1296 lines
51 KiB
Rust
1296 lines
51 KiB
Rust
// Copyright 2012-2013 The Rust Project Developers. See the COPYRIGHT
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// file at the top-level directory of this distribution and at
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// http://rust-lang.org/COPYRIGHT.
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//
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// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
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// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
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// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
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// option. This file may not be copied, modified, or distributed
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// except according to those terms.
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use core::prelude::*;
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use back::{link, abi};
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use lib::llvm::{SequentiallyConsistent, Acquire, Release, Xchg};
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use lib::llvm::{TypeRef, ValueRef};
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use lib;
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use middle::trans::base::*;
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use middle::trans::cabi;
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use middle::trans::cabi_x86;
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use middle::trans::cabi_x86_64;
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use middle::trans::cabi_arm;
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use middle::trans::cabi_mips;
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use middle::trans::build::*;
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use middle::trans::callee::*;
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use middle::trans::common::*;
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use middle::trans::datum::*;
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use middle::trans::expr::Ignore;
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use middle::trans::machine::llsize_of;
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use middle::trans::glue;
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use middle::trans::machine;
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use middle::trans::type_of::*;
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use middle::trans::type_of;
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use middle::ty;
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use middle::ty::{FnSig, arg};
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use util::ppaux::ty_to_str;
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use syntax::codemap::span;
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use syntax::{ast, ast_util};
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use syntax::{attr, ast_map};
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use syntax::opt_vec;
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use syntax::parse::token::special_idents;
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use syntax::abi::{X86, X86_64, Arm, Mips};
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use syntax::abi::{RustIntrinsic, Rust, Stdcall, Fastcall,
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Cdecl, Aapcs, C};
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fn abi_info(ccx: @CrateContext) -> @cabi::ABIInfo {
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return match ccx.sess.targ_cfg.arch {
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X86 => cabi_x86::abi_info(ccx),
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X86_64 => cabi_x86_64::abi_info(),
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Arm => cabi_arm::abi_info(),
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Mips => cabi_mips::abi_info(),
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}
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}
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pub fn link_name(ccx: @CrateContext, i: @ast::foreign_item) -> @~str {
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match attr::first_attr_value_str_by_name(i.attrs, ~"link_name") {
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None => ccx.sess.str_of(i.ident),
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Some(ln) => ln,
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}
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}
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struct ShimTypes {
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fn_sig: ty::FnSig,
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/// LLVM types that will appear on the foreign function
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llsig: LlvmSignature,
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/// True if there is a return value (not bottom, not unit)
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ret_def: bool,
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/// Type of the struct we will use to shuttle values back and forth.
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/// This is always derived from the llsig.
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bundle_ty: TypeRef,
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/// Type of the shim function itself.
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shim_fn_ty: TypeRef,
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/// Adapter object for handling native ABI rules (trust me, you
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/// don't want to know).
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fn_ty: cabi::FnType
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}
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struct LlvmSignature {
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llarg_tys: ~[TypeRef],
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llret_ty: TypeRef,
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sret: bool,
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}
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fn foreign_signature(ccx: @CrateContext, fn_sig: &ty::FnSig)
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-> LlvmSignature {
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/*!
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* The ForeignSignature is the LLVM types of the arguments/return type
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* of a function. Note that these LLVM types are not quite the same
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* as the LLVM types would be for a native Rust function because foreign
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* functions just plain ignore modes. They also don't pass aggregate
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* values by pointer like we do.
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*/
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let llarg_tys = fn_sig.inputs.map(|arg| type_of(ccx, arg.ty));
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let llret_ty = type_of::type_of(ccx, fn_sig.output);
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LlvmSignature {
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llarg_tys: llarg_tys,
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llret_ty: llret_ty,
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sret: !ty::type_is_immediate(fn_sig.output),
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}
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}
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fn shim_types(ccx: @CrateContext, id: ast::node_id) -> ShimTypes {
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let fn_sig = match ty::get(ty::node_id_to_type(ccx.tcx, id)).sty {
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ty::ty_bare_fn(ref fn_ty) => copy fn_ty.sig,
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_ => ccx.sess.bug(~"c_arg_and_ret_lltys called on non-function type")
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};
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let llsig = foreign_signature(ccx, &fn_sig);
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let bundle_ty = T_struct(vec::append_one(copy llsig.llarg_tys,
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T_ptr(llsig.llret_ty)),
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false);
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let ret_def = !ty::type_is_bot(fn_sig.output) &&
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!ty::type_is_nil(fn_sig.output);
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let fn_ty = abi_info(ccx).compute_info(llsig.llarg_tys,
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llsig.llret_ty,
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ret_def);
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ShimTypes {
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fn_sig: fn_sig,
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llsig: llsig,
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ret_def: ret_def,
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bundle_ty: bundle_ty,
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shim_fn_ty: T_fn(~[T_ptr(bundle_ty)], T_nil()),
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fn_ty: fn_ty
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}
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}
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type shim_arg_builder<'self> =
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&'self fn(bcx: block, tys: &ShimTypes,
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llargbundle: ValueRef) -> ~[ValueRef];
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type shim_ret_builder<'self> =
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&'self fn(bcx: block, tys: &ShimTypes,
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llargbundle: ValueRef,
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llretval: ValueRef);
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fn build_shim_fn_(ccx: @CrateContext,
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shim_name: ~str,
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llbasefn: ValueRef,
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tys: &ShimTypes,
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cc: lib::llvm::CallConv,
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arg_builder: shim_arg_builder,
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ret_builder: shim_ret_builder)
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-> ValueRef {
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let llshimfn = decl_internal_cdecl_fn(
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ccx.llmod, shim_name, tys.shim_fn_ty);
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// Declare the body of the shim function:
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let fcx = new_fn_ctxt(ccx, ~[], llshimfn, tys.fn_sig.output, None);
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let bcx = top_scope_block(fcx, None);
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let lltop = bcx.llbb;
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let llargbundle = get_param(llshimfn, 0u);
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let llargvals = arg_builder(bcx, tys, llargbundle);
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// Create the call itself and store the return value:
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let llretval = CallWithConv(bcx, llbasefn, llargvals, cc);
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ret_builder(bcx, tys, llargbundle, llretval);
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// Don't finish up the function in the usual way, because this doesn't
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// follow the normal Rust calling conventions.
