build.rs - platform/external/rust/crates/libm - Git at Google

 use std::env;

 fn main() {
     println!("cargo:rerun-if-changed=build.rs");

     #[cfg(feature = "musl-reference-tests")]
     musl_reference_tests::generate();

     if !cfg!(feature = "checked") {
         let lvl = env::var("OPT_LEVEL").unwrap();
         if lvl != "0" {
             println!("cargo:rustc-cfg=assert_no_panic");
         }
     }
 }

 #[cfg(feature = "musl-reference-tests")]
 mod musl_reference_tests {
     use rand::seq::SliceRandom;
     use rand::Rng;
     use std::fs;
     use std::process::Command;

     // Number of tests to generate for each function
     const NTESTS: usize = 500;

     // These files are all internal functions or otherwise miscellaneous, not
     // defining a function we want to test.
     const IGNORED_FILES: &[&str] = &["fenv.rs"];

     struct Function {
         name: String,
         args: Vec<Ty>,
         ret: Vec<Ty>,
         tests: Vec<Test>,
     }

     enum Ty {
         F32,
         F64,
         I32,
         Bool,
     }

     struct Test {
         inputs: Vec<i64>,
         outputs: Vec<i64>,
     }

     pub fn generate() {
         let files = fs::read_dir("src/math")
             .unwrap()
             .map(|f| f.unwrap().path())
             .collect::<Vec<_>>();

         let mut math = Vec::new();
         for file in files {
             if IGNORED_FILES.iter().any(|f| file.ends_with(f)) {
                 continue;
             }

             println!("generating musl reference tests in {:?}", file);

             let contents = fs::read_to_string(file).unwrap();
             let mut functions = contents.lines().filter(|f| f.starts_with("pub fn"));
             while let Some(function_to_test) = functions.next() {
                 math.push(parse(function_to_test));
             }
         }

         // Generate a bunch of random inputs for each function. This will
         // attempt to generate a good set of uniform test cases for exercising
         // all the various functionality.
         generate_random_tests(&mut math, &mut rand::thread_rng());

         // After we have all our inputs, use the x86_64-unknown-linux-musl
         // target to generate the expected output.
         generate_test_outputs(&mut math);
         //panic!("Boo");
         // ... and now that we have both inputs and expected outputs, do a bunch
         // of codegen to create the unit tests which we'll actually execute.
         generate_unit_tests(&math);
     }

     /// A "poor man's" parser for the signature of a function
     fn parse(s: &str) -> Function {
         let s = eat(s, "pub fn ");
         let pos = s.find('(').unwrap();
         let name = &s[..pos];
         let s = &s[pos + 1..];
         let end = s.find(')').unwrap();
         let args = s[..end]
             .split(',')
             .map(|arg| {
                 let colon = arg.find(':').unwrap();
                 parse_ty(arg[colon + 1..].trim())
             })
             .collect::<Vec<_>>();
         let tail = &s[end + 1..];
         let tail = eat(tail, " -> ");
         let ret = parse_retty(tail.replace("{", "").trim());

         return Function {
             name: name.to_string(),
             args,
             ret,
             tests: Vec::new(),
         };

         fn parse_ty(s: &str) -> Ty {
             match s {
                 "f32" => Ty::F32,
                 "f64" => Ty::F64,
                 "i32" => Ty::I32,
                 "bool" => Ty::Bool,
                 other => panic!("unknown type `{}`", other),
             }
         }

         fn parse_retty(s: &str) -> Vec<Ty> {
             match s {
                 "(f32, f32)" => vec![Ty::F32, Ty::F32],
                 "(f32, i32)" => vec![Ty::F32, Ty::I32],
                 "(f64, f64)" => vec![Ty::F64, Ty::F64],
                 "(f64, i32)" => vec![Ty::F64, Ty::I32],
                 other => vec![parse_ty(other)],
             }
         }

         fn eat<'a>(s: &'a str, prefix: &str) -> &'a str {
             if s.starts_with(prefix) {
                 &s[prefix.len()..]
             } else {
                 panic!("{:?} didn't start with {:?}", s, prefix)
             }
         }
     }

     fn generate_random_tests<R: Rng>(functions: &mut [Function], rng: &mut R) {
         for function in functions {
             for _ in 0..NTESTS {
                 function.tests.push(generate_test(function, rng));
             }
         }

         fn generate_test<R: Rng>(function: &Function, rng: &mut R) -> Test {
             let mut inputs = function
                 .args
                 .iter()
                 .map(|ty| ty.gen_i64(rng))
                 .collect::<Vec<_>>();

