use std::{ collections::{HashMap, HashSet}, convert::AsRef, env, fs::{self, DirEntry, File}, io::{self, BufRead, BufReader}, path::{Path, PathBuf}, process::{Command, Stdio}, str::FromStr, }; /// Minimum required Python version. const PY3_MIN_MINOR: u8 = 6; /// Maximum Python version that can be used as minimum required Python version with abi3. const ABI3_MAX_MINOR: u8 = 9; const CFG_KEY: &str = "py_sys_config"; type Result = std::result::Result>; // A simple macro for returning an error. Resembles failure::bail and anyhow::bail. macro_rules! bail { ($msg: expr) => { return Err($msg.into()); }; ($fmt: literal $(, $args: expr)+) => { return Err(format!($fmt $(,$args)+).into()); }; } /// Information returned from python interpreter #[derive(Debug)] struct InterpreterConfig { version: PythonVersion, libdir: Option, shared: bool, ld_version: String, /// Prefix used for determining the directory of libpython base_prefix: String, executable: PathBuf, calcsize_pointer: Option, } #[derive(Debug, Clone)] struct PythonVersion { major: u8, minor: u8, implementation: PythonInterpreterKind, } #[derive(Debug, Clone, PartialEq)] pub enum PythonInterpreterKind { CPython, PyPy, } impl FromStr for PythonInterpreterKind { type Err = Box; fn from_str(s: &str) -> Result { match s { "CPython" => Ok(PythonInterpreterKind::CPython), "PyPy" => Ok(PythonInterpreterKind::PyPy), _ => bail!("Invalid interpreter: {}", s), } } } trait GetPrimitive { fn get_bool(&self, key: &str) -> Result; fn get_numeric(&self, key: &str) -> Result; } impl GetPrimitive for HashMap { fn get_bool(&self, key: &str) -> Result { match self .get(key) .map(|x| x.as_str()) .ok_or(format!("{} is not defined", key))? { "1" | "true" | "True" => Ok(true), "0" | "false" | "False" => Ok(false), _ => bail!("{} must be a bool (1/true/True or 0/false/False", key), } } fn get_numeric(&self, key: &str) -> Result { self.get(key) .ok_or(format!("{} is not defined", key))? .parse::() .map_err(|_| format!("Could not parse value of {}", key).into()) } } struct CrossCompileConfig { lib_dir: PathBuf, include_dir: Option, version: Option, os: String, arch: String, } impl CrossCompileConfig { fn both() -> Result { Ok(CrossCompileConfig { include_dir: env::var_os("PYO3_CROSS_INCLUDE_DIR").map(Into::into), ..CrossCompileConfig::lib_only()? }) } fn lib_only() -> Result { Ok(CrossCompileConfig { lib_dir: CrossCompileConfig::validate_variable("PYO3_CROSS_LIB_DIR")?, include_dir: None, os: env::var("CARGO_CFG_TARGET_OS").unwrap(), arch: env::var("CARGO_CFG_TARGET_ARCH").unwrap(), version: env::var_os("PYO3_CROSS_PYTHON_VERSION").map(|s| s.into_string().unwrap()), }) } fn validate_variable(var: &str) -> Result { let path = match env::var_os(var) { Some(v) => v, None => bail!( "Must provide {} environment variable when cross-compiling", var ), }; if fs::metadata(&path).is_err() { bail!("{} value of {:?} does not exist", var, path) } Ok(path.into()) } } fn cross_compiling() -> Result> { let target = env::var("TARGET")?; let host = env::var("HOST")?; if target == host { // Not cross-compiling return Ok(None); } if target == "i686-pc-windows-msvc" && host == "x86_64-pc-windows-msvc" { // Not cross-compiling to compile for 32-bit Python from windows 64-bit return Ok(None); } if target == "x86_64-apple-darwin" && host == "aarch64-apple-darwin" { // Not cross-compiling to compile for x86-64 Python from macOS arm64 return Ok(None); } if target == "aarch64-apple-darwin" && host == "x86_64-apple-darwin" { // Not cross-compiling to compile for arm64 Python from macOS x86_64 return Ok(None); } if host.starts_with(&format!