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356 lines
17 KiB
Markdown
356 lines
17 KiB
Markdown
# Developer's Guide
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## Environment
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* Primary Language: [Java][java]
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* Secondary Languages: [C++][cpp], [Sleigh][sleigh], [Jython][jython]
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* Integrated Development Environment: [Eclipse][eclipse]
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* Build System: [Gradle][gradle]
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* Source Control: [Git][git]
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For specific information on required versions and download links please see the
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[README.md](README.md) file.
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## Quickstart
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Follow the [Advanced Development](README.md#advanced-development) instructions in the [
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README.md](README.md) file to get your development environment setup quickly.
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## Licensing and Copyright
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* Primary License: [Apache License 2.0][apache]
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* Secondary Licenses: [See licenses directory](licenses)
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If possible please try to stick to the [Apache License 2.0][apache]
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license when developing for Ghidra. At times it may be necessary to incorporate other compatible
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licenses into Ghidra. Any GPL code must live in the top-level `GPL/` directory as a totally
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standalone, independently buildable Ghidra module.
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If you are contributing code to the Ghidra project, the preferred way to receive credit/recognition
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is Git commit authorship. Please ensure your Git credentials are properly linked to your GitHub
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account so you appear as a Ghidra contributor on GitHub. We do not have a standard for putting
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authors' names directly in the source code, so it is discouraged.
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## Common Gradle Tasks
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Download non-Maven Central dependencies. This creates a `dependencies` directory in the repository
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root.
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```
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gradle -I gradle/support/fetchDependencies.gradle
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```
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Download Maven Central dependencies and setup the repository for development. By default, these
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will be stored at `$HOME/.gradle/`.
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```
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gradle prepdev
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```
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Generate nested Eclipse project files which can then be imported into Eclipse as "existing
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projects".
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```
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gradle cleanEclipse eclipse
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```
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Build native components for your current platform. Requires native tool chains to be present.
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```
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gradle buildNatives
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```
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Manually compile sleigh files. Ghidra will also do this at runtime when necessary.
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```
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gradle sleighCompile
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```
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Build Javadoc:
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```
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gradle createJavadocs
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```
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Build Python3 packages for the Debugger:
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```
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gradle buildPyPackage
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```
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Build Ghidra to `build/dist` in an uncompressed form. This will be a distribution intended only to
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run on the platform on which it was built.
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```
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gradle assembleAll
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```
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Build Ghidra to `build/dist` in a compressed form. This will be a distribution intended only to run
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on the platform on which it was built.
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```
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gradle buildGhidra
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```
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**Tip:** You may want to skip certain Gradle tasks to speed up your build, or to deal with
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a problem later. For example, perhaps you added some new source files and the build is failing
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because of unresolved IP header issues. You can use the Gradle `-x <task>` command line argument to
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prevent specific tasks from running:
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```
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gradle buildGhidra -x ip
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```
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## Known Issues
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* There is a known issue in Gradle that can prevent it from discovering native toolchains on Linux
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if a non-English system locale is being used. As a workaround, set the following environment
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variable prior to running your Gradle task: `LC_MESSAGES=en_US.UTF-8`
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## Offline Development Environment
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Sometimes you may want to move the Ghidra repository to an offline network and do development there.
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These are the recommended steps to ensure that you not only move the source repository, but all
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downloaded dependencies as well:
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1. `gradle -I gradle/support/fetchDependencies.gradle`
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2. `gradle -g dependencies/gradle prepdev`
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3. Move ghidra directory to different system
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4. `gradle -g dependencies/gradle buildGhidra` (on offline system)
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**NOTE**: The `-g` flag specifies the Gradle user home directory. The default is the `.gradle`
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directory in the user’s home directory. Overriding it to be inside the Ghidra repository will
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ensure that all maven central dependencies that were fetched during the `prepdev` task will be moved
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along with the rest of the repo.
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## Developing GhidraDev Eclipse Plugin
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Developing the GhidraDev Eclipse plugin requires the
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_Eclipse PDE (Plug-in Development Environment)_, which can be installed via the Eclipse marketplace.