             // First argument to this function appears to be a number of
             // iterations, so passing in massive random numbers causes it to
             // take forever to execute, so make sure we're not running random
             // math code until the heat death of the universe.
             if function.name == "jn" || function.name == "jnf" {
                 inputs[0] &= 0xffff;
             }

             Test {
                 inputs,
                 // zero output for now since we'll generate it later
                 outputs: vec![],
             }
         }
     }

     impl Ty {
         fn gen_i64<R: Rng>(&self, r: &mut R) -> i64 {
             use std::f32;
             use std::f64;

             return match self {
                 Ty::F32 => {
                     if r.gen_range(0, 20) < 1 {
                         let i = *[f32::NAN, f32::INFINITY, f32::NEG_INFINITY]
                             .choose(r)
                             .unwrap();
                         i.to_bits().into()
                     } else {
                         r.gen::<f32>().to_bits().into()
                     }
                 }
                 Ty::F64 => {
                     if r.gen_range(0, 20) < 1 {
                         let i = *[f64::NAN, f64::INFINITY, f64::NEG_INFINITY]
                             .choose(r)
                             .unwrap();
                         i.to_bits() as i64
                     } else {
                         r.gen::<f64>().to_bits() as i64
                     }
                 }
                 Ty::I32 => {
                     if r.gen_range(0, 10) < 1 {
                         let i = *[i32::max_value(), 0, i32::min_value()].choose(r).unwrap();
                         i.into()
                     } else {
                         r.gen::<i32>().into()
                     }
                 }
                 Ty::Bool => r.gen::<bool>() as i64,
             };
         }

         fn libc_ty(&self) -> &'static str {
             match self {
                 Ty::F32 => "f32",
                 Ty::F64 => "f64",
                 Ty::I32 => "i32",
                 Ty::Bool => "i32",
             }
         }

         fn libc_pty(&self) -> &'static str {
             match self {
                 Ty::F32 => "*mut f32",
                 Ty::F64 => "*mut f64",
                 Ty::I32 => "*mut i32",
                 Ty::Bool => "*mut i32",
             }
         }

         fn default(&self) -> &'static str {
             match self {
                 Ty::F32 => "0_f32",
                 Ty::F64 => "0_f64",
                 Ty::I32 => "0_i32",
                 Ty::Bool => "false",
             }
         }

         fn to_i64(&self) -> &'static str {
             match self {
                 Ty::F32 => ".to_bits() as i64",
                 Ty::F64 => ".to_bits() as i64",
                 Ty::I32 => " as i64",
                 Ty::Bool => " as i64",
             }
         }
     }

     fn generate_test_outputs(functions: &mut [Function]) {
         let mut src = String::new();
         let dst = std::env::var("OUT_DIR").unwrap();

         // Generate a program which will run all tests with all inputs in
         // `functions`. This program will write all outputs to stdout (in a
         // binary format).
         src.push_str("use std::io::Write;");
         src.push_str("fn main() {");
         src.push_str("let mut result = Vec::new();");
         for function in functions.iter_mut() {
             src.push_str("unsafe {");
             src.push_str("extern { fn ");
             src.push_str(&function.name);
             src.push_str("(");