( "{}-{}-{}", env::var("CARGO_CFG_TARGET_ARCH")?, env::var("CARGO_CFG_TARGET_VENDOR")?, env::var("CARGO_CFG_TARGET_OS")? )) { // Not cross-compiling if arch-vendor-os is all the same // e.g. x86_64-unknown-linux-musl on x86_64-unknown-linux-gnu host return Ok(None); } if env::var("CARGO_CFG_TARGET_FAMILY")? == "windows" { // Windows cross-compile uses both header includes and sysconfig return Ok(Some(CrossCompileConfig::both()?)); } // Cross-compiling on any other platform Ok(Some(CrossCompileConfig::lib_only()?)) } /// A list of python interpreter compile-time preprocessor defines that /// we will pick up and pass to rustc via --cfg=py_sys_config={varname}; /// this allows using them conditional cfg attributes in the .rs files, so /// /// #[cfg(py_sys_config="{varname}"] /// /// is the equivalent of #ifdef {varname} name in C. /// /// see Misc/SpecialBuilds.txt in the python source for what these mean. /// /// (hrm, this is sort of re-implementing what distutils does, except /// by passing command line args instead of referring to a python.h) struct BuildFlags(HashSet<&'static str>); impl BuildFlags { const ALL: [&'static str; 5] = [ "WITH_THREAD", "Py_DEBUG", "Py_REF_DEBUG", "Py_TRACE_REFS", "COUNT_ALLOCS", ]; fn from_config_map(config_map: &HashMap) -> Self { Self( BuildFlags::ALL .iter() .copied() .filter(|flag| config_map.get(*flag).map_or(false, |value| value == "1")) .collect(), ) } /// Examine python's compile flags to pass to cfg by launching /// the interpreter and printing variables of interest from /// sysconfig.get_config_vars. fn from_interpreter(python_path: &Path) -> Result { if env::var("CARGO_CFG_TARGET_OS").unwrap() == "windows" { return Ok(Self::windows_hardcoded()); } let mut script = "import sysconfig; \ config = sysconfig.get_config_vars();" .to_owned(); for k in BuildFlags::ALL.iter() { script.push_str(&format!("print(config.get('{}', '0'));", k)); } let stdout = run_python_script(python_path, &script)?; let split_stdout: Vec<&str> = stdout.trim_end().lines().collect(); if split_stdout.len() != BuildFlags::ALL.len() { bail!( "Python stdout len didn't return expected number of lines: {}", split_stdout.len() ); } let flags = BuildFlags::ALL .iter() .zip(split_stdout) .filter(|(_, flag_value)| *flag_value == "1") .map(|(&flag, _)| flag) .collect(); Ok(Self(flags)) } fn windows_hardcoded() -> Self { // sysconfig is missing all the flags on windows, so we can't actually // query the interpreter directly for its build flags. // // For the time being, this is the flags as defined in the python source's // PC\pyconfig.h. This won't work correctly if someone has built their // python with a modified pyconfig.h - sorry if that is you, you will have // to comment/uncomment the lines below. let mut flags = HashSet::new(); flags.insert("WITH_THREAD"); // This is defined #ifdef _DEBUG. The visual studio build seems to produce // a specially named pythonXX_d.exe and pythonXX_d.dll when you build the // Debug configuration, which this script doesn't currently support anyway. // map.insert("Py_DEBUG", "1"); // Uncomment these manually if your python was built with these and you want // the cfg flags to be set in rust. // // map.insert("Py_REF_DEBUG", "1"); // map.insert("Py_TRACE_REFS", "1"); // map.insert("COUNT_ALLOCS", 1"); Self(flags) } fn fixup(&mut self, interpreter_config: &InterpreterConfig) { if self.0.contains("Py_DEBUG") { self.0.insert("Py_REF_DEBUG"); if interpreter_config.version.major == 3 && interpreter_config.version.minor <= 7 { // Py_DEBUG only implies Py_TRACE_REFS until Python 3.7 self.0.insert("Py_TRACE_REFS"); } } // WITH_THREAD is always on for Python 3.7, and for PyPy. if (interpreter_config.version.implementation == PythonInterpreterKind::PyPy) || (interpreter_config.version.major == 3 && interpreter_config.version.minor >= 7) { self.0.insert("WITH_THREAD"); } } } /// Attempts to parse the header at the given path, returning a map of definitions to their values. /// Each entry in the map directly corresponds to a `#define` in the given header. fn parse_header_defines(header_path: impl AsRef) -> Result> { let header_reader = BufReader::new(File::open(header_path.as_ref())?); let mut definitions = HashMap::new(); for maybe_line in header_reader.lines() { let line = maybe_line?; let mut i = line.trim().split_whitespace(); if i.next() == Some("#define") { if let (Some(key), Some(value), None) = (i.next(), i.next(), i.next()) { definitions.insert(key.into(), value.into()); } } } Ok(definitions) } fn parse_script_output(output: &str) -> HashMap { output .lines() .filter_map(|line| { let mut i = line.splitn(2, ' '); Some((i.next()?.into(), i.next()?.into())) }) .collect() } /// Parse sysconfigdata file /// /// The sysconfigdata is simply a dictionary containing all the build time variables used for the /// python executable and library. Here it is read and added to a script to extract only what is /// necessary. This necessitates a python interpreter for the host machine to work. fn parse_sysconfigdata(config_path: impl AsRef) -> Result> { let mut script = fs::read_to_string(config_path)?; script += r#" print("version_major", build_time_vars["VERSION"][0]) # 3 print("version_minor", build_time_vars["VERSION"][2]) # E.g., 8 if "WITH_THREAD" in build_time_vars: print("WITH_THREAD", build_time_vars["WITH_THREAD"]) if "Py_TRACE_REFS" in build_time_vars: print("Py_TRACE_REFS", build_time_vars["Py_TRACE_REFS"]) if "COUNT_ALLOCS" in build_time_vars: print("COUNT_ALLOCS", build_time_vars["COUNT_ALLOCS"]) if "Py_REF_DEBUG" in build_time_vars: print("Py_REF_DEBUG", build_time_vars["Py_REF_DEBUG"]) print("Py_DEBUG", build_time_vars["Py_DEBUG"]) print("Py_ENABLE_SHARED", build_time_vars["Py_ENABLE_SHARED"]) print("LDVERSION", build_time_vars["LDVERSION"]) print("SIZEOF_VOID_P", build_time_vars["SIZEOF_VOID_P"]) "#; let output = run_python_script(&find_interpreter()?, &script)?; Ok(parse_script_output(&output)) } fn starts_with(entry: &DirEntry, pat: &str) -> bool { let name = entry.file_name(); name.to_string_lossy().starts_with(pat) } fn ends_with(entry: &DirEntry, pat: &str) -> bool { let name = entry.file_name(); name.to_string_lossy().ends_with(pat) } /// Finds the `_sysconfigdata*.py` file in the library path. /// /// From the python source for `_sysconfigdata*.py` is always going to be located at /// `build/lib.{PLATFORM}-{PY_MINOR_VERSION}` when built from source. The [exact line][1] is defined as: /// /// ```py /// pybuilddir = 'build/lib.%s-%s' % (get_platform(), sys.version_info[:2]) /// ``` /// /// Where get_platform returns a kebab-case formated string containing the os, the architecture and /// possibly the os' kernel version (not the case on linux). However, when installed using a package /// manager, the `_sysconfigdata*.py` file is installed in the `${PREFIX}/lib/python3.Y/` directory. /// The `_sysconfigdata*.py` is generally in a sub-directory of the location of `libpython3.Y.so`. /// So we must find the file in the following possible locations: /// /// ```sh /// # distribution from package manager, lib_dir should include lib/ /// ${INSTALL_PREFIX}/lib/python3.Y/_sysconfigdata*.py /// ${INSTALL_PREFIX}/lib/libpython3.Y.so /// ${INSTALL_PREFIX}/lib/python3.Y/config-3.Y-${HOST_TRIPLE}/libpython3.Y.so /// /// # Built from source from host /// ${CROSS_COMPILED_LOCATION}/build/lib.linux-x86_64-Y/_sysconfigdata*.py /// ${CROSS_COMPILED_LOCATION}/libpython3.Y.so /// /// # if cross compiled, kernel release is only present on certain OS targets. /// ${CROSS_COMPILED_LOCATION}/build/lib.