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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.
// minidump.h: A minidump reader.
//
// The basic structure of this module tracks the structure of the minidump
// file itself. At the top level, a minidump file is represented by a
// Minidump object. Like most other classes in this module, Minidump
// provides a Read method that initializes the object with information from
// the file. Most of the classes in this file are wrappers around the
// "raw" structures found in the minidump file itself, and defined in
// minidump_format.h. For example, each thread is represented by a
// MinidumpThread object, whose parameters are specified in an MDRawThread
// structure. A properly byte-swapped MDRawThread can be obtained from a
// MinidumpThread easily by calling its thread() method.
//
// Most of the module lazily reads only the portion of the minidump file
// necessary to fulfill the user's request. Calling Minidump::Read
// only reads the minidump's directory. The thread list is not read until
// it is needed, and even once it's read, the memory regions for each
// thread's stack aren't read until they're needed. This strategy avoids
// unnecessary file input, and allocating memory for data in which the user
// has no interest. Note that although memory allocations for a typical
// minidump file are not particularly large, it is possible for legitimate
// minidumps to be sizable. A full-memory minidump, for example, contains
// a snapshot of the entire mapped memory space. Even a normal minidump,
// with stack memory only, can be large if, for example, the dump was
// generated in response to a crash that occurred due to an infinite-
// recursion bug that caused the stack's limits to be exceeded. Finally,
// some users of this library will unfortunately find themselves in the
// position of having to process potentially-hostile minidumps that might
// attempt to cause problems by forcing the minidump processor to over-
// allocate memory.
//
// Memory management in this module is based on a strict
// you-don't-own-anything policy. The only object owned by the user is
// the top-level Minidump object, the creation and destruction of which
// must be the user's own responsibility. All other objects obtained
// through interaction with this module are ultimately owned by the
// Minidump object, and will be freed upon the Minidump object's destruction.
// Because memory regions can potentially involve large allocations, a
// FreeMemory method is provided by MinidumpMemoryRegion, allowing the user
// to release data when it is no longer needed. Use of this method is
// optional but recommended. If freed data is later required, it will
// be read back in from the minidump file again.
//
// There is one exception to this memory management policy:
// Minidump::ReadString will return a string object to the user, and the user
// is responsible for its deletion.
//
// Author: Mark Mentovai
#ifndef GOOGLE_BREAKPAD_PROCESSOR_MINIDUMP_H__
#define GOOGLE_BREAKPAD_PROCESSOR_MINIDUMP_H__
#ifndef _WIN32
#include <unistd.h>
#endif
#include <iostream>
#include <map>
#include <string>
#include <vector>
#include "common/using_std_string.h"
#include "google_breakpad/common/minidump_format.h"
#include "google_breakpad/processor/code_module.h"
#include "google_breakpad/processor/code_modules.h"
#include "google_breakpad/processor/memory_region.h"
namespace google_breakpad {
using std::map;
using std::vector;
class Minidump;
template<typename AddressType, typename EntryType> class RangeMap;
// MinidumpObject is the base of all Minidump* objects except for Minidump
// itself.
class MinidumpObject {
public:
virtual ~MinidumpObject() {}
bool valid() const { return valid_; }
protected:
explicit MinidumpObject(Minidump* minidump);
// Refers to the Minidump object that is the ultimate parent of this
// Some MinidumpObjects are owned by other MinidumpObjects, but at the
// root of the ownership tree is always a Minidump. The Minidump object
// is kept here for access to its seeking and reading facilities, and
// for access to data about the minidump file itself, such as whether
// it should be byte-swapped.
Minidump* minidump_;
// MinidumpObjects are not valid when created. When a subclass populates
// its own fields, it can set valid_ to true. Accessors and mutators may
// wish to consider or alter the valid_ state as they interact with
// objects.
bool valid_;
};
// This class exists primarily to provide a virtual destructor in a base
// class common to all objects that might be stored in
// Minidump::mStreamObjects. Some object types (MinidumpContext) will
// never be stored in Minidump::mStreamObjects, but are represented as
// streams and adhere to the same interface, and may be derived from
// this class.
class MinidumpStream : public MinidumpObject {
public:
virtual ~MinidumpStream() {}
protected:
explicit MinidumpStream(Minidump* minidump);
private:
// Populate (and validate) the MinidumpStream. minidump_ is expected
// to be positioned at the beginning of the stream, so that the next
// read from the minidump will be at the beginning of the stream.
