src/client/mac/handler/dynamic_images.h - nest-cam/v350/breakpad - Git at Google

 // Copyright (c) 2007, 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.

 //  dynamic_images.h
 //
 //    Implements most of the function of the dyld API, but allowing an
 //    arbitrary task to be introspected, unlike the dyld API which
 //    only allows operation on the current task.  The current implementation
 //    is limited to use by 32-bit tasks.

 #ifndef CLIENT_MAC_HANDLER_DYNAMIC_IMAGES_H__
 #define CLIENT_MAC_HANDLER_DYNAMIC_IMAGES_H__

 #include <mach/mach.h>
 #include <mach-o/dyld.h>
 #include <mach-o/loader.h>
 #include <sys/types.h>

 #include <string>
 #include <vector>

 #include "mach_vm_compat.h"

 namespace google_breakpad {

 using std::string;
 using std::vector;

 //==============================================================================
 // The memory layout of this struct matches the dyld_image_info struct
 // defined in "dyld_gdb.h" in the darwin source.
 typedef struct dyld_image_info32 {
   uint32_t                   load_address_;  // struct mach_header*
   uint32_t                   file_path_;     // char*
   uint32_t                   file_mod_date_;
 } dyld_image_info32;

 typedef struct dyld_image_info64 {
   uint64_t                   load_address_;  // struct mach_header*
   uint64_t                   file_path_;     // char*
   uint64_t                   file_mod_date_;
 } dyld_image_info64;

 //==============================================================================
 // This is as defined in "dyld_gdb.h" in the darwin source.
 // _dyld_all_image_infos (in dyld) is a structure of this type
 // which will be used to determine which dynamic code has been loaded.
 typedef struct dyld_all_image_infos32 {
   uint32_t                      version;  // == 1 in Mac OS X 10.4
   uint32_t                      infoArrayCount;
   uint32_t                      infoArray;  // const struct dyld_image_info*
   uint32_t                      notification;
   bool                          processDetachedFromSharedRegion;
 } dyld_all_image_infos32;

 typedef struct dyld_all_image_infos64 {
   uint32_t                      version;  // == 1 in Mac OS X 10.4
   uint32_t                      infoArrayCount;
   uint64_t                      infoArray;  // const struct dyld_image_info*
   uint64_t                      notification;
   bool                          processDetachedFromSharedRegion;
 } dyld_all_image_infos64;

 // some typedefs to isolate 64/32 bit differences
 #ifdef __LP64__
 typedef mach_header_64 breakpad_mach_header;
 typedef segment_command_64 breakpad_mach_segment_command;
 #else
 typedef mach_header breakpad_mach_header;
 typedef segment_command breakpad_mach_segment_command;
 #endif

 // Helper functions to deal with 32-bit/64-bit Mach-O differences.
 class DynamicImage;
 template<typename MachBits>
 bool FindTextSection(DynamicImage& image);

 template<typename MachBits>
 uint32_t GetFileTypeFromHeader(DynamicImage& image);

 //==============================================================================
 // Represents a single dynamically loaded mach-o image
 class DynamicImage {
  public:
   DynamicImage(uint8_t* header,     // data is copied
                size_t header_size,  // includes load commands
                uint64_t load_address,
                string file_path,
                uintptr_t image_mod_date,
                mach_port_t task,
                cpu_type_t cpu_type)
     : header_(header, header + header_size),
       header_size_(header_size),
       load_address_(load_address),
       vmaddr_(0),
       vmsize_(0),
       slide_(0),
       version_(0),
       file_path_(file_path),
       file_mod_date_(image_mod_date),
       task_(task),
       cpu_type_(cpu_type) {
     CalculateMemoryAndVersionInfo();
   }

   // Size of mach_header plus load commands
   size_t GetHeaderSize() const {return header_.size();}

   // Full path to mach-o binary
   string GetFilePath() {return file_path_;}

   uint64_t GetModDate() const {return file_mod_date_;}

   // Actual address where the image was loaded
   uint64_t GetLoadAddress() const {return load_address_;}