{OS}(-{OS-KERNEL-RELEASE})?-{ARCH}-Y/_sysconfigdata*.py /// ${CROSS_COMPILED_LOCATION}/libpython3.Y.so /// ``` /// /// [1]: https://github.com/python/cpython/blob/3.5/Lib/sysconfig.py#L389 fn find_sysconfigdata(cross: &CrossCompileConfig) -> Result { let sysconfig_paths = search_lib_dir(&cross.lib_dir, &cross); let mut sysconfig_paths = sysconfig_paths .iter() .filter_map(|p| fs::canonicalize(p).ok()) .collect::>(); sysconfig_paths.dedup(); if sysconfig_paths.is_empty() { bail!( "Could not find either libpython.so or _sysconfigdata*.py in {}", cross.lib_dir.display() ); } else if sysconfig_paths.len() > 1 { bail!( "Detected multiple possible python versions, please set the PYO3_PYTHON_VERSION \ variable to the wanted version on your system\nsysconfigdata paths = {:?}", sysconfig_paths ) } Ok(sysconfig_paths.remove(0)) } /// recursive search for _sysconfigdata, returns all possibilities of sysconfigdata paths fn search_lib_dir(path: impl AsRef, cross: &CrossCompileConfig) -> Vec { let mut sysconfig_paths = vec![]; let version_pat = if let Some(v) = &cross.version { format!("python{}", v) } else { "python3.".into() }; for f in fs::read_dir(path).expect("Path does not exist") { let sysc = match &f { Ok(f) if starts_with(f, "_sysconfigdata") && ends_with(f, "py") => vec![f.path()], Ok(f) if starts_with(f, "build") => search_lib_dir(f.path(), cross), Ok(f) if starts_with(f, "lib.") => { let name = f.file_name(); // check if right target os if !name.to_string_lossy().contains(if cross.os == "android" { "linux" } else { &cross.os }) { continue; } // Check if right arch if !name.to_string_lossy().contains(&cross.arch) { continue; } search_lib_dir(f.path(), cross) } Ok(f) if starts_with(f, &version_pat) => search_lib_dir(f.path(), cross), _ => continue, }; sysconfig_paths.extend(sysc); } sysconfig_paths } /// Find cross compilation information from sysconfigdata file /// /// first find sysconfigdata file which follows the pattern [`_sysconfigdata_{abi}_{platform}_{multiarch}`][1] /// on python 3.6 or greater. On python 3.5 it is simply `_sysconfigdata.py`. /// /// [1]: https://github.com/python/cpython/blob/3.8/Lib/sysconfig.py#L348 fn load_cross_compile_from_sysconfigdata( cross_compile_config: CrossCompileConfig, ) -> Result<(InterpreterConfig, BuildFlags)> { let sysconfig_path = find_sysconfigdata(&cross_compile_config)?; let sysconfig_data = parse_sysconfigdata(sysconfig_path)?; let major = sysconfig_data.get_numeric("version_major")?; let minor = sysconfig_data.get_numeric("version_minor")?; let ld_version = match sysconfig_data.get("LDVERSION") { Some(s) => s.clone(), None => format!("{}.{}", major, minor), }; let calcsize_pointer = sysconfig_data.get_numeric("SIZEOF_VOID_P").ok(); let python_version = PythonVersion { major, minor, implementation: PythonInterpreterKind::CPython, }; let interpreter_config = InterpreterConfig { version: python_version, libdir: cross_compile_config.lib_dir.to_str().map(String::from), shared: sysconfig_data.get_bool("Py_ENABLE_SHARED")?, ld_version, base_prefix: "".to_string(), executable: PathBuf::new(), calcsize_pointer, }; let build_flags = BuildFlags::from_config_map(&sysconfig_data); Ok((interpreter_config, build_flags)) } fn load_cross_compile_from_headers( cross_compile_config: CrossCompileConfig, ) -> Result<(InterpreterConfig, BuildFlags)> { let python_include_dir = cross_compile_config.include_dir.unwrap(); let python_include_dir = Path::new(&python_include_dir); let patchlevel_defines = parse_header_defines(python_include_dir.join("patchlevel.h"))?; let major = patchlevel_defines.get_numeric("PY_MAJOR_VERSION")?; let minor = patchlevel_defines.get_numeric("PY_MINOR_VERSION")?; let python_version = PythonVersion { major, minor, implementation: PythonInterpreterKind::CPython, }; let config_data = parse_header_defines(python_include_dir.join("pyconfig.h"))?; let interpreter_config = InterpreterConfig { version: python_version, libdir: cross_compile_config.lib_dir.to_str().map(String::from), shared: config_data.get_bool("Py_ENABLE_SHARED").unwrap_or(false), ld_version: format!("{}.{}", major, minor), base_prefix: "".to_string(), executable: PathBuf::new(), calcsize_pointer: None, }; let build_flags = BuildFlags::from_config_map(&config_data); Ok((interpreter_config, build_flags)) } fn windows_hardcoded_cross_compile( cross_compile_config: CrossCompileConfig, ) -> Result<(InterpreterConfig, BuildFlags)> { let (major, minor) = if let Some(version) = cross_compile_config.version { let mut parts = version.split('.'); match ( parts.next().and_then(|major| major.parse().ok()), parts.next().and_then(|minor| minor.parse().ok()), parts.next(), ) { (Some(major), Some(minor), None) => (major, minor), _ => bail!( "Expected major.minor version (e.g. 3.9) for PYO3_CROSS_VERSION, got `{}`", version ), } } else if let Some(minor_version) = get_abi3_minor_version() { (3, minor_version) } else { bail!("One of PYO3_CROSS_INCLUDE_DIR, PYO3_CROSS_PYTHON_VERSION, or an abi3-py3* feature must be specified when cross-compiling for Windows.") }; let python_version = PythonVersion { major, minor, implementation: PythonInterpreterKind::CPython, }; let interpreter_config = InterpreterConfig { version: python_version, libdir: cross_compile_config.lib_dir.to_str().map(String::from), shared: true, ld_version: format!("{}.{}", major, minor), base_prefix: "".to_string(), executable: PathBuf::new(), calcsize_pointer: None, }; Ok((interpreter_config, BuildFlags::windows_hardcoded())) } fn load_cross_compile_info( cross_compile_config: CrossCompileConfig, ) -> Result<(InterpreterConfig, BuildFlags)> { let target_family = env::var("CARGO_CFG_TARGET_FAMILY")?; // Because compiling for windows on linux still includes the unix target family if target_family == "unix" { // Configure for unix platforms using the sysconfigdata file load_cross_compile_from_sysconfigdata(cross_compile_config) } else if cross_compile_config.include_dir.is_some() { // Must configure by headers on windows platform load_cross_compile_from_headers(cross_compile_config) } else { windows_hardcoded_cross_compile(cross_compile_config) } } /// Run a python script using the specified interpreter binary. fn run_python_script(interpreter: &Path, script: &str) -> Result { let out = Command::new(interpreter) .env("PYTHONIOENCODING", "utf-8") .stdin(Stdio::piped()) .stdout(Stdio::piped()) .stderr(Stdio::inherit()) .spawn() .and_then(|mut child| { use std::io::Write; child .stdin .as_mut() .expect("piped stdin") .write_all(script.as_bytes())?; child.wait_with_output() }); match out { Err(err) => { if err.kind() == io::ErrorKind::NotFound { bail!( "Could not find any interpreter at {}, \ are you sure you have Python installed on your PATH?", interpreter.display() ); } else { bail!( "Failed to run the Python interpreter at {}: {}", interpreter.display(), err ); } } Ok(ok) if !ok.status.success() => bail!