// expected_size should be set to the stream's length as contained in
// the MDRawDirectory record or other identifying record. A class
// that implements MinidumpStream can compare expected_size to a
// known size as an integrity check.
virtual bool Read(uint32_t expected_size) = 0;
};
// MinidumpContext carries a CPU-specific MDRawContext structure, which
// contains CPU context such as register states. Each thread has its
// own context, and the exception record, if present, also has its own
// context. Note that if the exception record is present, the context it
// refers to is probably what the user wants to use for the exception
// thread, instead of that thread's own context. The exception thread's
// context (as opposed to the exception record's context) will contain
// context for the exception handler (which performs minidump generation),
// and not the context that caused the exception (which is probably what the
// user wants).
class MinidumpContext : public MinidumpStream {
public:
virtual ~MinidumpContext();
// Returns an MD_CONTEXT_* value such as MD_CONTEXT_X86 or MD_CONTEXT_PPC
// identifying the CPU type that the context was collected from. The
// returned value will identify the CPU only, and will have any other
// MD_CONTEXT_* bits masked out. Returns 0 on failure.
uint32_t GetContextCPU() const;
// A convenience method to get the instruction pointer out of the
// MDRawContext, since it varies per-CPU architecture.
bool GetInstructionPointer(uint64_t* ip) const;
// Returns raw CPU-specific context data for the named CPU type. If the
// context data does not match the CPU type or does not exist, returns
// NULL.
const MDRawContextAMD64* GetContextAMD64() const;
const MDRawContextARM* GetContextARM() const;
const MDRawContextMIPS* GetContextMIPS() const;
const MDRawContextPPC* GetContextPPC() const;
const MDRawContextPPC64* GetContextPPC64() const;
const MDRawContextSPARC* GetContextSPARC() const;
const MDRawContextX86* GetContextX86() const;
// Print a human-readable representation of the object to stdout.
void Print();
protected:
explicit MinidumpContext(Minidump* minidump);
// The CPU-specific context structure.
union {
MDRawContextBase* base;
MDRawContextX86* x86;
MDRawContextPPC* ppc;
MDRawContextPPC64* ppc64;
MDRawContextAMD64* amd64;
// on Solaris SPARC, sparc is defined as a numeric constant,
// so variables can NOT be named as sparc
MDRawContextSPARC* ctx_sparc;
MDRawContextARM* arm;
MDRawContextMIPS* ctx_mips;
} context_;
// Store this separately because of the weirdo AMD64 context
uint32_t context_flags_;
private:
friend class MinidumpThread;
friend class MinidumpException;
bool Read(uint32_t expected_size);
// Free the CPU-specific context structure.
void FreeContext();
// If the minidump contains a SYSTEM_INFO_STREAM, makes sure that the
// system info stream gives an appropriate CPU type matching the context
// CPU type in context_cpu_type. Returns false if the CPU type does not
// match. Returns true if the CPU type matches or if the minidump does
// not contain a system info stream.
bool CheckAgainstSystemInfo(uint32_t context_cpu_type);
};
// MinidumpMemoryRegion does not wrap any MDRaw structure, and only contains
// a reference to an MDMemoryDescriptor. This object is intended to wrap
// portions of a minidump file that contain memory dumps. In normal
// minidumps, each MinidumpThread owns a MinidumpMemoryRegion corresponding
// to the thread's stack memory. MinidumpMemoryList also gives access to
// memory regions in its list as MinidumpMemoryRegions. This class
// adheres to MemoryRegion so that it may be used as a data provider to
// the Stackwalker family of classes.
class MinidumpMemoryRegion : public MinidumpObject,
public MemoryRegion {
public:
virtual ~MinidumpMemoryRegion();
static void set_max_bytes(uint32_t max_bytes) { max_bytes_ = max_bytes; }
static uint32_t max_bytes() { return max_bytes_; }
// Returns a pointer to the base of the memory region. Returns the
// cached value if available, otherwise, reads the minidump file and
// caches the memory region.
const uint8_t* GetMemory() const;
// The address of the base of the memory region.
uint64_t GetBase() const;
// The size, in bytes, of the memory region.
uint32_t GetSize() const;
// Frees the cached memory region, if cached.
void FreeMemory();
// Obtains the value of memory at the pointer specified by address.