             let (ret, retptr) = match function.name.as_str() {
                 "sincos" | "sincosf" => (None, &function.ret[..]),
                 _ => (Some(&function.ret[0]), &function.ret[1..]),
             };
             for (i, arg) in function.args.iter().enumerate() {
                 src.push_str(&format!("arg{}: {},", i, arg.libc_ty()));
             }
             for (i, ret) in retptr.iter().enumerate() {
                 src.push_str(&format!("argret{}: {},", i, ret.libc_pty()));
             }
             src.push_str(")");
             if let Some(ty) = ret {
                 src.push_str(" -> ");
                 src.push_str(ty.libc_ty());
             }
             src.push_str("; }");

             src.push_str(&format!("static TESTS: &[[i64; {}]]", function.args.len()));
             src.push_str(" = &[");
             for test in function.tests.iter() {
                 src.push_str("[");
                 for val in test.inputs.iter() {
                     src.push_str(&val.to_string());
                     src.push_str(",");
                 }
                 src.push_str("],");
             }
             src.push_str("];");

             src.push_str("for test in TESTS {");
             for (i, arg) in retptr.iter().enumerate() {
                 src.push_str(&format!("let mut argret{} = {};", i, arg.default()));
             }
             src.push_str("let output = ");
             src.push_str(&function.name);
             src.push_str("(");
             for (i, arg) in function.args.iter().enumerate() {
                 src.push_str(&match arg {
                     Ty::F32 => format!("f32::from_bits(test[{}] as u32)", i),
                     Ty::F64 => format!("f64::from_bits(test[{}] as u64)", i),
                     Ty::I32 => format!("test[{}] as i32", i),
                     Ty::Bool => format!("test[{}] as i32", i),
                 });
                 src.push_str(",");
             }
             for (i, _) in retptr.iter().enumerate() {
                 src.push_str(&format!("&mut argret{},", i));
             }
             src.push_str(");");
             if let Some(ty) = &ret {
                 src.push_str(&format!("let output = output{};", ty.to_i64()));
                 src.push_str("result.extend_from_slice(&output.to_le_bytes());");
             }

             for (i, ret) in retptr.iter().enumerate() {
                 src.push_str(&format!(
                     "result.extend_from_slice(&(argret{}{}).to_le_bytes());",
                     i,
                     ret.to_i64(),
                 ));
             }
             src.push_str("}");

             src.push_str("}");
         }

         src.push_str("std::io::stdout().write_all(&result).unwrap();");

         src.push_str("}");

         let path = format!("{}/gen.rs", dst);
         fs::write(&path, src).unwrap();

         // Make it somewhat pretty if something goes wrong
         drop(Command::new("rustfmt").arg(&path).status());

         // Compile and execute this tests for the musl target, assuming we're an
         // x86_64 host effectively.
         let status = Command::new("rustc")
             .current_dir(&dst)
             .arg(&path)
             .arg("--target=x86_64-unknown-linux-musl")
             .status()
             .unwrap();
         assert!(status.success());
         let output = Command::new("./gen").current_dir(&dst).output().unwrap();
         assert!(output.status.success());
         assert!(output.stderr.is_empty());

         // Map all the output bytes back to an `i64` and then shove it all into
         // the expected results.
         let mut results = output.stdout.chunks_exact(8).map(|buf| {
             let mut exact = [0; 8];
             exact.copy_from_slice(buf);
             i64::from_le_bytes(exact)
         });

         for f in functions.iter_mut() {
             for test in f.tests.iter_mut() {
                 test.outputs = (0..f.ret.len()).map(|_| results.next().unwrap()).collect();
             }
         }
         assert!(results.next().is_none());
     }

     /// Codegens a file which has a ton of `#[test]` annotations for all the
     /// tests that we generated above.
     fn generate_unit_tests(functions: &[Function]) {
         let mut src = String::new();
         let dst = std::env::var("OUT_DIR").unwrap();

