## Debugger Visualizers Many languages and debuggers enable developers to control how a type is displayed in a debugger. These are called "debugger visualizations" or "debugger views". The Windows debuggers (WinDbg\CDB) support defining custom debugger visualizations using the `Natvis` framework. To use Natvis, developers write XML documents using the natvis schema that describe how debugger types should be displayed with the `.natvis` extension. (See: https://docs.microsoft.com/en-us/visualstudio/debugger/create-custom-views-of-native-objects?view=vs-2019) The Natvis files provide patterns which match type names a description of how to display those types. The Natvis schema can be found either online (See: https://code.visualstudio.com/docs/cpp/natvis#_schema) or locally at `\Xml\Schemas\1033\natvis.xsd`. The GNU debugger (GDB) supports defining custom debugger views using Pretty Printers. Pretty printers are written as python scripts that describe how a type should be displayed when loaded up in GDB/LLDB. (See: https://sourceware.org/gdb/onlinedocs/gdb/Pretty-Printing.html#Pretty-Printing) The pretty printers provide patterns, which match type names, and for matching types, describe how to display those types. (For writing a pretty printer, see: https://sourceware.org/gdb/onlinedocs/gdb/Writing-a-Pretty_002dPrinter.html#Writing-a-Pretty_002dPrinter). ### Embedding Visualizers Through the use of the currently unstable `#[debugger_visualizer]` attribute, the `tinyvec` crate can embed debugger visualizers into the crate metadata. Currently the two types of visualizers supported are Natvis and Pretty printers. For Natvis files, when linking an executable with a crate that includes Natvis files, the MSVC linker will embed the contents of all Natvis files into the generated `PDB`. For pretty printers, the compiler will encode the contents of the pretty printer in the `.debug_gdb_scripts` section of the `ELF` generated. ### Testing Visualizers The `tinyvec` crate supports testing debugger visualizers defined for this crate. The entry point for these tests are `tests/debugger_visualizer.rs`. These tests are defined using the `debugger_test` and `debugger_test_parser` crates. The `debugger_test` crate is a proc macro crate which defines a single proc macro attribute, `#[debugger_test]`. For more detailed information about this crate, see https://crates.io/crates/debugger_test. The CI pipeline for the `tinyvec` crate has been updated to run the debugger visualizer tests to ensure debugger visualizers do not become broken/stale. The `#[debugger_test]` proc macro attribute may only be used on test functions and will run the function under the debugger specified by the `debugger` meta item. This proc macro attribute has 3 required values: 1. The first required meta item, `debugger`, takes a string value which specifies the debugger to launch. 2. The second required meta item, `commands`, takes a string of new line (`\n`) separated list of debugger commands to run. 3. The third required meta item, `expected_statements`, takes a string of new line (`\n`) separated list of statements that must exist in the debugger output. Pattern matching through regular expressions is also supported by using the `pattern:` prefix for each expected statement. #### Example: ```rust #[debugger_test( debugger = "cdb", commands = "command1\ncommand2\ncommand3", expected_statements = "statement1\nstatement2\nstatement3")] fn test() { } ``` Using a multiline string is also supported, with a single debugger command/expected statement per line: ```rust #[debugger_test( debugger = "cdb", commands = " command1 command2 command3", expected_statements = " statement1 pattern:statement[0-9]+ statement3")] fn test() { } ``` In the example above, the second expected statement uses pattern matching through a regular expression by using the `pattern:` prefix. #### Testing Locally Currently, only Natvis visualizations have been defined for the `tinyvec` crate via `debug_metadata/tinyvec.natvis`, which means the `tests/debugger_visualizer.rs` tests need to be run on Windows using the `*-pc-windows-msvc` targets. To run these tests locally, first ensure the debugging tools for Windows are installed or install them following the steps listed here, [Debugging Tools for Windows](https://docs.microsoft.com/en-us/windows-hardware/drivers/debugger/). Once the debugging tools have been installed, the tests can be run in the same manner as they are in the CI pipeline. #### Note When running the debugger visualizer tests, `tests/debugger_visualizer.rs`, they need to be run consecutively and not in parallel. This can be achieved by passing the flag `--test-threads=1` to rustc. This is due to how the debugger tests are run. Each test marked with the `#[debugger_test]` attribute launches a debugger and attaches it to the current test process. If tests are running in parallel, the test will try to attach a debugger to the current process which may already have a debugger attached causing the test to fail. For example: ``` cargo test --test debugger_visualizer --features debugger_visualizer -- --test-threads=1 ```