   // Address where the image should be loaded
   mach_vm_address_t GetVMAddr() const {return vmaddr_;}

   // Difference between GetLoadAddress() and GetVMAddr()
   ptrdiff_t GetVMAddrSlide() const {return slide_;}

   // Size of the image
   mach_vm_size_t GetVMSize() const {return vmsize_;}

   // Task owning this loaded image
   mach_port_t GetTask() {return task_;}

   // CPU type of the task
   cpu_type_t GetCPUType() {return cpu_type_;}

   // filetype from the Mach-O header.
   uint32_t GetFileType();

   // Return true if the task is a 64-bit architecture.
   bool Is64Bit() { return (GetCPUType() & CPU_ARCH_ABI64) == CPU_ARCH_ABI64; }

   uint32_t GetVersion() {return version_;}
   // For sorting
   bool operator<(const DynamicImage& inInfo) {
     return GetLoadAddress() < inInfo.GetLoadAddress();
   }

   // Sanity checking
   bool IsValid() {return GetVMSize() != 0;}

  private:
   DynamicImage(const DynamicImage&);
   DynamicImage& operator=(const DynamicImage&);

   friend class DynamicImages;
   template<typename MachBits>
   friend bool FindTextSection(DynamicImage& image);
   template<typename MachBits>
   friend uint32_t GetFileTypeFromHeader(DynamicImage& image);

   // Initializes vmaddr_, vmsize_, and slide_
   void CalculateMemoryAndVersionInfo();

   const vector<uint8_t>   header_;        // our local copy of the header
   size_t                  header_size_;    // mach_header plus load commands
   uint64_t                load_address_;   // base address image is mapped into
   mach_vm_address_t       vmaddr_;
   mach_vm_size_t          vmsize_;
   ptrdiff_t               slide_;
   uint32_t                version_;        // Dylib version
   string                  file_path_;     // path dyld used to load the image
   uintptr_t               file_mod_date_;  // time_t of image file

   mach_port_t             task_;
   cpu_type_t              cpu_type_;        // CPU type of task_
 };

 //==============================================================================
 // DynamicImageRef is just a simple wrapper for a pointer to
 // DynamicImage.  The reason we use it instead of a simple typedef is so
 // that we can use stl::sort() on a vector of DynamicImageRefs
 // and simple class pointers can't implement operator<().
 //
 class DynamicImageRef {
  public:
   explicit DynamicImageRef(DynamicImage* inP) : p(inP) {}
   // The copy constructor is required by STL
   DynamicImageRef(const DynamicImageRef& inRef) : p(inRef.p) {}

   bool operator<(const DynamicImageRef& inRef) const {
     return (*const_cast<DynamicImageRef*>(this)->p)
       < (*const_cast<DynamicImageRef&>(inRef).p);
   }

   bool operator==(const DynamicImageRef& inInfo) const {
     return (*const_cast<DynamicImageRef*>(this)->p).GetLoadAddress() ==
         (*const_cast<DynamicImageRef&>(inInfo)).GetLoadAddress();
   }

   // Be just like DynamicImage*
   DynamicImage* operator->() {return p;}
   operator DynamicImage*() {return p;}

  private:
   DynamicImage* p;
 };

 // Helper function to deal with 32-bit/64-bit Mach-O differences.
 class DynamicImages;
 template<typename MachBits>
 void ReadImageInfo(DynamicImages& images, uint64_t image_list_address);

 //==============================================================================
 // An object of type DynamicImages may be created to allow introspection of
 // an arbitrary task's dynamically loaded mach-o binaries.  This makes the
 // assumption that the current task has send rights to the target task.
 class DynamicImages {
  public:
   explicit DynamicImages(mach_port_t task);

   ~DynamicImages() {
     for (int i = 0; i < GetImageCount(); ++i) {
       delete image_list_[i];
     }
   }

   // Returns the number of dynamically loaded mach-o images.
   int GetImageCount() const {return static_cast<int>(image_list_.size());}

