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225 lines
13 KiB
Markdown
225 lines
13 KiB
Markdown
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# Breakpad Client Libraries
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## Objective
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The Breakpad client libraries are responsible for monitoring an application for
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crashes (exceptions), handling them when they occur by generating a dump, and
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providing a means to upload dumps to a crash reporting server. These tasks are
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divided between the “handler” (short for “exception handler”) library linked in
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to an application being monitored for crashes, and the “sender” library,
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intended to be linked in to a separate external program.
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## Background
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As one of the chief tasks of the client handler is to generate a dump, an
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understanding of [dump files](processor_design.md) will aid in understanding the
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handler.
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## Overview
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Breakpad provides client libraries for each of its target platforms. Currently,
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these exist for Windows on x86 and Mac OS X on both x86 and PowerPC. A Linux
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implementation has been written and is currently under review.
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Because the mechanisms for catching exceptions and the methods for obtaining the
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information that a dump contains vary between operating systems, each target
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operating system requires a completely different handler implementation. Where
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multiple CPUs are supported for a single operating system, the handler
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implementation will likely also require separate code for each processor type to
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extract CPU-specific information. One of the goals of the Breakpad handler is to
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provide a prepackaged cross-platform system that masks many of these
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system-level differences and quirks from the application developer. Although the
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underlying implementations differ, the handler library for each system follows
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the same set of principles and exposes a similar interface.
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Code that wishes to take advantage of Breakpad should be linked against the
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handler library, and should, at an appropriate time, install a Breakpad handler.
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For applications, it is generally desirable to install the handler as early in
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the start-up process as possible. Developers of library code using Breakpad to
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monitor itself may wish to install a Breakpad handler when the library is
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loaded, or may only want to install a handler when calls are made in to the
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library.
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The handler can be triggered to generate a dump either by catching an exception
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or at the request of the application itself. The latter case may be useful in
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debugging assertions or other conditions where developers want to know how a
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program got in to a specific non-crash state. After generating a dump, the
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handler calls a user-specified callback function. The callback function may
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collect additional data about the program’s state, quit the program, launch a
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crash reporter application, or perform other tasks. Allowing for this
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functionality to be dictated by a callback function preserves flexibility.
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The sender library is also has a separate implementation for each supported
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platform, because of the varying interfaces for accessing network resources on
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different operating systems. The sender transmits a dump along with other
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application-defined information to a crash report server via HTTP. Because dumps
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may contain sensitive data, the sender allows for the use of HTTPS.
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The canonical example of the entire client system would be for a monitored
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application to link against the handler library, install a Breakpad handler from
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its main function, and provide a callback to launch a small crash reporter
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program. The crash reporter program would be linked against the sender library,
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and would send the crash dump when launched. A separate process is recommended
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for this function because of the unreliability inherent in doing any significant
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amount of work from a crashed process.
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## Detailed Design
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### Exception Handler Installation
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The mechanisms for installing an exception handler vary between operating
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systems. On Windows, it’s a relatively simple matter of making one call to
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register a [top-level exception filter]
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(http://msdn.microsoft.com/library/en-us/debug/base/setunhandledexceptionfilter.asp)
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callback function. On most Unix-like systems such as Linux, processes are
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informed of exceptions by the delivery of a signal, so an exception handler
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takes the form of a signal handler. The native mechanism to catch exceptions on
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Mac OS X requires a large amount of code to set up a Mach port, identify it as
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the exception port, and assign a thread to listen for an exception on that port.
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Just as the preparation of exception handlers differ, the manner in which they
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are called differs as well. On Windows and most Unix-like systems, the handler
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is called on the thread that caused the exception. On Mac OS X, the thread
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listening to the exception port is notified that an exception has occurred. The
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different implementations of the Breakpad handler libraries perform these tasks
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in the appropriate ways on each platform, while exposing a similar interface on
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each.
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A Breakpad handler is embodied in an `ExceptionHandler` object. Because it’s a
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C++ object, `ExceptionHandler`s may be created as local variables, allowing them
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to be installed and removed as functions are called and return. This provides
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one possible way for a developer to monitor only a portion of an application for
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crashes.
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### Exception Basics
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Once an application encounters an exception, it is in an indeterminate and
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possibly hazardous state. Consequently, any code that runs after an exception
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occurs must take extreme care to avoid performing operations that might fail,
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hang, or cause additional exceptions. This task is not at all straightforward,
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and the Breakpad handler library seeks to do it properly, accounting for all of
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the minute details while allowing other application developers, even those with
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little systems programming experience, to reap the benefits. All of the Breakpad
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handler code that executes after an exception occurs has been written according
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to the following guidelines for safety at exception time:
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* Use of the application heap is forbidden. The heap may be corrupt or
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otherwise unusable, and allocators may not function.
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* Resource allocation must be severely limited. The handler may create a new
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file to contain the dump, and it may attempt to launch a process to continue
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handling the crash.
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* Execution on the thread that caused the exception is significantly limited.
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The only code permitted to execute on this thread is the code necessary to
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transition handling to a dedicated preallocated handler thread, and the code
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to return from the exception handler.