bool GetMemoryAtAddress(uint64_t address, uint8_t* value) const;
bool GetMemoryAtAddress(uint64_t address, uint16_t* value) const;
bool GetMemoryAtAddress(uint64_t address, uint32_t* value) const;
bool GetMemoryAtAddress(uint64_t address, uint64_t* value) const;
// Print a human-readable representation of the object to stdout.
void Print();
protected:
explicit MinidumpMemoryRegion(Minidump* minidump);
private:
friend class MinidumpThread;
friend class MinidumpMemoryList;
// Identify the base address and size of the memory region, and the
// location it may be found in the minidump file.
void SetDescriptor(MDMemoryDescriptor* descriptor);
// Implementation for GetMemoryAtAddress
template<typename T> bool GetMemoryAtAddressInternal(uint64_t address,
T* value) const;
// The largest memory region that will be read from a minidump. The
// default is 1MB.
static uint32_t max_bytes_;
// Base address and size of the memory region, and its position in the
// minidump file.
MDMemoryDescriptor* descriptor_;
// Cached memory.
mutable vector<uint8_t>* memory_;
};
// MinidumpThread contains information about a thread of execution,
// including a snapshot of the thread's stack and CPU context. For
// the thread that caused an exception, the context carried by
// MinidumpException is probably desired instead of the CPU context
// provided here.
// Note that a MinidumpThread may be valid() even if it does not
// contain a memory region or context.
class MinidumpThread : public MinidumpObject {
public:
virtual ~MinidumpThread();
const MDRawThread* thread() const { return valid_ ? &thread_ : NULL; }
// GetMemory may return NULL even if the MinidumpThread is valid,
// if the thread memory cannot be read.
virtual MinidumpMemoryRegion* GetMemory();
// GetContext may return NULL even if the MinidumpThread is valid.
virtual MinidumpContext* GetContext();
// The thread ID is used to determine if a thread is the exception thread,
// so a special getter is provided to retrieve this data from the
// MDRawThread structure. Returns false if the thread ID cannot be
// determined.
virtual bool GetThreadID(uint32_t *thread_id) const;
// Print a human-readable representation of the object to stdout.
void Print();
// Returns the start address of the thread stack memory region. Returns 0 if
// MinidumpThread is invalid. Note that this method can be called even when
// the thread memory cannot be read and GetMemory returns NULL.
virtual uint64_t GetStartOfStackMemoryRange() const;
protected:
explicit MinidumpThread(Minidump* minidump);
private:
// These objects are managed by MinidumpThreadList.
friend class MinidumpThreadList;
// This works like MinidumpStream::Read, but is driven by
// MinidumpThreadList. No size checking is done, because
// MinidumpThreadList handles that directly.
bool Read();
MDRawThread thread_;
MinidumpMemoryRegion* memory_;
MinidumpContext* context_;
};
// MinidumpThreadList contains all of the threads (as MinidumpThreads) in
// a process.
class MinidumpThreadList : public MinidumpStream {
public:
virtual ~MinidumpThreadList();
static void set_max_threads(uint32_t max_threads) {
max_threads_ = max_threads;
}
static uint32_t max_threads() { return max_threads_; }
virtual unsigned int thread_count() const {
return valid_ ? thread_count_ : 0;
}
// Sequential access to threads.
virtual MinidumpThread* GetThreadAtIndex(unsigned int index) const;
// Random access to threads.
MinidumpThread* GetThreadByID(uint32_t thread_id);
// Print a human-readable representation of the object to stdout.
void Print();
protected:
explicit MinidumpThreadList(Minidump* aMinidump);
private:
friend class Minidump;
typedef map<uint32_t, MinidumpThread*> IDToThreadMap;
typedef vector<MinidumpThread> MinidumpThreads;
static const uint32_t kStreamType = MD_THREAD_LIST_STREAM;
bool Read(uint32_t aExpectedSize);
// The largest number of threads that will be read from a minidump. The
// default is 256.
static uint32_t max_threads_;
// Access to threads using the thread ID as the key.
IDToThreadMap id_to_thread_map_;
// The list of threads.
