src/librustc_trans/trans/cabi.rs - third_party/rust - Git at Google

 // Copyright 2012-2015 The Rust Project Developers. See the COPYRIGHT
 // file at the top-level directory of this distribution and at
 // http://rust-lang.org/COPYRIGHT.
 //
 // Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
 // http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
 // <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
 // option. This file may not be copied, modified, or distributed
 // except according to those terms.

 pub use self::ArgKind::*;

 use llvm::Attribute;
 use std::option;
 use trans::context::CrateContext;
 use trans::cabi_x86;
 use trans::cabi_x86_64;
 use trans::cabi_x86_win64;
 use trans::cabi_arm;
 use trans::cabi_aarch64;
 use trans::cabi_powerpc;
 use trans::cabi_powerpc64;
 use trans::cabi_mips;
 use trans::type_::Type;

 #[derive(Clone, Copy, PartialEq)]
 pub enum ArgKind {
     /// Pass the argument directly using the normal converted
     /// LLVM type or by coercing to another specified type
     Direct,
     /// Pass the argument indirectly via a hidden pointer
     Indirect,
     /// Ignore the argument (useful for empty struct)
     Ignore,
 }

 /// Information about how a specific C type
 /// should be passed to or returned from a function
 ///
 /// This is borrowed from clang's ABIInfo.h
 #[derive(Clone, Copy)]
 pub struct ArgType {
     pub kind: ArgKind,
     /// Original LLVM type
     pub ty: Type,
     /// Coerced LLVM Type
     pub cast: option::Option<Type>,
     /// Dummy argument, which is emitted before the real argument
     pub pad: option::Option<Type>,
     /// LLVM attribute of argument
     pub attr: option::Option<Attribute>
 }

 impl ArgType {
     pub fn direct(ty: Type, cast: option::Option<Type>,
                             pad: option::Option<Type>,
                             attr: option::Option<Attribute>) -> ArgType {
         ArgType {
             kind: Direct,
             ty: ty,
             cast: cast,
             pad: pad,
             attr: attr
         }
     }

     pub fn indirect(ty: Type, attr: option::Option<Attribute>) -> ArgType {
         ArgType {
             kind: Indirect,
             ty: ty,
             cast: option::Option::None,
             pad: option::Option::None,
             attr: attr
         }
     }

     pub fn ignore(ty: Type) -> ArgType {
         ArgType {
             kind: Ignore,
             ty: ty,
             cast: None,
             pad: None,
             attr: None,
         }
     }

     pub fn is_indirect(&self) -> bool {
         return self.kind == Indirect;
     }

     pub fn is_ignore(&self) -> bool {
         return self.kind == Ignore;
     }
 }

 /// Metadata describing how the arguments to a native function
 /// should be passed in order to respect the native ABI.
 ///
 /// I will do my best to describe this structure, but these
 /// comments are reverse-engineered and may be inaccurate. -NDM
 pub struct FnType {
     /// The LLVM types of each argument.
     pub arg_tys: Vec<ArgType> ,

     /// LLVM return type.
     pub ret_ty: ArgType,
 }

 pub fn compute_abi_info(ccx: &CrateContext,
                         atys: &[Type],
                         rty: Type,
                         ret_def: bool) -> FnType {
     match &ccx.sess().target.target.arch[..] {
         "x86" => cabi_x86::compute_abi_info(ccx, atys, rty, ret_def),
         "x86_64" => if ccx.sess().target.target.options.is_like_windows {
             cabi_x86_win64::compute_abi_info(ccx, atys, rty, ret_def)
         } else {
             cabi_x86_64::compute_abi_info(ccx, atys, rty, ret_def)
         },
         "aarch64" => cabi_aarch64::compute_abi_info(ccx, atys, rty, ret_def),
         "arm" => {
             let flavor = if ccx.sess().target.target.target_os == "ios" {
                 cabi_arm::Flavor::Ios
             } else {
                 cabi_arm::Flavor::General
             };
             cabi_arm::compute_abi_info(ccx, atys, rty, ret_def, flavor)
         },
         "mips" => cabi_mips::compute_abi_info(ccx, atys, rty, ret_def),
         "powerpc" => cabi_powerpc::compute_abi_info(ccx, atys, rty, ret_def),
         "powerpc64" | "powerpc64le" => cabi_powerpc64::compute_abi_info(ccx, atys, rty, ret_def),
         a => ccx.sess().fatal(&format!("unrecognized arch \"{}\" in target specification", a)
                               ),
     }
 }
	// Copyright 2012-2015 The Rust Project Developers. See the COPYRIGHT
	// file at the top-level directory of this distribution and at
	// http://rust-lang.org/COPYRIGHT.
	//
	// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
	// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
	// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
	// option. This file may not be copied, modified, or distributed
	// except according to those terms.