         for function in functions {
             src.push_str("#[test]");
             src.push_str("fn ");
             src.push_str(&function.name);
             src.push_str("_matches_musl() {");
             src.push_str(&format!(
                 "static TESTS: &[([i64; {}], [i64; {}])]",
                 function.args.len(),
                 function.ret.len(),
             ));
             src.push_str(" = &[");
             for test in function.tests.iter() {
                 src.push_str("([");
                 for val in test.inputs.iter() {
                     src.push_str(&val.to_string());
                     src.push_str(",");
                 }
                 src.push_str("],");
                 src.push_str("[");
                 for val in test.outputs.iter() {
                     src.push_str(&val.to_string());
                     src.push_str(",");
                 }
                 src.push_str("],");
                 src.push_str("),");
             }
             src.push_str("];");

             src.push_str("for (test, expected) in TESTS {");
             src.push_str("let output = ");
             src.push_str(&function.name);
             src.push_str("(");
             for (i, arg) in function.args.iter().enumerate() {
                 src.push_str(&match arg {
                     Ty::F32 => format!("f32::from_bits(test[{}] as u32)", i),
                     Ty::F64 => format!("f64::from_bits(test[{}] as u64)", i),
                     Ty::I32 => format!("test[{}] as i32", i),
                     Ty::Bool => format!("test[{}] as i32", i),
                 });
                 src.push_str(",");
             }
             src.push_str(");");

             for (i, ret) in function.ret.iter().enumerate() {
                 let get = if function.ret.len() == 1 {
                     String::new()
                 } else {
                     format!(".{}", i)
                 };
                 src.push_str(&(match ret {
                     Ty::F32 => format!("if _eqf(output{}, f32::from_bits(expected[{}] as u32)).is_ok() {{ continue }}", get, i),
                     Ty::F64 => format!("if _eq(output{}, f64::from_bits(expected[{}] as u64)).is_ok() {{ continue }}", get, i),
                     Ty::I32 => format!("if output{} as i64 == expected[{}] {{ continue }}", get, i),
                     Ty::Bool => unreachable!(),
                 }));
             }

             src.push_str(
                 r#"
                 panic!("INPUT: {:?} EXPECTED: {:?} ACTUAL {:?}", test, expected, output);
             "#,
             );
             src.push_str("}");

             src.push_str("}");
         }

         let path = format!("{}/musl-tests.rs", dst);
         fs::write(&path, src).unwrap();

         // Try to make it somewhat pretty
         drop(Command::new("rustfmt").arg(&path).status());
     }
 }
	use std::env;

	fn main() {
	println!("cargo:rerun-if-changed=build.rs");

	#[cfg(feature = "musl-reference-tests")]
	musl_reference_tests::generate();

	if !cfg!(feature = "checked") {
	let lvl = env::var("OPT_LEVEL").unwrap();
	if lvl != "0" {
	println!("cargo:rustc-cfg=assert_no_panic");
	}
	}
	}

	#[cfg(feature = "musl-reference-tests")]
	mod musl_reference_tests {
	use rand::seq::SliceRandom;
	use rand::Rng;
	use std::fs;
	use std::process::Command;

	// Number of tests to generate for each function
	const NTESTS: usize = 500;

	// These files are all internal functions or otherwise miscellaneous, not
	// defining a function we want to test.
	const IGNORED_FILES: &[&str] = &["fenv.rs"];

	struct Function {
	name: String,
	args: Vec<Ty>,
	ret: Vec<Ty>,
	tests: Vec<Test>,
	}

	enum Ty {
	F32,
	F64,
	I32,
	Bool,
	}

	struct Test {
	inputs: Vec<i64>,
	outputs: Vec<i64>,
	}

	pub fn generate() {
	let files = fs::read_dir("src/math")
	.unwrap()
	.map(\|f\| f.unwrap().path())
	.collect::<Vec<_>>();

	let mut math = Vec::new();
	for file in files {
	if IGNORED_FILES.iter().any(\|f\| file.ends_with(f)) {
	continue;
	}

	println!("generating musl reference tests in {:?}", file);

	let contents = fs::read_to_string(file).unwrap();
	let mut functions = contents.lines().filter(\|f\| f.starts_with("pub fn"));
	while let Some(function_to_test) = functions.next() {
	math.push(parse(function_to_test));
	}
	}