   // Returns an individual image.
   DynamicImage* GetImage(int i) {
     if (i < (int)image_list_.size()) {
       return image_list_[i];
     }
     return NULL;
   }

   // Returns the image corresponding to the main executable.
   DynamicImage* GetExecutableImage();
   int GetExecutableImageIndex();

   // Returns the task which we're looking at.
   mach_port_t GetTask() const {return task_;}

   // CPU type of the task
   cpu_type_t GetCPUType() {return cpu_type_;}

   // Return true if the task is a 64-bit architecture.
   bool Is64Bit() { return (GetCPUType() & CPU_ARCH_ABI64) == CPU_ARCH_ABI64; }

   // Determine the CPU type of the task being dumped.
   static cpu_type_t DetermineTaskCPUType(task_t task);

   // Get the native CPU type of this task.
   static cpu_type_t GetNativeCPUType() {
 #if defined(__i386__)
     return CPU_TYPE_I386;
 #elif defined(__x86_64__)
     return CPU_TYPE_X86_64;
 #elif defined(__ppc__)
     return CPU_TYPE_POWERPC;
 #elif defined(__ppc64__)
     return CPU_TYPE_POWERPC64;
 #elif defined(__arm__)
     return CPU_TYPE_ARM;
 #elif defined(__aarch64__)
     return CPU_TYPE_ARM64;
 #else
 #error "GetNativeCPUType not implemented for this architecture"
 #endif
   }

  private:
   template<typename MachBits>
   friend void ReadImageInfo(DynamicImages& images, uint64_t image_list_address);

   bool IsOurTask() {return task_ == mach_task_self();}

   // Initialization
   void ReadImageInfoForTask();
   uint64_t GetDyldAllImageInfosPointer();

   mach_port_t              task_;
   cpu_type_t               cpu_type_;  // CPU type of task_
   vector<DynamicImageRef>  image_list_;
 };

 // Fill bytes with the contents of memory at a particular
 // location in another task.
 kern_return_t ReadTaskMemory(task_port_t target_task,
                              const uint64_t address,
                              size_t length,
                              vector<uint8_t>& bytes);

 }   // namespace google_breakpad

 #endif // CLIENT_MAC_HANDLER_DYNAMIC_IMAGES_H__
	// Copyright (c) 2007, 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.

	// dynamic_images.h
	//
	// Implements most of the function of the dyld API, but allowing an
	// arbitrary task to be introspected, unlike the dyld API which
	// only allows operation on the current task. The current implementation
	// is limited to use by 32-bit tasks.

	#ifndef CLIENT_MAC_HANDLER_DYNAMIC_IMAGES_H__
	#define CLIENT_MAC_HANDLER_DYNAMIC_IMAGES_H__

	#include <mach/mach.h>
	#include <mach-o/dyld.h>
	#include <mach-o/loader.h>
	#include <sys/types.h>

	#include <string>
	#include <vector>

	#include "mach_vm_compat.h"

	namespace google_breakpad {

	using std::string;
	using std::vector;

	//==============================================================================
	// The memory layout of this struct matches the dyld_image_info struct
	// defined in "dyld_gdb.h" in the darwin source.
	typedef struct dyld_image_info32 {
	uint32_t load_address_; // struct mach_header*
	uint32_t file_path_; // char*
	uint32_t file_mod_date_;
	} dyld_image_info32;

	typedef struct dyld_image_info64 {
	uint64_t load_address_; // struct mach_header*
	uint64_t file_path_; // char*
	uint64_t file_mod_date_;
	} dyld_image_info64;

	//==============================================================================
	// This is as defined in "dyld_gdb.h" in the darwin source.
	// _dyld_all_image_infos (in dyld) is a structure of this type
	// which will be used to determine which dynamic code has been loaded.
	typedef struct dyld_all_image_infos32 {
	uint32_t version; // == 1 in Mac OS X 10.4
	uint32_t infoArrayCount;
	uint32_t infoArray; // const struct dyld_image_info*
	uint32_t notification;
	bool processDetachedFromSharedRegion;
	} dyld_all_image_infos32;

	typedef struct dyld_all_image_infos64 {
	uint32_t version; // == 1 in Mac OS X 10.4
	uint32_t infoArrayCount;
	uint64_t infoArray; // const struct dyld_image_info*
	uint64_t notification;
	bool processDetachedFromSharedRegion;
	} dyld_all_image_infos64;

