roc/compiler/build/src/program.rs

#[cfg(feature = "llvm")]
use roc_gen_llvm::llvm::build::module_from_builtins;
#[cfg(feature = "llvm")]
pub use roc_gen_llvm::llvm::build::FunctionIterator;
#[cfg(feature = "llvm")]
use roc_load::file::MonomorphizedModule;
#[cfg(feature = "llvm")]
use roc_mono::ir::OptLevel;
#[cfg(feature = "llvm")]
use std::path::{Path, PathBuf};
use std::time::Duration;

#[derive(Debug, Clone, Copy, Default)]
pub struct CodeGenTiming {
    pub code_gen: Duration,
    pub emit_o_file: Duration,
}

// TODO: If modules besides this one start needing to know which version of
// llvm we're using, consider moving me somewhere else.
const LLVM_VERSION: &str = "12";

// TODO instead of finding exhaustiveness problems in monomorphization, find
// them after type checking (like Elm does) so we can complete the entire
// `roc check` process without needing to monomorphize.
/// Returns the number of problems reported.
pub fn report_problems(loaded: &mut MonomorphizedModule) -> usize {
    use roc_reporting::report::{
        can_problem, mono_problem, type_problem, Report, RocDocAllocator, Severity::*,
        DEFAULT_PALETTE,
    };
    let palette = DEFAULT_PALETTE;

    // This will often over-allocate total memory, but it means we definitely
    // never need to re-allocate either the warnings or the errors vec!
    let total_problems = loaded.total_problems();
    let mut warnings = Vec::with_capacity(total_problems);
    let mut errors = Vec::with_capacity(total_problems);

    for (home, (module_path, src)) in loaded.sources.iter() {
        let mut src_lines: Vec<&str> = Vec::new();

        if let Some((_, header_src)) = loaded.header_sources.get(&home) {
            src_lines.extend(header_src.split('\n'));
            src_lines.extend(src.split('\n').skip(1));
        } else {
            src_lines.extend(src.split('\n'));
        }

        // Report parsing and canonicalization problems
        let alloc = RocDocAllocator::new(&src_lines, *home, &loaded.interns);

        let problems = loaded.can_problems.remove(&home).unwrap_or_default();

        for problem in problems.into_iter() {
            let report = can_problem(&alloc, module_path.clone(), problem);
            let severity = report.severity;
            let mut buf = String::new();

            report.render_color_terminal(&mut buf, &alloc, &palette);

            match severity {
                Warning => {
                    warnings.push(buf);
                }
                RuntimeError => {
                    errors.push(buf);
                }
            }
        }

        let problems = loaded.type_problems.remove(&home).unwrap_or_default();

        for problem in problems {
            let report = type_problem(&alloc, module_path.clone(), problem);
            let severity = report.severity;
            let mut buf = String::new();

            report.render_color_terminal(&mut buf, &alloc, &palette);

            match severity {
                Warning => {
                    warnings.push(buf);
                }
                RuntimeError => {
                    errors.push(buf);
                }
            }
        }

        let problems = loaded.mono_problems.remove(&home).unwrap_or_default();

        for problem in problems {
            let report = mono_problem(&alloc, module_path.clone(), problem);
            let severity = report.severity;
            let mut buf = String::new();

            report.render_color_terminal(&mut buf, &alloc, &palette);

            match severity {
                Warning => {
                    warnings.push(buf);
                }
                RuntimeError => {
                    errors.push(buf);
                }
            }
        }
    }

    let problems_reported;