	// Generate a bunch of random inputs for each function. This will
	// attempt to generate a good set of uniform test cases for exercising
	// all the various functionality.
	generate_random_tests(&mut math, &mut rand::thread_rng());

	// After we have all our inputs, use the x86_64-unknown-linux-musl
	// target to generate the expected output.
	generate_test_outputs(&mut math);
	//panic!("Boo");
	// ... and now that we have both inputs and expected outputs, do a bunch
	// of codegen to create the unit tests which we'll actually execute.
	generate_unit_tests(&math);
	}

	/// A "poor man's" parser for the signature of a function
	fn parse(s: &str) -> Function {
	let s = eat(s, "pub fn ");
	let pos = s.find('(').unwrap();
	let name = &s[..pos];
	let s = &s[pos + 1..];
	let end = s.find(')').unwrap();
	let args = s[..end]
	.split(',')
	.map(\|arg\| {
	let colon = arg.find(':').unwrap();
	parse_ty(arg[colon + 1..].trim())
	})
	.collect::<Vec<_>>();
	let tail = &s[end + 1..];
	let tail = eat(tail, " -> ");
	let ret = parse_retty(tail.replace("{", "").trim());

	return Function {
	name: name.to_string(),
	args,
	ret,
	tests: Vec::new(),
	};

	fn parse_ty(s: &str) -> Ty {
	match s {
	"f32" => Ty::F32,
	"f64" => Ty::F64,
	"i32" => Ty::I32,
	"bool" => Ty::Bool,
	other => panic!("unknown type `{}`", other),
	}
	}

	fn parse_retty(s: &str) -> Vec<Ty> {
	match s {
	"(f32, f32)" => vec![Ty::F32, Ty::F32],
	"(f32, i32)" => vec![Ty::F32, Ty::I32],
	"(f64, f64)" => vec![Ty::F64, Ty::F64],
	"(f64, i32)" => vec![Ty::F64, Ty::I32],
	other => vec![parse_ty(other)],
	}
	}

	fn eat<'a>(s: &'a str, prefix: &str) -> &'a str {
	if s.starts_with(prefix) {
	&s[prefix.len()..]
	} else {
	panic!("{:?} didn't start with {:?}", s, prefix)
	}
	}
	}

	fn generate_random_tests<R: Rng>(functions: &mut [Function], rng: &mut R) {
	for function in functions {
	for _ in 0..NTESTS {
	function.tests.push(generate_test(function, rng));
	}
	}

	fn generate_test<R: Rng>(function: &Function, rng: &mut R) -> Test {
	let mut inputs = function
	.args
	.iter()
	.map(\|ty\| ty.gen_i64(rng))
	.collect::<Vec<_>>();

	// First argument to this function appears to be a number of
	// iterations, so passing in massive random numbers causes it to
	// take forever to execute, so make sure we're not running random
	// math code until the heat death of the universe.
	if function.name == "jn" \|\| function.name == "jnf" {
	inputs[0] &= 0xffff;
	}

	Test {
	inputs,
	// zero output for now since we'll generate it later
	outputs: vec![],
	}
	}
	}

	impl Ty {
	fn gen_i64<R: Rng>(&self, r: &mut R) -> i64 {
	use std::f32;
	use std::f64;

	return match self {
	Ty::F32 => {
	if r.gen_range(0, 20) < 1 {
	let i = *[f32::NAN, f32::INFINITY, f32::NEG_INFINITY]
	.choose(r)
	.unwrap();
	i.to_bits().into()
	} else {
	r.gen::<f32>().to_bits().into()
	}
	}
	Ty::F64 => {
	if r.gen_range(0, 20) < 1 {
	let i = *[f64::NAN, f64::INFINITY, f64::NEG_INFINITY]
	.choose(r)
	.unwrap();
	i.to_bits() as i64
	} else {
	r.gen::<f64>().to_bits() as i64
	}
	}
	Ty::I32 => {
	if r.gen_range(0, 10) < 1 {
	let i = *[i32::max_value(), 0, i32::min_value()].choose(r).unwrap();
	i.into()
	} else {
	r.gen::<i32>().into()
	}
	}
	Ty::Bool => r.gen::<bool>() as i64,
	};
	}