	// some typedefs to isolate 64/32 bit differences
	#ifdef __LP64__
	typedef mach_header_64 breakpad_mach_header;
	typedef segment_command_64 breakpad_mach_segment_command;
	#else
	typedef mach_header breakpad_mach_header;
	typedef segment_command breakpad_mach_segment_command;
	#endif

	// Helper functions to deal with 32-bit/64-bit Mach-O differences.
	class DynamicImage;
	template<typename MachBits>
	bool FindTextSection(DynamicImage& image);

	template<typename MachBits>
	uint32_t GetFileTypeFromHeader(DynamicImage& image);

	//==============================================================================
	// Represents a single dynamically loaded mach-o image
	class DynamicImage {
	public:
	DynamicImage(uint8_t* header, // data is copied
	size_t header_size, // includes load commands
	uint64_t load_address,
	string file_path,
	uintptr_t image_mod_date,
	mach_port_t task,
	cpu_type_t cpu_type)
	: header_(header, header + header_size),
	header_size_(header_size),
	load_address_(load_address),
	vmaddr_(0),
	vmsize_(0),
	slide_(0),
	version_(0),
	file_path_(file_path),
	file_mod_date_(image_mod_date),
	task_(task),
	cpu_type_(cpu_type) {
	CalculateMemoryAndVersionInfo();
	}

	// Size of mach_header plus load commands
	size_t GetHeaderSize() const {return header_.size();}

	// Full path to mach-o binary
	string GetFilePath() {return file_path_;}

	uint64_t GetModDate() const {return file_mod_date_;}

	// Actual address where the image was loaded
	uint64_t GetLoadAddress() const {return load_address_;}

	// Address where the image should be loaded
	mach_vm_address_t GetVMAddr() const {return vmaddr_;}

	// Difference between GetLoadAddress() and GetVMAddr()
	ptrdiff_t GetVMAddrSlide() const {return slide_;}

	// Size of the image
	mach_vm_size_t GetVMSize() const {return vmsize_;}

	// Task owning this loaded image
	mach_port_t GetTask() {return task_;}

	// CPU type of the task
	cpu_type_t GetCPUType() {return cpu_type_;}

	// filetype from the Mach-O header.
	uint32_t GetFileType();

	// Return true if the task is a 64-bit architecture.
	bool Is64Bit() { return (GetCPUType() & CPU_ARCH_ABI64) == CPU_ARCH_ABI64; }

	uint32_t GetVersion() {return version_;}
	// For sorting
	bool operator<(const DynamicImage& inInfo) {
	return GetLoadAddress() < inInfo.GetLoadAddress();
	}

	// Sanity checking
	bool IsValid() {return GetVMSize() != 0;}

	private:
	DynamicImage(const DynamicImage&);
	DynamicImage& operator=(const DynamicImage&);

	friend class DynamicImages;
	template<typename MachBits>
	friend bool FindTextSection(DynamicImage& image);
	template<typename MachBits>
	friend uint32_t GetFileTypeFromHeader(DynamicImage& image);

	// Initializes vmaddr_, vmsize_, and slide_
	void CalculateMemoryAndVersionInfo();

	const vector<uint8_t> header_; // our local copy of the header
	size_t header_size_; // mach_header plus load commands
	uint64_t load_address_; // base address image is mapped into
	mach_vm_address_t vmaddr_;
	mach_vm_size_t vmsize_;
	ptrdiff_t slide_;
	uint32_t version_; // Dylib version
	string file_path_; // path dyld used to load the image
	uintptr_t file_mod_date_; // time_t of image file

	mach_port_t task_;
	cpu_type_t cpu_type_; // CPU type of task_
	};