("Python script failed"), Ok(ok) => Ok(String::from_utf8(ok.stdout)?), } } fn get_rustc_link_lib(config: &InterpreterConfig) -> String { let link_name = if env::var("CARGO_CFG_TARGET_OS").unwrap().as_str() == "windows" { if env::var("CARGO_CFG_TARGET_ENV").unwrap().as_str() == "gnu" { // https://packages.msys2.org/base/mingw-w64-python format!( "pythonXY:python{}.{}", config.version.major, config.version.minor ) } else { // Link against python3.lib for the stable ABI on Windows. // See https://www.python.org/dev/peps/pep-0384/#linkage // // This contains only the limited ABI symbols. if env::var_os("CARGO_FEATURE_ABI3").is_some() { "pythonXY:python3".to_owned() } else { format!( "pythonXY:python{}{}", config.version.major, config.version.minor ) } } } else { match config.version.implementation { PythonInterpreterKind::CPython => format!("python{}", config.ld_version), PythonInterpreterKind::PyPy => format!("pypy{}-c", config.version.major), } }; format!( "cargo:rustc-link-lib={link_model}{link_name}", link_model = if config.shared { "" } else { "static=" }, link_name = link_name ) } fn find_interpreter() -> Result { if let Some(exe) = env::var_os("PYO3_PYTHON") { Ok(exe.into()) } else if let Some(exe) = env::var_os("PYTHON_SYS_EXECUTABLE") { // Backwards-compatible name for PYO3_PYTHON; this may be removed at some point in the future. Ok(exe.into()) } else { ["python", "python3"] .iter() .find(|bin| { if let Ok(out) = Command::new(bin).arg("--version").output() { // begin with `Python 3.X.X :: additional info` out.stdout.starts_with(b"Python 3") || out.stderr.starts_with(b"Python 3") } else { false } }) .map(PathBuf::from) .ok_or_else(|| "Python 3.x interpreter not found".into()) } } /// Locate a suitable python interpreter and extract config from it. /// /// The following locations are checked in the order listed: /// /// 1. If `PYO3_PYTHON` is set, this intepreter is used and an error is raised if the /// version doesn't match. /// 2. `python` /// 3. `python{major version}` /// 4. `python{major version}.{minor version}` /// /// If none of the above works, an error is returned fn find_interpreter_and_get_config() -> Result<(InterpreterConfig, BuildFlags)> { let python_interpreter = find_interpreter()?; let interpreter_config = get_config_from_interpreter(&python_interpreter)?; if interpreter_config.version.major == 3 { return Ok(( interpreter_config, BuildFlags::from_interpreter(&python_interpreter)?, )); } Err("No Python interpreter found".into()) } /// Extract compilation vars from the specified interpreter. fn get_config_from_interpreter(interpreter: &Path) -> Result { let script = r#" import platform import struct import sys import sysconfig import os.path PYPY = platform.python_implementation() == "PyPy" # Anaconda based python distributions have a static python executable, but include # the shared library. Use the shared library for embedding to avoid rust trying to # LTO the static library (and failing with newer gcc's, because it is old). ANACONDA = os.path.exists(os.path.join(sys.base_prefix, 'conda-meta')) libdir = sysconfig.get_config_var('LIBDIR') print("version_major", sys.version_info[0]) print("version_minor", sys.version_info[1]) print("implementation", platform.python_implementation()) if libdir is not None: print("libdir", libdir) print("ld_version", sysconfig.get_config_var('LDVERSION') or sysconfig.get_config_var('py_version_short')) print("base_prefix", sys.base_prefix) print("framework", bool(sysconfig.get_config_var('PYTHONFRAMEWORK'))) print("shared", PYPY or ANACONDA or bool(sysconfig.get_config_var('Py_ENABLE_SHARED'))) print("executable", sys.executable) print("calcsize_pointer", struct.calcsize("P")) "#; let output = run_python_script(interpreter, script)?; let map: HashMap = parse_script_output(&output); let shared = match ( env::var("CARGO_CFG_TARGET_OS").unwrap().as_str(), map["framework"].as_str(), map["shared"].as_str(), ) { (_, _, "True") // Py_ENABLE_SHARED is set | ("windows", _, _) // Windows always uses shared linking | ("macos", "True", _) // MacOS framework package uses shared linking => true, (_, _, "False") => false, // Any other platform, Py_ENABLE_SHARED not set _ => bail!