MinidumpThreads* threads_;
uint32_t thread_count_;
};
// MinidumpModule wraps MDRawModule, which contains information about loaded
// code modules. Access is provided to various data referenced indirectly
// by MDRawModule, such as the module's name and a specification for where
// to locate debugging information for the module.
class MinidumpModule : public MinidumpObject,
public CodeModule {
public:
virtual ~MinidumpModule();
static void set_max_cv_bytes(uint32_t max_cv_bytes) {
max_cv_bytes_ = max_cv_bytes;
}
static uint32_t max_cv_bytes() { return max_cv_bytes_; }
static void set_max_misc_bytes(uint32_t max_misc_bytes) {
max_misc_bytes_ = max_misc_bytes;
}
static uint32_t max_misc_bytes() { return max_misc_bytes_; }
const MDRawModule* module() const { return valid_ ? &module_ : NULL; }
// CodeModule implementation
virtual uint64_t base_address() const {
return valid_ ? module_.base_of_image : static_cast<uint64_t>(-1);
}
virtual uint64_t size() const { return valid_ ? module_.size_of_image : 0; }
virtual string code_file() const;
virtual string code_identifier() const;
virtual string debug_file() const;
virtual string debug_identifier() const;
virtual string version() const;
virtual const CodeModule* Copy() const;
// The CodeView record, which contains information to locate the module's
// debugging information (pdb). This is returned as uint8_t* because
// the data can be of types MDCVInfoPDB20* or MDCVInfoPDB70*, or it may be
// of a type unknown to Breakpad, in which case the raw data will still be
// returned but no byte-swapping will have been performed. Check the
// record's signature in the first four bytes to differentiate between
// the various types. Current toolchains generate modules which carry
// MDCVInfoPDB70 by default. Returns a pointer to the CodeView record on
// success, and NULL on failure. On success, the optional |size| argument
// is set to the size of the CodeView record.
const uint8_t* GetCVRecord(uint32_t* size);
// The miscellaneous debug record, which is obsolete. Current toolchains
// do not generate this type of debugging information (dbg), and this
// field is not expected to be present. Returns a pointer to the debugging
// record on success, and NULL on failure. On success, the optional |size|
// argument is set to the size of the debugging record.
const MDImageDebugMisc* GetMiscRecord(uint32_t* size);
// Print a human-readable representation of the object to stdout.
void Print();
private:
// These objects are managed by MinidumpModuleList.
friend class MinidumpModuleList;
explicit MinidumpModule(Minidump* minidump);
// This works like MinidumpStream::Read, but is driven by
// MinidumpModuleList. No size checking is done, because
// MinidumpModuleList handles that directly.
bool Read();
// Reads indirectly-referenced data, including the module name, CodeView
// record, and miscellaneous debugging record. This is necessary to allow
// MinidumpModuleList to fully construct MinidumpModule objects without
// requiring seeks to read a contiguous set of MinidumpModule objects.
// All auxiliary data should be available when Read is called, in order to
// allow the CodeModule getters to be const methods.
bool ReadAuxiliaryData();
// The largest number of bytes that will be read from a minidump for a
// CodeView record or miscellaneous debugging record, respectively. The
// default for each is 1024.
static uint32_t max_cv_bytes_;
static uint32_t max_misc_bytes_;
// True after a successful Read. This is different from valid_, which is
// not set true until ReadAuxiliaryData also completes successfully.
// module_valid_ is only used by ReadAuxiliaryData and the functions it
// calls to determine whether the object is ready for auxiliary data to
// be read.
bool module_valid_;
// True if debug info was read from the module. Certain modules
// may contain debug records in formats we don't support,
// so we can just set this to false to ignore them.
bool has_debug_info_;
MDRawModule module_;
// Cached module name.
const string* name_;
// Cached CodeView record - this is MDCVInfoPDB20 or (likely)
// MDCVInfoPDB70, or possibly something else entirely. Stored as a uint8_t
// because the structure contains a variable-sized string and its exact
// size cannot be known until it is processed.
vector<uint8_t>* cv_record_;
// If cv_record_ is present, cv_record_signature_ contains a copy of the
// CodeView record's first four bytes, for ease of determinining the
// type of structure that cv_record_ contains.
uint32_t cv_record_signature_;
// Cached MDImageDebugMisc (usually not present), stored as uint8_t
// because the structure contains a variable-sized string and its exact
// size cannot be known until it is processed.
vector<uint8_t>* misc_record_;
};
// MinidumpModuleList contains all of the loaded code modules for a process
// in the form of MinidumpModules. It maintains a map of these modules
// so that it may easily provide a code module corresponding to a specific
// address.
class MinidumpModuleList : public MinidumpStream,
public CodeModules {
public:
virtual ~MinidumpModuleList();
static void set_max_modules(uint32_t max_modules) {
max_modules_ = max_modules;
}
static uint32_t max_modules() { return max_modules_; }
// CodeModules implementation.
