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// exploitability_linux.h: Linux specific exploitability engine.
//
// Provides a guess at the exploitability of the crash for the Linux
// platform given a minidump and process_state.
//
// Author: Matthew Riley

#ifndef GOOGLE_BREAKPAD_PROCESSOR_EXPLOITABILITY_LINUX_H_
#define GOOGLE_BREAKPAD_PROCESSOR_EXPLOITABILITY_LINUX_H_

#include "google_breakpad/common/breakpad_types.h"
#include "google_breakpad/processor/exploitability.h"

namespace google_breakpad {

class ExploitabilityLinux : public Exploitability {
 public:
  ExploitabilityLinux(Minidump* dump,
                      ProcessState* process_state);

  // Parameters are the minidump to analyze, the object representing process
  // state, and whether to enable objdump disassembly.
  // Enabling objdump will allow exploitability analysis to call out to
  // objdump for diassembly. It is used to check the identity of the
  // instruction that caused the program to crash. If there are any
  // portability concerns, this should not be enabled.
  ExploitabilityLinux(Minidump* dump,
                      ProcessState* process_state,
                      bool enable_objdump);

  virtual ExploitabilityRating CheckPlatformExploitability();

 private:
  friend class ExploitabilityLinuxTest;

  // Takes the address of the instruction pointer and returns
  // whether the instruction pointer lies in a valid instruction region.
  bool InstructionPointerInCode(uint64_t instruction_ptr);

  // Checks the exception that triggered the creation of the
  // minidump and reports whether the exception suggests no exploitability.
  bool BenignCrashTrigger(const MDRawExceptionStream* raw_exception_stream);

  // This method checks if the crash occurred during a write to read-only or
  // invalid memory. It does so by checking if the instruction at the
  // instruction pointer is a write instruction, and if the target of the
  // instruction is at a spot in memory that prohibits writes.
  bool EndedOnIllegalWrite(uint64_t instruction_ptr);

#ifndef _WIN32
  // Disassembles raw bytes via objdump and pipes the output into the provided
  // buffer, given the desired architecture, the file from which objdump will
  // read, and the buffer length. The method returns whether the disassembly
  // was a success, and the caller owns all pointers.
  static bool DisassembleBytes(const string& architecture,
                               const uint8_t* raw_bytes,
                               const unsigned int MAX_OBJDUMP_BUFFER_LEN,
                               char* objdump_output_buffer);

  // Parses the objdump output given in |objdump_output_buffer| and extracts
  // the line of the first instruction into |instruction_line|.  Returns true
  // when the instruction line is successfully extracted.
  static bool GetObjdumpInstructionLine(
      const char* objdump_output_buffer,
      string* instruction_line);

  // Tokenizes out the operation and operands from a line of instruction
  // disassembled by objdump. This method modifies the pointers to match the
  // tokens of the instruction, and returns if the tokenizing was a success.
  // The caller owns all pointers.
  static bool TokenizeObjdumpInstruction(const string& line,
                                         string* operation,
                                         string* dest,
                                         string* src);

  // Calculates the effective address of an expression in the form reg+a or
  // reg-a, where 'reg' is a register and 'a' is a constant, and writes the
  // result in the pointer. The method returns whether the calculation was
  // a success. The caller owns the pointer.
  static bool CalculateAddress(const string& address_expression,
                               const DumpContext& context,
                               uint64_t* write_address);
#endif  // _WIN32

  // Checks if the stack pointer points to a memory mapping that is not
  // labelled as the stack.
  bool StackPointerOffStack(uint64_t stack_ptr);

  // Checks if the stack or heap are marked executable according
  // to the memory mappings.
  bool ExecutableStackOrHeap();

  // Whether this exploitability engine is permitted to shell out to objdump
  // to disassemble raw bytes.
  bool enable_objdump_;
};

}  // namespace google_breakpad

#endif  // GOOGLE_BREAKPAD_PROCESSOR_EXPLOITABILITY_LINUX_H_