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Rust Stable MIR Pretty Printing

This package provides:

  1. a library crate that provides:
    • a rustc compiler wrapper which can access stable MIR APIs
    • a pretty-printer for a large fragment of stable MIR
  2. a rustc wrapper binary that uses (1)-(2) to pretty-print Rust source files as stable MIR using the .smir.json extension.

It is designed so that anyone can use this library crate as a jumping off point for their own tools which might use stable MIR APIs.

Building

For first-time builds, run:

make setup build_all

If the underlying rustc branch is updated and this crate needs to be rebuilt on top of it, run:

make update build_all

If the source code changes locally for this crate only and it needs to be rebuilt, run:

make build

Usage

Use the wrapper script run.sh (or cargo run, but this may also initiate a build). The options that this tool accepts are identical to rustc. To generate stable MIR output without building a binary, you can invoke the tool as follows:

./run.sh -Z no-codegen <crate_root>

There are a few environment variables that can be set to control the tools output:

  1. LINK_ITEMS - add entries to the link-time functions map for each monomorphic item in the crate;
  2. LINK_INST - use a richer key-structure for the link-time functions map which uses keys that are pairs of a function type (Ty) and an function instance kind (InstanceKind)
  3. DEBUG - serialize additional data in the JSON file and dump logs to stdout

Invocation Details

We use an uncommon build process where we link against a patched rustc installed in this repo. However, since cargo build does not set rpath for dynamic linking, we must manually point the program loader/dynamic linker at the required runtime libraries. Note that the cargo run command appears to prepard the rustlib directories automatically to the dynamic link search path. If you wish to run the tool manually, you will need to tell the program loader/dynamic linker where to find the missing libraries by:

  1. setting LD_LIBRARY_PATH
  2. setting the rpath attribute on the binary ELF file
  3. manually invoking the loader (usually /usr/lib/ld-linux.so.2) with its specific options

Tests

Running the Tests

To run the tests, do the following:

make generate_ui_tests

This will generate four outputs:

Path Comment
deps/rust/tests/ui/upstream Upstream rustc test outputs
deps/rust/tests_ui_upstream.log Upstream test log
deps/rust/tests/ui/smir smir_pretty test outputs (including .smir.json files)
deps/rust/tests_ui_smir.log smir_pretty test log

Test Rationale

Since this crate is a Stable MIR serialization tool, there are two main features we are interested in:

  1. the serialization facilities should be stable (i.e. not crash)
  2. the serialized output should be correct

Since this tool is currently in its early stages, it is hard to test (2). However, to test (1) and to make progress towards (2), we currently do the following:

  1. in the rustc test suite, we gather all of the run-pass tests, i.e., tests where the compiler is able to generate a binary and subsequently execute the binary such that it exits successfully
  2. we extract the test runner invocation from the x.py test command
  3. we execute the test runner with upstream rustc against the test inputs from (1) --- this gives us a baseline on which tests should pass/fail
  4. we re-execute the test runner but use our wrapper binary against the test inputs from (1) --- this generates the corresponding .smir.json files and shows us where any regressions occur

NOTE: In order to speed up test time, we setup the test runner, by default, such that it skips codegen and compiler-generated binary execution.
NOTE: Points (1,4) also means that our test outputs from this phase can become test inputs for KMIR.

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