virtual unsigned int module_count() const {
return valid_ ? module_count_ : 0;
}
virtual const MinidumpModule* GetModuleForAddress(uint64_t address) const;
virtual const MinidumpModule* GetMainModule() const;
virtual const MinidumpModule* GetModuleAtSequence(
unsigned int sequence) const;
virtual const MinidumpModule* GetModuleAtIndex(unsigned int index) const;
virtual const CodeModules* Copy() const;
// Print a human-readable representation of the object to stdout.
void Print();
protected:
explicit MinidumpModuleList(Minidump* minidump);
private:
friend class Minidump;
typedef vector<MinidumpModule> MinidumpModules;
static const uint32_t kStreamType = MD_MODULE_LIST_STREAM;
bool Read(uint32_t expected_size);
// The largest number of modules that will be read from a minidump. The
// default is 1024.
static uint32_t max_modules_;
// Access to modules using addresses as the key.
RangeMap<uint64_t, unsigned int> *range_map_;
MinidumpModules *modules_;
uint32_t module_count_;
};
// MinidumpMemoryList corresponds to a minidump's MEMORY_LIST_STREAM stream,
// which references the snapshots of all of the memory regions contained
// within the minidump. For a normal minidump, this includes stack memory
// (also referenced by each MinidumpThread, in fact, the MDMemoryDescriptors
// here and in MDRawThread both point to exactly the same data in a
// minidump file, conserving space), as well as a 256-byte snapshot of memory
// surrounding the instruction pointer in the case of an exception. Other
// types of minidumps may contain significantly more memory regions. Full-
// memory minidumps contain all of a process' mapped memory.
class MinidumpMemoryList : public MinidumpStream {
public:
virtual ~MinidumpMemoryList();
static void set_max_regions(uint32_t max_regions) {
max_regions_ = max_regions;
}
static uint32_t max_regions() { return max_regions_; }
unsigned int region_count() const { return valid_ ? region_count_ : 0; }
// Sequential access to memory regions.
MinidumpMemoryRegion* GetMemoryRegionAtIndex(unsigned int index);
// Random access to memory regions. Returns the region encompassing
// the address identified by address.
virtual MinidumpMemoryRegion* GetMemoryRegionForAddress(uint64_t address);
// Print a human-readable representation of the object to stdout.
void Print();
private:
friend class Minidump;
friend class MockMinidumpMemoryList;
typedef vector<MDMemoryDescriptor> MemoryDescriptors;
typedef vector<MinidumpMemoryRegion> MemoryRegions;
static const uint32_t kStreamType = MD_MEMORY_LIST_STREAM;
explicit MinidumpMemoryList(Minidump* minidump);
bool Read(uint32_t expected_size);
// The largest number of memory regions that will be read from a minidump.
// The default is 256.
static uint32_t max_regions_;
// Access to memory regions using addresses as the key.
RangeMap<uint64_t, unsigned int> *range_map_;
// The list of descriptors. This is maintained separately from the list
// of regions, because MemoryRegion doesn't own its MemoryDescriptor, it
// maintains a pointer to it. descriptors_ provides the storage for this
// purpose.
MemoryDescriptors *descriptors_;
// The list of regions.
MemoryRegions *regions_;
uint32_t region_count_;
};
// MinidumpException wraps MDRawExceptionStream, which contains information
// about the exception that caused the minidump to be generated, if the
// minidump was generated in an exception handler called as a result of
// an exception. It also provides access to a MinidumpContext object,
// which contains the CPU context for the exception thread at the time
// the exception occurred.
class MinidumpException : public MinidumpStream {
public:
virtual ~MinidumpException();
const MDRawExceptionStream* exception() const {
return valid_ ? &exception_ : NULL;
}
// The thread ID is used to determine if a thread is the exception thread,
// so a special getter is provided to retrieve this data from the
// MDRawExceptionStream structure. Returns false if the thread ID cannot
// be determined.
bool GetThreadID(uint32_t *thread_id) const;
MinidumpContext* GetContext();
// Print a human-readable representation of the object to stdout.
void Print();
private:
friend class Minidump;
static const uint32_t kStreamType = MD_EXCEPTION_STREAM;
explicit MinidumpException(Minidump* minidump);
bool Read(uint32_t expected_size);
MDRawExceptionStream exception_;
MinidumpContext* context_;
};
// MinidumpAssertion wraps MDRawAssertionInfo, which contains information
// about an assertion that caused the minidump to be generated.
