
stack_ptr = context->GetContextAMD64()->rsp;
instruction_ptr = context->GetContextAMD64()->rip;
break;
default:
BPLOG(INFO) << "Unsupported architecture.";
return EXPLOITABILITY_ERR_PROCESSING;
}
// Check if we are executing on the stack.
if (instruction_ptr <= (stack_ptr + kProbableStackOffset) &&
instruction_ptr >= (stack_ptr - kProbableStackOffset))
exploitability_weight += kHugeBump;
switch (exception_code) {
// This is almost certainly recursion.
case MD_EXCEPTION_CODE_WIN_STACK_OVERFLOW:
exploitability_weight += kTinyBump;
break;
// These exceptions tend to be benign and we can generally ignore them.
case MD_EXCEPTION_CODE_WIN_INTEGER_DIVIDE_BY_ZERO:
case MD_EXCEPTION_CODE_WIN_INTEGER_OVERFLOW:
case MD_EXCEPTION_CODE_WIN_FLOAT_DIVIDE_BY_ZERO:
case MD_EXCEPTION_CODE_WIN_FLOAT_INEXACT_RESULT:
case MD_EXCEPTION_CODE_WIN_FLOAT_OVERFLOW:
case MD_EXCEPTION_CODE_WIN_FLOAT_UNDERFLOW:
case MD_EXCEPTION_CODE_WIN_IN_PAGE_ERROR:
exploitability_weight += kTinyBump;
break;
// These exceptions will typically mean that we have jumped where we
// shouldn't.
case MD_EXCEPTION_CODE_WIN_ILLEGAL_INSTRUCTION:
case MD_EXCEPTION_CODE_WIN_FLOAT_INVALID_OPERATION:
case MD_EXCEPTION_CODE_WIN_PRIVILEGED_INSTRUCTION:
exploitability_weight += kLargeBump;
break;
// These represent bugs in exception handlers.
case MD_EXCEPTION_CODE_WIN_INVALID_DISPOSITION:
case MD_EXCEPTION_CODE_WIN_NONCONTINUABLE_EXCEPTION:
exploitability_weight += kSmallBump;
break;
case MD_EXCEPTION_CODE_WIN_HEAP_CORRUPTION:
case MD_EXCEPTION_CODE_WIN_STACK_BUFFER_OVERRUN:
exploitability_weight += kHugeBump;
break;
case MD_EXCEPTION_CODE_WIN_GUARD_PAGE_VIOLATION:
exploitability_weight += kLargeBump;
break;
case MD_EXCEPTION_CODE_WIN_ACCESS_VIOLATION:
bool near_null = (address <= kProbableNullOffset);
bool bad_read = false;
bool bad_write = false;
if (raw_exception->exception_record.number_parameters >= 1) {
MDAccessViolationTypeWin av_type =
static_cast<MDAccessViolationTypeWin>
(raw_exception->exception_record.exception_information[0]);
switch (av_type) {
case MD_ACCESS_VIOLATION_WIN_READ:
bad_read = true;
if (near_null)
exploitability_weight += kSmallBump;
else
exploitability_weight += kMediumBump;
break;
case MD_ACCESS_VIOLATION_WIN_WRITE:
bad_write = true;
if (near_null)
exploitability_weight += kSmallBump;
else
exploitability_weight += kHugeBump;
break;
case MD_ACCESS_VIOLATION_WIN_EXEC:
if (near_null)
exploitability_weight += kSmallBump;
else
exploitability_weight += kHugeBump;
break;
default:
BPLOG(INFO) << "Unrecognized access violation type.";
return EXPLOITABILITY_ERR_PROCESSING;
break;
}
MinidumpMemoryRegion *instruction_region = 0;
if (memory_available) {
instruction_region =
memory_list->GetMemoryRegionForAddress(instruction_ptr);
}
if (!near_null && instruction_region &&
context->GetContextCPU() == MD_CONTEXT_X86 &&
(bad_read || bad_write)) {
// Perform checks related to memory around instruction pointer.
uint32_t memory_offset =
instruction_ptr - instruction_region->GetBase();
uint32_t available_memory =
instruction_region->GetSize() - memory_offset;
available_memory = available_memory > kDisassembleBytesBeyondPC ?
kDisassembleBytesBeyondPC : available_memory;
if (available_memory) {
const uint8_t *raw_memory =
instruction_region->GetMemory() + memory_offset;
DisassemblerX86 disassembler(raw_memory,
available_memory,
instruction_ptr);
disassembler.NextInstruction();
if (bad_read)
disassembler.setBadRead();
else
disassembler.setBadWrite();
if (disassembler.currentInstructionValid()) {
// Check if the faulting instruction falls into one of
// several interesting groups.
switch (disassembler.currentInstructionGroup()) {
case libdis::insn_controlflow:
exploitability_weight += kLargeBump;
break;
case libdis::insn_string:
exploitability_weight += kHugeBump;
break;
default:
break;
}
// Loop the disassembler through the code and check if it
// IDed any interesting conditions in the near future.
// Multiple flags may be set so treat each equally.
while (disassembler.NextInstruction() &&
disassembler.currentInstructionValid() &&
!disassembler.endOfBlock())
continue;
if (disassembler.flags() & DISX86_BAD_BRANCH_TARGET)
exploitability_weight += kLargeBump;
if (disassembler.flags() & DISX86_BAD_ARGUMENT_PASSED)
exploitability_weight += kTinyBump;
if (disassembler.flags() & DISX86_BAD_WRITE)
exploitability_weight += kMediumBump;
if (disassembler.flags() & DISX86_BAD_BLOCK_WRITE)
exploitability_weight += kMediumBump;
if (disassembler.flags() & DISX86_BAD_READ)
exploitability_weight += kTinyBump;
if (disassembler.flags() & DISX86_BAD_BLOCK_READ)
exploitability_weight += kTinyBump;
if (disassembler.flags() & DISX86_BAD_COMPARISON)
exploitability_weight += kTinyBump;
}
}
}
if (!near_null && AddressIsAscii(address))
exploitability_weight += kMediumBump;
} else {
BPLOG(INFO) << "Access violation type parameter missing.";
return EXPLOITABILITY_ERR_PROCESSING;
}
}
// Based on the calculated weight we return a simplified classification.
BPLOG(INFO) << "Calculated exploitability weight: " << exploitability_weight;
if (exploitability_weight >= kHighCutoff)
return EXPLOITABILITY_HIGH;
if (exploitability_weight >= kMediumCutoff)
return EXPLOITABLITY_MEDIUM;
if (exploitability_weight >= kLowCutoff)
return EXPLOITABILITY_LOW;
if (exploitability_weight >= kInterestingCutoff)
return EXPLOITABILITY_INTERESTING;
return EXPLOITABILITY_NONE;
}
} // namespace google_breakpad