    // Only print warnings if there are no errors
    if errors.is_empty() {
        problems_reported = warnings.len();

        for warning in warnings {
            println!("\n{}\n", warning);
        }
    } else {
        problems_reported = errors.len();

        for error in errors {
            println!("\n{}\n", error);
        }
    }

    // If we printed any problems, print a horizontal rule at the end,
    // and then clear any ANSI escape codes (e.g. colors) we've used.
    //
    // The horizontal rule is nice when running the program right after
    // compiling it, as it lets you clearly see where the compiler
    // errors/warnings end and the program output begins.
    if problems_reported > 0 {
        println!("{}\u{001B}[0m\n", Report::horizontal_rule(&palette));
    }

    problems_reported
}

// TODO how should imported modules factor into this? What if those use builtins too?
// TODO this should probably use more helper functions
// TODO make this polymorphic in the llvm functions so it can be reused for another backend.
#[cfg(feature = "llvm")]
pub fn gen_from_mono_module(
    arena: &bumpalo::Bump,
    loaded: MonomorphizedModule,
    roc_file_path: &Path,
    target: &target_lexicon::Triple,
    app_o_file: &Path,
    opt_level: OptLevel,
    emit_debug_info: bool,
) -> CodeGenTiming {
    use crate::target::{self, convert_opt_level};
    use inkwell::attributes::{Attribute, AttributeLoc};
    use inkwell::context::Context;
    use inkwell::module::Linkage;
    use inkwell::targets::{CodeModel, FileType, RelocMode};
    use std::time::SystemTime;

    let code_gen_start = SystemTime::now();

    // Generate the binary
    let ptr_bytes = target.pointer_width().unwrap().bytes() as u32;
    let context = Context::create();
    let module = arena.alloc(module_from_builtins(target, &context, "app"));

    // strip Zig debug stuff
    // module.strip_debug_info();

    // mark our zig-defined builtins as internal
    let app_ll_file = {
        let mut temp = PathBuf::from(roc_file_path);
        temp.set_extension("ll");

        temp
    };

    let kind_id = Attribute::get_named_enum_kind_id("alwaysinline");
    debug_assert!(kind_id > 0);
    let enum_attr = context.create_enum_attribute(kind_id, 1);

    for function in FunctionIterator::from_module(module) {
        let name = function.get_name().to_str().unwrap();

        // mark our zig-defined builtins as internal
        if name.starts_with("roc_builtins") {
            function.set_linkage(Linkage::Internal);
        }

        if name.starts_with("roc_builtins.dict")
            || name.starts_with("roc_builtins.list")
            || name.starts_with("roc_builtins.dec")
            || name.starts_with("list.RocList")
            || name.starts_with("dict.RocDict")
            || name.contains("decref")
        {
            function.add_attribute(AttributeLoc::Function, enum_attr);
        }
    }

    let builder = context.create_builder();
    let (dibuilder, compile_unit) = roc_gen_llvm::llvm::build::Env::new_debug_info(module);
    let (mpm, _fpm) = roc_gen_llvm::llvm::build::construct_optimization_passes(module, opt_level);

    // Compile and add all the Procs before adding main
    let env = roc_gen_llvm::llvm::build::Env {
        arena,
        builder: &builder,
        dibuilder: &dibuilder,
        compile_unit: &compile_unit,
        context: &context,
        interns: loaded.interns,
        module,
        ptr_bytes,
        // in gen_tests, the compiler provides roc_panic
        // and sets up the setjump/longjump exception handling
        is_gen_test: false,
        exposed_to_host: loaded.exposed_to_host.keys().copied().collect(),
    };

    roc_gen_llvm::llvm::build::build_procedures(
        &env,
        opt_level,
        loaded.procedures,
        loaded.entry_point,
        Some(&app_ll_file),
    );

    env.dibuilder.finalize();

    // we don't use the debug info, and it causes weird errors.
    module.strip_debug_info();

    // Uncomment this to see the module's optimized LLVM instruction output:
    // env.module.print_to_stderr();

    mpm.run_on(module);

    // Verify the module
    if let Err(errors) = env.module.verify() {
        // write the ll code to a file, so we can modify it
        env.module.print_to_file(&app_ll_file).unwrap();

        panic!(
            "😱 LLVM errors when defining module; I wrote the full LLVM IR to {:?}\n\n {}",
            app_ll_file,
            errors.to_string(),
        );
    }