class MinidumpAssertion : public MinidumpStream {
public:
virtual ~MinidumpAssertion();
const MDRawAssertionInfo* assertion() const {
return valid_ ? &assertion_ : NULL;
}
string expression() const {
return valid_ ? expression_ : "";
}
string function() const {
return valid_ ? function_ : "";
}
string file() const {
return valid_ ? file_ : "";
}
// Print a human-readable representation of the object to stdout.
void Print();
private:
friend class Minidump;
static const uint32_t kStreamType = MD_ASSERTION_INFO_STREAM;
explicit MinidumpAssertion(Minidump* minidump);
bool Read(uint32_t expected_size);
MDRawAssertionInfo assertion_;
string expression_;
string function_;
string file_;
};
// MinidumpSystemInfo wraps MDRawSystemInfo and provides information about
// the system on which the minidump was generated. See also MinidumpMiscInfo.
class MinidumpSystemInfo : public MinidumpStream {
public:
virtual ~MinidumpSystemInfo();
const MDRawSystemInfo* system_info() const {
return valid_ ? &system_info_ : NULL;
}
// GetOS and GetCPU return textual representations of the operating system
// and CPU that produced the minidump. Unlike most other Minidump* methods,
// they return string objects, not weak pointers. Defined values for
// GetOS() are "mac", "windows", and "linux". Defined values for GetCPU
// are "x86" and "ppc". These methods return an empty string when their
// values are unknown.
string GetOS();
string GetCPU();
// I don't know what CSD stands for, but this field is documented as
// returning a textual representation of the OS service pack. On other
// platforms, this provides additional information about an OS version
// level beyond major.minor.micro. Returns NULL if unknown.
const string* GetCSDVersion();
// If a CPU vendor string can be determined, returns a pointer to it,
// otherwise, returns NULL. CPU vendor strings can be determined from
// x86 CPUs with CPUID 0.
const string* GetCPUVendor();
// Print a human-readable representation of the object to stdout.
void Print();
protected:
explicit MinidumpSystemInfo(Minidump* minidump);
MDRawSystemInfo system_info_;
// Textual representation of the OS service pack, for minidumps produced
// by MiniDumpWriteDump on Windows.
const string* csd_version_;
private:
friend class Minidump;
static const uint32_t kStreamType = MD_SYSTEM_INFO_STREAM;
bool Read(uint32_t expected_size);
// A string identifying the CPU vendor, if known.
const string* cpu_vendor_;
};
// MinidumpMiscInfo wraps MDRawMiscInfo and provides information about
// the process that generated the minidump, and optionally additional system
// information. See also MinidumpSystemInfo.
class MinidumpMiscInfo : public MinidumpStream {
public:
const MDRawMiscInfo* misc_info() const {
return valid_ ? &misc_info_ : NULL;
}
// Print a human-readable representation of the object to stdout.
void Print();
private:
friend class Minidump;
static const uint32_t kStreamType = MD_MISC_INFO_STREAM;
explicit MinidumpMiscInfo(Minidump* minidump_);
bool Read(uint32_t expected_size_);
MDRawMiscInfo misc_info_;
// Populated by Read. Contains the converted strings from the corresponding
// UTF-16 fields in misc_info_
string standard_name_;
string daylight_name_;
string build_string_;
string dbg_bld_str_;
};
// MinidumpBreakpadInfo wraps MDRawBreakpadInfo, which is an optional stream in
// a minidump that provides additional information about the process state
// at the time the minidump was generated.
class MinidumpBreakpadInfo : public MinidumpStream {
public:
const MDRawBreakpadInfo* breakpad_info() const {
return valid_ ? &breakpad_info_ : NULL;
}
// These thread IDs are used to determine if threads deserve special
// treatment, so special getters are provided to retrieve this data from
// the MDRawBreakpadInfo structure. The getters return false if the thread
// IDs cannot be determined.
bool GetDumpThreadID(uint32_t *thread_id) const;
bool GetRequestingThreadID(uint32_t *thread_id) const;
// Print a human-readable representation of the object to stdout.