	pub use self::ArgKind::*;

	use llvm::Attribute;
	use std::option;
	use trans::context::CrateContext;
	use trans::cabi_x86;
	use trans::cabi_x86_64;
	use trans::cabi_x86_win64;
	use trans::cabi_arm;
	use trans::cabi_aarch64;
	use trans::cabi_powerpc;
	use trans::cabi_powerpc64;
	use trans::cabi_mips;
	use trans::type_::Type;

	#[derive(Clone, Copy, PartialEq)]
	pub enum ArgKind {
	/// Pass the argument directly using the normal converted
	/// LLVM type or by coercing to another specified type
	Direct,
	/// Pass the argument indirectly via a hidden pointer
	Indirect,
	/// Ignore the argument (useful for empty struct)
	Ignore,
	}

	/// Information about how a specific C type
	/// should be passed to or returned from a function
	///
	/// This is borrowed from clang's ABIInfo.h
	#[derive(Clone, Copy)]
	pub struct ArgType {
	pub kind: ArgKind,
	/// Original LLVM type
	pub ty: Type,
	/// Coerced LLVM Type
	pub cast: option::Option<Type>,
	/// Dummy argument, which is emitted before the real argument
	pub pad: option::Option<Type>,
	/// LLVM attribute of argument
	pub attr: option::Option<Attribute>
	}

	impl ArgType {
	pub fn direct(ty: Type, cast: option::Option<Type>,
	pad: option::Option<Type>,
	attr: option::Option<Attribute>) -> ArgType {
	ArgType {
	kind: Direct,
	ty: ty,
	cast: cast,
	pad: pad,
	attr: attr
	}
	}

	pub fn indirect(ty: Type, attr: option::Option<Attribute>) -> ArgType {
	ArgType {
	kind: Indirect,
	ty: ty,
	cast: option::Option::None,
	pad: option::Option::None,
	attr: attr
	}
	}

	pub fn ignore(ty: Type) -> ArgType {
	ArgType {
	kind: Ignore,
	ty: ty,
	cast: None,
	pad: None,
	attr: None,
	}
	}

	pub fn is_indirect(&self) -> bool {
	return self.kind == Indirect;
	}

	pub fn is_ignore(&self) -> bool {
	return self.kind == Ignore;
	}
	}

	/// Metadata describing how the arguments to a native function
	/// should be passed in order to respect the native ABI.
	///
	/// I will do my best to describe this structure, but these
	/// comments are reverse-engineered and may be inaccurate. -NDM
	pub struct FnType {
	/// The LLVM types of each argument.
	pub arg_tys: Vec<ArgType> ,

	/// LLVM return type.
	pub ret_ty: ArgType,
	}

	pub fn compute_abi_info(ccx: &CrateContext,
	atys: &[Type],
	rty: Type,
	ret_def: bool) -> FnType {
	match &ccx.sess().target.target.arch[..] {
	"x86" => cabi_x86::compute_abi_info(ccx, atys, rty, ret_def),
	"x86_64" => if ccx.sess().target.target.options.is_like_windows {
	cabi_x86_win64::compute_abi_info(ccx, atys, rty, ret_def)
	} else {
	cabi_x86_64::compute_abi_info(ccx, atys, rty, ret_def)
	},
	"aarch64" => cabi_aarch64::compute_abi_info(ccx, atys, rty, ret_def),
	"arm" => {
	let flavor = if ccx.sess().target.target.target_os == "ios" {
	cabi_arm::Flavor::Ios
	} else {
	cabi_arm::Flavor::General
	};
	cabi_arm::compute_abi_info(ccx, atys, rty, ret_def, flavor)
	},
	"mips" => cabi_mips::compute_abi_info(ccx, atys, rty, ret_def),
	"powerpc" => cabi_powerpc::compute_abi_info(ccx, atys, rty, ret_def),
	"powerpc64" \| "powerpc64le" => cabi_powerpc64::compute_abi_info(ccx, atys, rty, ret_def),
	a => ccx.sess().fatal(&format!("unrecognized arch \"{}\" in target specification", a)
	),
	}
	}