    // Uncomment this to see the module's optimized LLVM instruction output:
    // env.module.print_to_stderr();

    let code_gen = code_gen_start.elapsed().unwrap();
    let emit_o_file_start = SystemTime::now();

    // annotate the LLVM IR output with debug info
    // so errors are reported with the line number of the LLVM source
    if emit_debug_info {
        module.strip_debug_info();

        let mut app_ll_dbg_file = PathBuf::from(roc_file_path);
        app_ll_dbg_file.set_extension("dbg.ll");

        let mut app_bc_file = PathBuf::from(roc_file_path);
        app_bc_file.set_extension("bc");

        use std::process::Command;

        // write the ll code to a file, so we can modify it
        module.print_to_file(&app_ll_file).unwrap();

        // run the debugir https://github.com/vaivaswatha/debugir tool
        match Command::new("debugir")
            .args(&["-instnamer", app_ll_file.to_str().unwrap()])
            .output()
        {
            Ok(_) => {}
            Err(error) => {
                use std::io::ErrorKind;
                match error.kind() {
                    ErrorKind::NotFound => panic!(
                        r"I could not find the `debugir` tool on the PATH, install it from https://github.com/vaivaswatha/debugir"
                    ),
                    _ => panic!("{:?}", error),
                }
            }
        }

        use target_lexicon::Architecture;
        match target.architecture {
            Architecture::X86_64 | Architecture::X86_32(_) | Architecture::Aarch64(_) => {
                // assemble the .ll into a .bc
                let _ = Command::new("llvm-as")
                    .args(&[
                        app_ll_dbg_file.to_str().unwrap(),
                        "-o",
                        app_bc_file.to_str().unwrap(),
                    ])
                    .output()
                    .unwrap();

                let llc_args = &[
                    "-relocation-model=pic",
                    "-filetype=obj",
                    app_bc_file.to_str().unwrap(),
                    "-o",
                    app_o_file.to_str().unwrap(),
                ];

                // write the .o file. Note that this builds the .o for the local machine,
                // and ignores the `target_machine` entirely.
                //
                // different systems name this executable differently, so we shotgun for
                // the most common ones and then give up.
                let _: Result<std::process::Output, std::io::Error> =
                    Command::new(format!("llc-{}", LLVM_VERSION))
                        .args(llc_args)
                        .output()
                        .or_else(|_| Command::new("llc").args(llc_args).output())
                        .map_err(|_| {
                            panic!("We couldn't find llc-{} on your machine!", LLVM_VERSION);
                        });
            }

            Architecture::Wasm32 => {
                // assemble the .ll into a .bc
                let _ = Command::new("llvm-as")
                    .args(&[
                        app_ll_dbg_file.to_str().unwrap(),
                        "-o",
                        app_o_file.to_str().unwrap(),
                    ])
                    .output()
                    .unwrap();
            }
            _ => unreachable!(),
        }
    } else {
        // Emit the .o file
        use target_lexicon::Architecture;
        match target.architecture {
            Architecture::X86_64 | Architecture::X86_32(_) | Architecture::Aarch64(_) => {
                let reloc = RelocMode::PIC;
                let model = CodeModel::Default;
                let target_machine =
                    target::target_machine(target, convert_opt_level(opt_level), reloc, model)
                        .unwrap();

                target_machine
                    .write_to_file(env.module, FileType::Object, app_o_file)
                    .expect("Writing .o file failed");
            }
            Architecture::Wasm32 => {
                // Useful for debugging
                // module.print_to_file(app_ll_file);
                module.write_bitcode_to_path(app_o_file);
            }
            _ => panic!(
                "TODO gracefully handle unsupported architecture: {:?}",
                target.architecture
            ),
        }
    }

    let emit_o_file = emit_o_file_start.elapsed().unwrap();

    CodeGenTiming {
        code_gen,
        emit_o_file,
    }
}