void Print();
private:
friend class Minidump;
static const uint32_t kStreamType = MD_BREAKPAD_INFO_STREAM;
explicit MinidumpBreakpadInfo(Minidump* minidump_);
bool Read(uint32_t expected_size_);
MDRawBreakpadInfo breakpad_info_;
};
// MinidumpMemoryInfo wraps MDRawMemoryInfo, which provides information
// about mapped memory regions in a process, including their ranges
// and protection.
class MinidumpMemoryInfo : public MinidumpObject {
public:
const MDRawMemoryInfo* info() const { return valid_ ? &memory_info_ : NULL; }
// The address of the base of the memory region.
uint64_t GetBase() const { return valid_ ? memory_info_.base_address : 0; }
// The size, in bytes, of the memory region.
uint64_t GetSize() const { return valid_ ? memory_info_.region_size : 0; }
// Return true if the memory protection allows execution.
bool IsExecutable() const;
// Return true if the memory protection allows writing.
bool IsWritable() const;
// Print a human-readable representation of the object to stdout.
void Print();
private:
// These objects are managed by MinidumpMemoryInfoList.
friend class MinidumpMemoryInfoList;
explicit MinidumpMemoryInfo(Minidump* minidump);
// This works like MinidumpStream::Read, but is driven by
// MinidumpMemoryInfoList. No size checking is done, because
// MinidumpMemoryInfoList handles that directly.
bool Read();
MDRawMemoryInfo memory_info_;
};
// MinidumpMemoryInfoList contains a list of information about
// mapped memory regions for a process in the form of MDRawMemoryInfo.
// It maintains a map of these structures so that it may easily provide
// info corresponding to a specific address.
class MinidumpMemoryInfoList : public MinidumpStream {
public:
virtual ~MinidumpMemoryInfoList();
unsigned int info_count() const { return valid_ ? info_count_ : 0; }
const MinidumpMemoryInfo* GetMemoryInfoForAddress(uint64_t address) const;
const MinidumpMemoryInfo* GetMemoryInfoAtIndex(unsigned int index) const;
// Print a human-readable representation of the object to stdout.
void Print();
private:
friend class Minidump;
typedef vector<MinidumpMemoryInfo> MinidumpMemoryInfos;
static const uint32_t kStreamType = MD_MEMORY_INFO_LIST_STREAM;
explicit MinidumpMemoryInfoList(Minidump* minidump);
bool Read(uint32_t expected_size);
// Access to memory info using addresses as the key.
RangeMap<uint64_t, unsigned int> *range_map_;
MinidumpMemoryInfos* infos_;
uint32_t info_count_;
};
// Minidump is the user's interface to a minidump file. It wraps MDRawHeader
// and provides access to the minidump's top-level stream directory.
class Minidump {
public:
// path is the pathname of a file containing the minidump.
explicit Minidump(const string& path);
// input is an istream wrapping minidump data. Minidump holds a
// weak pointer to input, and the caller must ensure that the stream
// is valid as long as the Minidump object is.
explicit Minidump(std::istream& input);
virtual ~Minidump();
// path may be empty if the minidump was not opened from a file
virtual string path() const {
return path_;
}
static void set_max_streams(uint32_t max_streams) {
max_streams_ = max_streams;
}
static uint32_t max_streams() { return max_streams_; }
static void set_max_string_length(uint32_t max_string_length) {
max_string_length_ = max_string_length;
}
static uint32_t max_string_length() { return max_string_length_; }
virtual const MDRawHeader* header() const { return valid_ ? &header_ : NULL; }
// Reads the CPU information from the system info stream and generates the
// appropriate CPU flags. The returned context_cpu_flags are the same as
// if the CPU type bits were set in the context_flags of a context record.
// On success, context_cpu_flags will have the flags that identify the CPU.
// If a system info stream is missing, context_cpu_flags will be 0.
// Returns true if the current position in the stream was not changed.
// Returns false when the current location in the stream was changed and the
// attempt to restore the original position failed.
bool GetContextCPUFlagsFromSystemInfo(uint32_t* context_cpu_flags);
// Reads the minidump file's header and top-level stream directory.