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It is also included in the _Eclipse IDE for RCP and RAP Developers_. To generate the GhidraDev
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Eclipse projects, execute:
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```
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gradle eclipse -PeclipsePDE
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```
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Import the newly generated GhidraDev projects into an Eclipse that supports this type of project.
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__Note:__ If you are getting compilation errors related to PyDev and CDT, go into Eclipse's
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preferences, and under _Target Platform_, activate _/Eclipse GhidraDevPlugin/GhidraDev.target_.
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See [Building GhidraDev](GhidraBuild/EclipsePlugins/GhidraDev/GhidraDevPlugin/README.md#building)
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for instructions on how to build the GhidraDev plugin.
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## Running tests
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To run unit tests, do:
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```
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gradle unitTestReport
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```
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For more complex integration tests, do:
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```
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gradle integrationTest
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```
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For running both unit and integration tests and to generate a report do:
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```
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gradle combinedTestReport
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```
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## Setup build in CI
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For running tests in headless mode on Linux, in a CI environment, or in Docker, first do:
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```
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Xvfb :99 -nolisten tcp &
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export DISPLAY=:99
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```
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This is required to make AWT happy.
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## Building Supporting Data
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Some features of Ghidra require the curation of rather extensive databases. These include the Data
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Type Archives and Function ID Databases, both of which require collecting header files and libraries
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for the relevant SDKs and platforms. Much of this work is done by hand. The archives included in our
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official builds can be found in the [ghidra-data] repository.
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### Building Data Type Archives
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This task is often done manually from the Ghidra GUI, and the archives included in our official
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build require a fair bit of fine tuning.
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1. From the CodeBrowser, select __File -> Parse C Source__
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2. From here you can create and configure
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parsing profiles, which lists headers and pre-processor options.
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3. Click _Parse to File_ to create the Data Type Archive.
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4. The result can be added to an installation or source tree by copying it to
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`Ghidra/Features/Base/data/typeinfo`.
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### Building FID Databases
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This task is often done manually from the Ghidra GUI, and the archives included in our official
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build require a fair bit of fine tuning. You will first need to import the relevant libraries from
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which you'd like to produce a FID database. This is often a set of libraries from an SDK. We include
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a variety of Visual Studio platforms in the official build. The official .fidb files can be found in
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the [ghidra-data][ghidra-data] repository.
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1. From the CodeBrowser, select __File -> Configure__
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2. Enable the "Function ID" plugins, and close the dialog.
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3. From the CodeBrowser, select __Tools -> Function ID -> Create new empty FidDb__.
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4. Choose a destination file.
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5. Select __Tools -> Function ID -> Populate FidDb__ from programs.
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6. Fill out the options appropriately and click OK.
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If you'd like some details of our fine tuning, take a look at [building_fid.txt](Ghidra/Features/FunctionID/data/building_fid.txt).
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## Debugger Development
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We have recently changed the Debugger's back-end architecture.
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We no longer user JNA to access native Debugger APIs.
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We only use it for pseudo-terminal access.
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Instead, we use Python3 and a protobuf-based TCP connection for back-end integration.
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### Additional Dependencies
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In addition to Ghidra's normal dependencies, you may want the following:
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* WinDbg for Windows x64
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* GDB 13 or later for Linux
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* LLDB 10 or later for macOS
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The others (e.g., JNA) are handled by Gradle via Maven Central.
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### Architecture Overview
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There are several Eclipse projects each fitting into a larger architectural picture.
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These all currently reside in the `Ghidra/Debug` directory, but will likely be re-factored into the
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`Framework` and `Feature` directories later. Each project is listed "bottom up" with a brief
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description and status.
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* ProposedUtils - a collection of utilities proposed to be moved to other respective projects.
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* AnnotationValidator - an experimental annotation processor for database access objects.
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* Framework-TraceModeling - a database schema and set of interfaces for storing machine state over
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time.
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* Framework-AsyncComm - a collection of utilities for asynchronous communication (packet formats
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and completable-future conveniences).
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* Framework-Debugging - specifies interfaces for debugger models and provides implementation
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conveniences. This is mostly deprecated.