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* Handlers shouldn’t handle crashes by attempting to walk stacks themselves,
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as stacks may be in inconsistent states. Dump generation should be performed
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by interfacing with the operating system’s memory manager and code module
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manager.
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* Library code, including runtime library code, must be avoided unless it
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provably meets the above guidelines. For example, this means that the STL
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string class may not be used, because it performs operations that attempt to
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allocate and use heap memory. It also means that many C runtime functions
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must be avoided, particularly on Windows, because of heap operations that
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they may perform.
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A dedicated handler thread is used to preserve the state of the exception thread
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when an exception occurs: during dump generation, it is difficult if not
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impossible for a thread to accurately capture its own state. Performing all
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exception-handling functions on a separate thread is also critical when handling
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stack-limit-exceeded exceptions. It would be hazardous to run out of stack space
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while attempting to handle an exception. Because of the rule against allocating
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resources at exception time, the Breakpad handler library creates its handler
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thread when it installs its exception handler. On Mac OS X, this handler thread
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is created during the normal setup of the exception handler, and the handler
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thread will be signaled directly in the event of an exception. On Windows and
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Linux, the handler thread is signaled by a small amount of code that executes on
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the exception thread. Because the code that executes on the exception thread in
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this case is small and safe, this does not pose a problem. Even when an
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exception is caused by exceeding stack size limits, this code is sufficiently
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compact to execute entirely within the stack’s guard page without causing an
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exception.
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The handler thread may also be triggered directly by a user call, even when no
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exception occurs, to allow dumps to be generated at any point deemed
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interesting.
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### Filter Callback
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When the handler thread begins handling an exception, it calls an optional
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user-defined filter callback function, which is responsible for judging whether
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Breakpad’s handler should continue handling the exception or not. This mechanism
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is provided for the benefit of library or plug-in code, whose developers may not
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be interested in reports of crashes that occur outside of their modules but
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within processes hosting their code. If the filter callback indicates that it is
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not interested in the exception, the Breakpad handler arranges for it to be
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delivered to any previously-installed handler.
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### Dump Generation
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Assuming that the filter callback approves (or does not exist), the handler
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writes a dump in a directory specified by the application developer when the
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handler was installed, using a previously generated unique identifier to avoid
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name collisions. The mechanics of dump generation also vary between platforms,
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but in general, the process involves enumerating each thread of execution, and
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capturing its state, including processor context and the active portion of its
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stack area. The dump also includes a list of the code modules loaded in to the
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application, and an indicator of which thread generated the exception or
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requested the dump. In order to avoid allocating memory during this process, the
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dump is written in place on disk.
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### Post-Dump Behavior
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Upon completion of writing the dump, a second callback function is called. This
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callback may be used to launch a separate crash reporting program or to collect
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additional data from the application. The callback may also be used to influence
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whether Breakpad will treat the exception as handled or unhandled. Even after a
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dump is successfully generated, Breakpad can be made to behave as though it
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didn’t actually handle an exception. This function may be useful for developers
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who want to test their applications with Breakpad enabled but still retain the
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ability to use traditional debugging techniques. It also allows a
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Breakpad-enabled application to coexist with a platform’s native crash reporting
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system, such as Mac OS X’ [CrashReporter]
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(http://developer.apple.com/technotes/tn2004/tn2123.html) and [Windows Error
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Reporting](http://msdn.microsoft.com/isv/resources/wer/).
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Typically, when Breakpad handles an exception fully and no debuggers are
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involved, the crashed process will terminate.
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Authors of both callback functions that execute within a Breakpad handler are
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cautioned that their code will be run at exception time, and that as a result,
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they should observe the same programming practices that the Breakpad handler
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itself adheres to. Notably, if a callback is to be used to collect additional
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data from an application, it should take care to read only “safe” data. This
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might involve accessing only static memory locations that are updated
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periodically during the course of normal program execution.
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### Sender Library
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The Breakpad sender library provides a single function to send a crash report to
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a crash server. It accepts a crash server’s URL, a map of key-value parameters
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that will accompany the dump, and the path to a dump file itself. Each of the
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key-value parameters and the dump file are sent as distinct parts of a multipart
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HTTP POST request to the specified URL using the platform’s native HTTP
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facilities. On Linux, [libcurl](http://curl.haxx.se/) is used for this function,
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as it is the closest thing to a standard HTTP library available on that
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platform.
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## Future Plans
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Although we’ve had great success with in-process dump generation by following
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our guidelines for safe code at exception time, we are exploring options for
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allowing dumps to be generated in a separate process, to further enhance the
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handler library’s robustness.
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On Windows, we intend to offer tools to make it easier for Breakpad’s settings
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to be managed by the native group policy management system.
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We also plan to offer tools that many developers would find desirable in the
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context of handling crashes, such as a mechanism to determine at launch if the
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program last terminated in a crash, and a way to calculate “crashiness” in terms
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of crashes over time or the number of application launches between crashes.
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We are also investigating methods to capture crashes that occur early in an
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application’s launch sequence, including crashes that occur before a program’s
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main function begins executing.
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