// The minidump is expected to be positioned at the beginning of the
// header. Read() sets up the stream list and map, and validates the
// Minidump object.
virtual bool Read();
// The next set of methods are stubs that call GetStream. They exist to
// force code generation of the templatized API within the module, and
// to avoid exposing an ugly API (GetStream needs to accept a garbage
// parameter).
virtual MinidumpThreadList* GetThreadList();
MinidumpModuleList* GetModuleList();
virtual MinidumpMemoryList* GetMemoryList();
MinidumpException* GetException();
MinidumpAssertion* GetAssertion();
virtual MinidumpSystemInfo* GetSystemInfo();
MinidumpMiscInfo* GetMiscInfo();
MinidumpBreakpadInfo* GetBreakpadInfo();
MinidumpMemoryInfoList* GetMemoryInfoList();
// The next set of methods are provided for users who wish to access
// data in minidump files directly, while leveraging the rest of
// this class and related classes to handle the basic minidump
// structure and known stream types.
unsigned int GetDirectoryEntryCount() const {
return valid_ ? header_.stream_count : 0;
}
const MDRawDirectory* GetDirectoryEntryAtIndex(unsigned int index) const;
// The next 2 methods are lower-level I/O routines. They use fd_.
// Reads count bytes from the minidump at the current position into
// the storage area pointed to by bytes. bytes must be of sufficient
// size. After the read, the file position is advanced by count.
bool ReadBytes(void* bytes, size_t count);
// Sets the position of the minidump file to offset.
bool SeekSet(off_t offset);
// Returns the current position of the minidump file.
off_t Tell();
// The next 2 methods are medium-level I/O routines.
// ReadString returns a string which is owned by the caller! offset
// specifies the offset that a length-encoded string is stored at in the
// minidump file.
string* ReadString(off_t offset);
// SeekToStreamType positions the file at the beginning of a stream
// identified by stream_type, and informs the caller of the stream's
// length by setting *stream_length. Because stream_map maps each stream
// type to only one stream in the file, this might mislead the user into
// thinking that the stream that this seeks to is the only stream with
// type stream_type. That can't happen for streams that these classes
// deal with directly, because they're only supposed to be present in the
// file singly, and that's verified when stream_map_ is built. Users who
// are looking for other stream types should be aware of this
// possibility, and consider using GetDirectoryEntryAtIndex (possibly
// with GetDirectoryEntryCount) if expecting multiple streams of the same
// type in a single minidump file.
bool SeekToStreamType(uint32_t stream_type, uint32_t* stream_length);
bool swap() const { return valid_ ? swap_ : false; }
// Print a human-readable representation of the object to stdout.
void Print();
private:
// MinidumpStreamInfo is used in the MinidumpStreamMap. It lets
// the Minidump object locate interesting streams quickly, and
// provides a convenient place to stash MinidumpStream objects.
struct MinidumpStreamInfo {
MinidumpStreamInfo() : stream_index(0), stream(NULL) {}
~MinidumpStreamInfo() { delete stream; }
// Index into the MinidumpDirectoryEntries vector
unsigned int stream_index;
// Pointer to the stream if cached, or NULL if not yet populated
MinidumpStream* stream;
};
typedef vector<MDRawDirectory> MinidumpDirectoryEntries;
typedef map<uint32_t, MinidumpStreamInfo> MinidumpStreamMap;
template<typename T> T* GetStream(T** stream);
// Opens the minidump file, or if already open, seeks to the beginning.
bool Open();
// The largest number of top-level streams that will be read from a minidump.
// Note that streams are only read (and only consume memory) as needed,
// when directed by the caller. The default is 128.
static uint32_t max_streams_;
// The maximum length of a UTF-16 string that will be read from a minidump
// in 16-bit words. The default is 1024. UTF-16 strings are converted
// to UTF-8 when stored in memory, and each UTF-16 word will be represented
// by as many as 3 bytes in UTF-8.
static unsigned int max_string_length_;
MDRawHeader header_;
// The list of streams.
MinidumpDirectoryEntries* directory_;
// Access to streams using the stream type as the key.
MinidumpStreamMap* stream_map_;
// The pathname of the minidump file to process, set in the constructor.
// This may be empty if the minidump was opened directly from a stream.
const string path_;
// The stream for all file I/O. Used by ReadBytes and SeekSet.
// Set based on the path in Open, or directly in the constructor.
std::istream* stream_;
// swap_ is true if the minidump file should be byte-swapped. If the
// minidump was produced by a CPU that is other-endian than the CPU
// processing the minidump, this will be true. If the two CPUs are
// same-endian, this will be false.
bool swap_;
// Validity of the Minidump structure, false immediately after
// construction or after a failed Read(); true following a successful
// Read().
bool valid_;
};
} // namespace google_breakpad
#endif // GOOGLE_BREAKPAD_PROCESSOR_MINIDUMP_H__
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