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* Debugger - the collection of Ghidra plugins and services comprising the Debugger UI.
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* Debugger-rmi-trace - the wire protocol, client, services, and UI components for Trace RMI, the new back-end architecture.
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* Debugger-agent-dbgeng - the connector for WinDbg (via dbgeng.dll) on Windows x64.
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* Debugger-agent-dbgmodel - an experimental connector for WinDbg Preview (with TTD, via
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dbgmodel.dll) on Windows x64. This is deprecated, as most of these features are implemented in Debugger-agent-dbgeng for the new architecture.
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* Debugger-agent-dbgmodel-traceloader - an experimental "importer" for WinDbg trace files. This is deprecated.
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* Debugger-agent-gdb - the connector for GDB (13 or later recommended) on UNIX.
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* Debugger-swig-lldb - the Java language bindings for LLDB's SBDebugger, also proposed upstream. This is deprecated. We now use the Python3 language bindings for LLDB.
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* Debugger-agent-lldb - the connector for LLDB (10 or later recommended) on macOS, UNIX, and Windows.
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* Debugger-gadp - the connector for our custom wire protocol the Ghidra Asynchronous Debugging
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Protocol. This is deprecated. It's replaced by Debugger-rmi-trace.
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* Debugger-jpda - an in-development connector for Java and Dalvik debugging via JDI (i.e., JDWP). This is deprecated and not yet replaced.
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The Trace Modeling schema records machine state and markup over time.
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It rests on the same database framework as Programs, allowing trace recordings to be stored in a Ghidra project and shared via a server, if desired.
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Trace "recording" is a de facto requirement for displaying information in Ghidra's UI.
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The back-end connector has full discretion over what is recorded by using Trace RMI.
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Typically, only the machine state actually observed by the user (or perhaps a script) is recorded.
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For most use cases, the Trace is small and ephemeral, serving only to mediate between the UI components and the target's model.
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It supports many of the same markup (e.g., disassembly, data types) as Programs, in addition to tracking active threads, loaded modues, breakpoints, etc.
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Every back end (or "adapter" or "connector" or "agent") employs the Trace RMI client to populate a trace database.
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As a general rule in Ghidra, no component is allowed to access a native API and reside in the same JVM as the Ghidra UI.
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This allows us to contain crashes, preventing data loss.
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To accommodate this requirement — given that debugging native applications is almost certainly going to require access to native APIs — we've developed the Trace RMI protocol.
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This also allows us to better bridge the language gap between Java and Python, which is supported by most native debuggers.
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This protocol is loosely coupled to Framework-TraceModeling, essentially exposing its methods via RMI, as well as some methods for controlling the UI.
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The protocol is built using Google's Protobuf library, providing a potential path for back-end implementations in alternative languages.
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We provide the Trace RMI server as a Ghidra component implemented in Java and the Trace RMI client as a Python3 package.
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A back-end implementation may be a stand-alone executable or script that accesses the native debugger's API, or a script or plugin for the native debugger.
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It then connects to Ghidra via Trace RMI to populate the trace database with information gleaned from that API.
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It should provide a set of diagnostic commands to control and monitor that connection.
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It should also use the native API to detect session and target changes so that Ghidra's UI consistently reflects the debugging session.
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The old system relied on a "recorder" to discover targets and map them to traces in the proper Ghidra language.
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That responsibility is now delegated to the back end.
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Typically, it examines the target's architecture and immediately creates a trace upon connection.
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### Developing a new connector
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So Ghidra does not yet support your favorite debugger?
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We believe the new system is much less daunting than the previous.
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Still, please finish reading this guide, and look carefully at the ones we have so far, and perhaps ask to see if we are already developing one.
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Of course, in time you might also search the internet to see if others are developing one.
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There are quite a few caveats and gotchas, the most notable being that this interface is still in some flux.
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When things go wrong, it could be because of, without limitation:
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1. A bug on your part
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2. A bug on our part
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3. A design flaw in the interfaces
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4. A bug in the debugger/API you're adapting
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We are still (yes, still) in the process of writing up this documentation.