	//==============================================================================
	// DynamicImageRef is just a simple wrapper for a pointer to
	// DynamicImage. The reason we use it instead of a simple typedef is so
	// that we can use stl::sort() on a vector of DynamicImageRefs
	// and simple class pointers can't implement operator<().
	//
	class DynamicImageRef {
	public:
	explicit DynamicImageRef(DynamicImage* inP) : p(inP) {}
	// The copy constructor is required by STL
	DynamicImageRef(const DynamicImageRef& inRef) : p(inRef.p) {}

	bool operator<(const DynamicImageRef& inRef) const {
	return (const_cast<DynamicImageRef>(this)->p)
	< (*const_cast<DynamicImageRef&>(inRef).p);
	}

	bool operator==(const DynamicImageRef& inInfo) const {
	return (const_cast<DynamicImageRef>(this)->p).GetLoadAddress() ==
	(*const_cast<DynamicImageRef&>(inInfo)).GetLoadAddress();
	}

	// Be just like DynamicImage*
	DynamicImage* operator->() {return p;}
	operator DynamicImage*() {return p;}

	private:
	DynamicImage* p;
	};

	// Helper function to deal with 32-bit/64-bit Mach-O differences.
	class DynamicImages;
	template<typename MachBits>
	void ReadImageInfo(DynamicImages& images, uint64_t image_list_address);

	//==============================================================================
	// An object of type DynamicImages may be created to allow introspection of
	// an arbitrary task's dynamically loaded mach-o binaries. This makes the
	// assumption that the current task has send rights to the target task.
	class DynamicImages {
	public:
	explicit DynamicImages(mach_port_t task);

	~DynamicImages() {
	for (int i = 0; i < GetImageCount(); ++i) {
	delete image_list_[i];
	}
	}

	// Returns the number of dynamically loaded mach-o images.
	int GetImageCount() const {return static_cast<int>(image_list_.size());}

	// Returns an individual image.
	DynamicImage* GetImage(int i) {
	if (i < (int)image_list_.size()) {
	return image_list_[i];
	}
	return NULL;
	}

	// Returns the image corresponding to the main executable.
	DynamicImage* GetExecutableImage();
	int GetExecutableImageIndex();

	// Returns the task which we're looking at.
	mach_port_t GetTask() const {return task_;}

	// CPU type of the task
	cpu_type_t GetCPUType() {return cpu_type_;}

	// Return true if the task is a 64-bit architecture.
	bool Is64Bit() { return (GetCPUType() & CPU_ARCH_ABI64) == CPU_ARCH_ABI64; }

	// Determine the CPU type of the task being dumped.
	static cpu_type_t DetermineTaskCPUType(task_t task);

	// Get the native CPU type of this task.
	static cpu_type_t GetNativeCPUType() {
	#if defined(__i386__)
	return CPU_TYPE_I386;
	#elif defined(__x86_64__)
	return CPU_TYPE_X86_64;
	#elif defined(__ppc__)
	return CPU_TYPE_POWERPC;
	#elif defined(__ppc64__)
	return CPU_TYPE_POWERPC64;
	#elif defined(__arm__)
	return CPU_TYPE_ARM;
	#elif defined(__aarch64__)
	return CPU_TYPE_ARM64;
	#else
	#error "GetNativeCPUType not implemented for this architecture"
	#endif
	}

	private:
	template<typename MachBits>
	friend void ReadImageInfo(DynamicImages& images, uint64_t image_list_address);

	bool IsOurTask() {return task_ == mach_task_self();}

	// Initialization
	void ReadImageInfoForTask();
	uint64_t GetDyldAllImageInfosPointer();

	mach_port_t task_;
	cpu_type_t cpu_type_; // CPU type of task_
	vector<DynamicImageRef> image_list_;
	};

	// Fill bytes with the contents of memory at a particular
	// location in another task.
	kern_return_t ReadTaskMemory(task_port_t target_task,
	const uint64_t address,
	size_t length,
	vector<uint8_t>& bytes);

	} // namespace google_breakpad

	#endif // CLIENT_MAC_HANDLER_DYNAMIC_IMAGES_H__