("Unrecognised link model combination") }; Ok(InterpreterConfig { version: PythonVersion { major: map["version_major"].parse()?, minor: map["version_minor"].parse()?, implementation: map["implementation"].parse()?, }, libdir: map.get("libdir").cloned(), shared, ld_version: map["ld_version"].clone(), base_prefix: map["base_prefix"].clone(), executable: map["executable"].clone().into(), calcsize_pointer: Some(map["calcsize_pointer"].parse()?), }) } fn configure(interpreter_config: &InterpreterConfig) -> Result<()> { if interpreter_config.version.major == 2 { // fail PYO3_PYTHON=python2 cargo ... bail!("Python 2 is not supported"); } if interpreter_config.version.minor < PY3_MIN_MINOR { bail!( "Python 3 required version is 3.{}, current version is 3.{}", PY3_MIN_MINOR, interpreter_config.version.minor ); } check_target_architecture(interpreter_config)?; let target_os = env::var_os("CARGO_CFG_TARGET_OS").unwrap(); let is_extension_module = env::var_os("CARGO_FEATURE_EXTENSION_MODULE").is_some(); if !is_extension_module || target_os == "windows" || target_os == "android" { println!("{}", get_rustc_link_lib(&interpreter_config)); if let Some(libdir) = &interpreter_config.libdir { println!("cargo:rustc-link-search=native={}", libdir); } else if target_os == "windows" { println!( "cargo:rustc-link-search=native={}\\libs", interpreter_config.base_prefix ); } } if interpreter_config.shared { println!("cargo:rustc-cfg=Py_SHARED"); } if interpreter_config.version.implementation == PythonInterpreterKind::PyPy { println!("cargo:rustc-cfg=PyPy"); }; let minor = if env::var_os("CARGO_FEATURE_ABI3").is_some() { println!("cargo:rustc-cfg=Py_LIMITED_API"); // Check any `abi3-py3*` feature is set. If not, use the interpreter version. match get_abi3_minor_version() { Some(minor) if minor > interpreter_config.version.minor => bail!( "You cannot set a mininimum Python version 3.{} higher than the interpreter version 3.{}", minor, interpreter_config.version.minor ), Some(minor) => minor, None => interpreter_config.version.minor } } else { interpreter_config.version.minor }; for i in PY3_MIN_MINOR..=minor { println!("cargo:rustc-cfg=Py_3_{}", i); } Ok(()) } fn check_target_architecture(interpreter_config: &InterpreterConfig) -> Result<()> { // Try to check whether the target architecture matches the python library let rust_target = match env::var("CARGO_CFG_TARGET_POINTER_WIDTH")?.as_str() { "64" => "64-bit", "32" => "32-bit", x => bail!("unexpected Rust target pointer width: {}", x), }; // The reason we don't use platform.architecture() here is that it's not // reliable on macOS. See https://stackoverflow.com/a/1405971/823869. // Similarly, sys.maxsize is not reliable on Windows. See // https://stackoverflow.com/questions/1405913/how-do-i-determine-if-my-python-shell-is-executing-in-32bit-or-64bit-mode-on-os/1405971#comment6209952_1405971 // and https://stackoverflow.com/a/3411134/823869. let python_target = match interpreter_config.calcsize_pointer { Some(8) => "64-bit", Some(4) => "32-bit", None => { // Unset, e.g. because we're cross-compiling. Don't check anything // in this case. return Ok(()); } Some(n) => bail!