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In the meantime, we recommend using the GDB and dbgeng agents as examples.
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Be sure to look at the Python code `src/main/py`!
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The deprecated Java code `src/main/java` is still included as we transition.
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You'll also need to provide launcher(s) so that Ghidra knows how to configure and start your connector.
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These are just shell scripts.
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We use bash scripts on Linux and macOS, and we use batch files on Windows.
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Try to include as many common use cases as makes sense for the debugger.
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This provides the most flexibility to users and examples to power users who might create derivative launchers.
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Look at the existing launchers for examples.
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For testing, please follow the examples for GDB.
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We no longer provide abstract classes that prescribe requirements.
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Instead, we just provide GDB as an example.
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Usually, we split our tests into three categories:
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* Commands
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* Methods
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* Hooks
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The Commands tests check that the user CLI commands, conventionally implemented in `commands.py`, work correctly.
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In general, do the minimum connection setup, execute the command, and check that it produces the expected output and causes the expected effects.
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The Methods tests check that the remote methods, conventionally implemented in `methods.py`, work correctly.
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Many methods are just wrappers around CLI commands, some provided by the native debugger and some provided by `commands.py`.
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These work similarly to the commands test, except that they invoke methods instead of executing commands.
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Again, check the return value (rarely applicable) and that it causes the expected effects.
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The Hooks tests check that the back end is able to listen for session and target changes, e.g., knowing when the target stops.
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*The test should not "cheat" by executing commands or invoking methods that should instead be triggered by the listener.*
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It should execute the minimal commands to setup the test, then trigger an event.
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It should then check that the event in turn triggered the expected effects, e.g., updating PC upon the target stopping.
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Whenever you make a change to the Python code, you'll need to re-assemble the package's source.
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```
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gradle assemblePyPackage
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```
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This is required in case your package includes generated source, as is the case for Debugger-rmi-trace.
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If you want to create a new Ghidra module for your connector (recommended) use an existing one's `build.gradle` as a template.
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A key part is applying the `hasPythonPackage.gradle` script.
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### Adding a new platform
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If a connector already exists for a suitable debugger on the desired platform, then adding it may be very simple.
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For example, many platforms are supported by GDB, so even though we're currently focused on x86-64 (and to some extent arm64) support, we've provided the mappings for many.
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These mappings are conventionally kept in each connector's `arch.py` file.
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In general, to update `arch.py`, you need to know:
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1. What the platform is called (including variant names) by the debugger
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2. What the processor language is called by Ghidra
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3. If applicable, the mapping of target address spaces into Ghidra's address spaces
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4. If applicable, the mapping of target register names to those in Ghidra's processor language
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In most cases (3) and (4) are already implemented by the included mappers.
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Naturally, you'll want to test the special cases, preferably in automated tests.
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### Emulation
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The most obvious integration path for 3rd-party emulators is to write a "connector."
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However, p-code emulation is an integral feature of the Ghidra UI, and it has a fairly accessible API.
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Namely, for interpolation between machines states recorded in a trace, and extrapolation into future machine states.
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Integration of such emulators may still be useful to you, but we recommend trying the p-code emulator to see if it suits your needs for emulation in Ghidra before pursuing integration of another emulator.
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We also provide out-of-the-box QEMU integration via GDB.
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### Contributing
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When submitting help tickets and pull requests, please tag those related to the debugger with "Debugger" so that we can triage them more quickly.
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[java]: https://dev.java
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[cpp]: https://isocpp.org
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[sleigh]: https://htmlpreview.github.io/?https://github.com/NationalSecurityAgency/ghidra/blob/master/GhidraDocs/languages/index.html
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[jython]: https://www.jython.org
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[eclipse]: https://www.eclipse.org/downloads/
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[gradle]: https://gradle.org
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[git]: https://git-scm.com
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[apache]: https://www.apache.org/licenses/LICENSE-2.0
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[fork]: https://docs.github.com/en/get-started/quickstart/fork-a-repo
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[ghidra-data]: https://github.com/NationalSecurityAgency/ghidra-data
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[DbgGuide]: DebuggerDevGuide.md
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