	fn libc_ty(&self) -> &'static str {
	match self {
	Ty::F32 => "f32",
	Ty::F64 => "f64",
	Ty::I32 => "i32",
	Ty::Bool => "i32",
	}
	}

	fn libc_pty(&self) -> &'static str {
	match self {
	Ty::F32 => "*mut f32",
	Ty::F64 => "*mut f64",
	Ty::I32 => "*mut i32",
	Ty::Bool => "*mut i32",
	}
	}

	fn default(&self) -> &'static str {
	match self {
	Ty::F32 => "0_f32",
	Ty::F64 => "0_f64",
	Ty::I32 => "0_i32",
	Ty::Bool => "false",
	}
	}

	fn to_i64(&self) -> &'static str {
	match self {
	Ty::F32 => ".to_bits() as i64",
	Ty::F64 => ".to_bits() as i64",
	Ty::I32 => " as i64",
	Ty::Bool => " as i64",
	}
	}
	}

	fn generate_test_outputs(functions: &mut [Function]) {
	let mut src = String::new();
	let dst = std::env::var("OUT_DIR").unwrap();

	// Generate a program which will run all tests with all inputs in
	// `functions`. This program will write all outputs to stdout (in a
	// binary format).
	src.push_str("use std::io::Write;");
	src.push_str("fn main() {");
	src.push_str("let mut result = Vec::new();");
	for function in functions.iter_mut() {
	src.push_str("unsafe {");
	src.push_str("extern { fn ");
	src.push_str(&function.name);
	src.push_str("(");

	let (ret, retptr) = match function.name.as_str() {
	"sincos" \| "sincosf" => (None, &function.ret[..]),
	_ => (Some(&function.ret[0]), &function.ret[1..]),
	};
	for (i, arg) in function.args.iter().enumerate() {
	src.push_str(&format!("arg{}: {},", i, arg.libc_ty()));
	}
	for (i, ret) in retptr.iter().enumerate() {
	src.push_str(&format!("argret{}: {},", i, ret.libc_pty()));
	}
	src.push_str(")");
	if let Some(ty) = ret {
	src.push_str(" -> ");
	src.push_str(ty.libc_ty());
	}
	src.push_str("; }");

	src.push_str(&format!("static TESTS: &[[i64; {}]]", function.args.len()));
	src.push_str(" = &[");
	for test in function.tests.iter() {
	src.push_str("[");
	for val in test.inputs.iter() {
	src.push_str(&val.to_string());
	src.push_str(",");
	}
	src.push_str("],");
	}
	src.push_str("];");

	src.push_str("for test in TESTS {");
	for (i, arg) in retptr.iter().enumerate() {
	src.push_str(&format!("let mut argret{} = {};", i, arg.default()));
	}
	src.push_str("let output = ");
	src.push_str(&function.name);
	src.push_str("(");
	for (i, arg) in function.args.iter().enumerate() {
	src.push_str(&match arg {
	Ty::F32 => format!("f32::from_bits(test[{}] as u32)", i),
	Ty::F64 => format!("f64::from_bits(test[{}] as u64)", i),
	Ty::I32 => format!("test[{}] as i32", i),
	Ty::Bool => format!("test[{}] as i32", i),
	});
	src.push_str(",");
	}
	for (i, _) in retptr.iter().enumerate() {
	src.push_str(&format!("&mut argret{},", i));
	}
	src.push_str(");");
	if let Some(ty) = &ret {
	src.push_str(&format!("let output = output{};", ty.to_i64()));
	src.push_str("result.extend_from_slice(&output.to_le_bytes());");
	}

	for (i, ret) in retptr.iter().enumerate() {
	src.push_str(&format!(
	"result.extend_from_slice(&(argret{}{}).to_le_bytes());",
	i,
	ret.to_i64(),
	));
	}
	src.push_str("}");

	src.push_str("}");
	}

	src.push_str("std::io::stdout().write_all(&result).unwrap();");

	src.push_str("}");

	let path = format!("{}/gen.rs", dst);
	fs::write(&path, src).unwrap();