("unexpected Python calcsize_pointer value: {}", n), }; if rust_target != python_target { bail!( "Your Rust target architecture ({}) does not match your python interpreter ({})", rust_target, python_target ); } Ok(()) } fn get_abi3_minor_version() -> Option { (PY3_MIN_MINOR..=ABI3_MAX_MINOR) .find(|i| env::var_os(format!("CARGO_FEATURE_ABI3_PY3{}", i)).is_some()) } fn abi3_without_interpreter() -> Result<()> { println!("cargo:rustc-cfg=Py_LIMITED_API"); let mut flags = "FLAG_WITH_THREAD=1".to_string(); let abi_version = get_abi3_minor_version().unwrap_or(ABI3_MAX_MINOR); for minor in PY3_MIN_MINOR..=abi_version { println!("cargo:rustc-cfg=Py_3_{}", minor); flags += &format!(",CFG_Py_3_{}", minor); } println!("cargo:rustc-cfg=py_sys_config=\"WITH_THREAD\""); println!("cargo:python_flags={}", flags); // Unfortunately, on windows we can't build without at least providing // python.lib to the linker. While maturin tells the linker the location // of python.lib, we need to do the renaming here, otherwise cargo // complains that the crate using pyo3 does not contains a `#[link(...)]` // attribute with pythonXY. if env::var("CARGO_CFG_TARGET_FAMILY")? == "windows" { println!("cargo:rustc-link-lib=pythonXY:python3"); } Ok(()) } fn main() -> Result<()> { // If PYO3_NO_PYTHON is set with abi3, we can build PyO3 without calling Python. // We only check for the abi3-py3{ABI3_MAX_MINOR} because lower versions depend on it. if env::var_os("PYO3_NO_PYTHON").is_some() && env::var_os(format!("CARGO_FEATURE_ABI3_PY3{}", ABI3_MAX_MINOR)).is_some() { return abi3_without_interpreter(); } // 1. Setup cfg variables so we can do conditional compilation in this library based on the // python interpeter's compilation flags. This is necessary for e.g. matching the right unicode // and threading interfaces. First check if we're cross compiling, if so, we cannot run the // target Python interpreter and have to parse pyconfig.h instead. If we're not cross // compiling, locate the python interpreter based on the PATH, which should work smoothly with // an activated virtualenv, and load from there. // // If you have troubles with your shell accepting '.' in a var name, // try using 'env' (sorry but this isn't our fault - it just has to // match the pkg-config package name, which is going to have a . in it). // // Detecting if cross-compiling by checking if the target triple is different from the host // rustc's triple. let (interpreter_config, mut build_flags) = if let Some(paths) = cross_compiling()? { load_cross_compile_info(paths)? } else { find_interpreter_and_get_config()? }; build_flags.fixup(&interpreter_config); configure(&interpreter_config)?; for flag in &build_flags.0 { println!("cargo:rustc-cfg={}=\"{}\"", CFG_KEY, flag) } if env::var_os("TARGET") == Some("x86_64-apple-darwin".into()) { // TODO: Find out how we can set -undefined dynamic_lookup here (if this is possible) } for var in ["LIB", "LD_LIBRARY_PATH", "PYO3_PYTHON"].iter() { println!("cargo:rerun-if-env-changed={}", var); } if env::var_os("PYO3_PYTHON").is_none() { // When PYO3_PYTHON is not used, PYTHON_SYS_EXECUTABLE has the highest priority. // Let's watch it. println!("cargo:rerun-if-env-changed=PYTHON_SYS_EXECUTABLE"); if env::var_os("PYTHON_SYS_EXECUTABLE").is_none() { // When PYTHON_SYS_EXECUTABLE is also not used, then we use PATH. // Let's watch this, too. println!("cargo:rerun-if-env-changed=PATH"); } } // TODO: this is a hack to workaround compile_error! warnings about auto-initialize on PyPy // Once cargo's `resolver = "2"` is stable (~ MSRV Rust 1.52), remove this. if env::var_os("PYO3_CI").is_some() { println!("cargo:rustc-cfg=__pyo3_ci"); } Ok(()) }