	// Make it somewhat pretty if something goes wrong
	drop(Command::new("rustfmt").arg(&path).status());

	// Compile and execute this tests for the musl target, assuming we're an
	// x86_64 host effectively.
	let status = Command::new("rustc")
	.current_dir(&dst)
	.arg(&path)
	.arg("--target=x86_64-unknown-linux-musl")
	.status()
	.unwrap();
	assert!(status.success());
	let output = Command::new("./gen").current_dir(&dst).output().unwrap();
	assert!(output.status.success());
	assert!(output.stderr.is_empty());

	// Map all the output bytes back to an `i64` and then shove it all into
	// the expected results.
	let mut results = output.stdout.chunks_exact(8).map(\|buf\| {
	let mut exact = [0; 8];
	exact.copy_from_slice(buf);
	i64::from_le_bytes(exact)
	});

	for f in functions.iter_mut() {
	for test in f.tests.iter_mut() {
	test.outputs = (0..f.ret.len()).map(\|_\| results.next().unwrap()).collect();
	}
	}
	assert!(results.next().is_none());
	}

	/// Codegens a file which has a ton of `#[test]` annotations for all the
	/// tests that we generated above.
	fn generate_unit_tests(functions: &[Function]) {
	let mut src = String::new();
	let dst = std::env::var("OUT_DIR").unwrap();

	for function in functions {
	src.push_str("#[test]");
	src.push_str("fn ");
	src.push_str(&function.name);
	src.push_str("_matches_musl() {");
	src.push_str(&format!(
	"static TESTS: &[([i64; {}], [i64; {}])]",
	function.args.len(),
	function.ret.len(),
	));
	src.push_str(" = &[");
	for test in function.tests.iter() {
	src.push_str("([");
	for val in test.inputs.iter() {
	src.push_str(&val.to_string());
	src.push_str(",");
	}
	src.push_str("],");
	src.push_str("[");
	for val in test.outputs.iter() {
	src.push_str(&val.to_string());
	src.push_str(",");
	}
	src.push_str("],");
	src.push_str("),");
	}
	src.push_str("];");

	src.push_str("for (test, expected) in TESTS {");
	src.push_str("let output = ");
	src.push_str(&function.name);
	src.push_str("(");
	for (i, arg) in function.args.iter().enumerate() {
	src.push_str(&match arg {
	Ty::F32 => format!("f32::from_bits(test[{}] as u32)", i),
	Ty::F64 => format!("f64::from_bits(test[{}] as u64)", i),
	Ty::I32 => format!("test[{}] as i32", i),
	Ty::Bool => format!("test[{}] as i32", i),
	});
	src.push_str(",");
	}
	src.push_str(");");

	for (i, ret) in function.ret.iter().enumerate() {
	let get = if function.ret.len() == 1 {
	String::new()
	} else {
	format!(".{}", i)
	};
	src.push_str(&(match ret {
	Ty::F32 => format!("if _eqf(output{}, f32::from_bits(expected[{}] as u32)).is_ok() {{ continue }}", get, i),
	Ty::F64 => format!("if _eq(output{}, f64::from_bits(expected[{}] as u64)).is_ok() {{ continue }}", get, i),
	Ty::I32 => format!("if output{} as i64 == expected[{}] {{ continue }}", get, i),
	Ty::Bool => unreachable!(),
	}));
	}

	src.push_str(
	r#"
	panic!("INPUT: {:?} EXPECTED: {:?} ACTUAL {:?}", test, expected, output);
	"#,
	);
	src.push_str("}");

	src.push_str("}");
	}

	let path = format!("{}/musl-tests.rs", dst);
	fs::write(&path, src).unwrap();

	// Try to make it somewhat pretty
	drop(Command::new("rustfmt").arg(&path).status());
	}
	}