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tie_up_header_blocks(fcx, lltop);
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let ret_cx = raw_block(fcx, false, fcx.llreturn);
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Ret(ret_cx, C_null(T_nil()));
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return llshimfn;
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}
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type wrap_arg_builder<'self> = &'self fn(bcx: block,
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tys: &ShimTypes,
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llwrapfn: ValueRef,
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llargbundle: ValueRef);
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type wrap_ret_builder<'self> = &'self fn(bcx: block,
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tys: &ShimTypes,
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llargbundle: ValueRef);
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fn build_wrap_fn_(ccx: @CrateContext,
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tys: &ShimTypes,
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llshimfn: ValueRef,
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llwrapfn: ValueRef,
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shim_upcall: ValueRef,
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needs_c_return: bool,
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arg_builder: wrap_arg_builder,
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ret_builder: wrap_ret_builder) {
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let _icx = ccx.insn_ctxt("foreign::build_wrap_fn_");
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let fcx = new_fn_ctxt(ccx, ~[], llwrapfn, tys.fn_sig.output, None);
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// Patch up the return type if it's not immediate and we're returning via
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// the C ABI.
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if needs_c_return && !ty::type_is_immediate(tys.fn_sig.output) {
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let lloutputtype = type_of::type_of(*fcx.ccx, tys.fn_sig.output);
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fcx.llretptr = Some(alloca(raw_block(fcx, false, fcx.llstaticallocas),
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lloutputtype));
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}
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let bcx = top_scope_block(fcx, None);
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let lltop = bcx.llbb;
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// Allocate the struct and write the arguments into it.
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let llargbundle = alloca(bcx, tys.bundle_ty);
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arg_builder(bcx, tys, llwrapfn, llargbundle);
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// Create call itself.
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let llshimfnptr = PointerCast(bcx, llshimfn, T_ptr(T_i8()));
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let llrawargbundle = PointerCast(bcx, llargbundle, T_ptr(T_i8()));
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Call(bcx, shim_upcall, ~[llrawargbundle, llshimfnptr]);
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ret_builder(bcx, tys, llargbundle);
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// Perform a custom version of `finish_fn`. First, tie up the header
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// blocks.
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tie_up_header_blocks(fcx, lltop);
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// Then return according to the C ABI.
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unsafe {
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let return_context = raw_block(fcx, false, fcx.llreturn);
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let llfunctiontype = val_ty(llwrapfn);
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let llfunctiontype =
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::lib::llvm::llvm::LLVMGetElementType(llfunctiontype);
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let llfunctionreturntype =
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::lib::llvm::llvm::LLVMGetReturnType(llfunctiontype);
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if ::lib::llvm::llvm::LLVMGetTypeKind(llfunctionreturntype) ==
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::lib::llvm::Void {
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// XXX: This might be wrong if there are any functions for which
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// the C ABI specifies a void output pointer and the Rust ABI
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// does not.
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RetVoid(return_context);
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} else {
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// Cast if we have to...
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// XXX: This is ugly.
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let llretptr = BitCast(return_context,
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fcx.llretptr.get(),
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T_ptr(llfunctionreturntype));
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Ret(return_context, Load(return_context, llretptr));
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}
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}
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}
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// For each foreign function F, we generate a wrapper function W and a shim
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// function S that all work together. The wrapper function W is the function
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// that other rust code actually invokes. Its job is to marshall the
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// arguments into a struct. It then uses a small bit of assembly to switch
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// over to the C stack and invoke the shim function. The shim function S then
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// unpacks the arguments from the struct and invokes the actual function F
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// according to its specified calling convention.
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//
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// Example: Given a foreign c-stack function F(x: X, y: Y) -> Z,
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// we generate a wrapper function W that looks like:
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//
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// void W(Z* dest, void *env, X x, Y y) {
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// struct { X x; Y y; Z *z; } args = { x, y, z };
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// call_on_c_stack_shim(S, &args);
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// }
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//
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// The shim function S then looks something like:
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//
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// void S(struct { X x; Y y; Z *z; } *args) {
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// *args->z = F(args->x, args->y);
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// }
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//
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// However, if the return type of F is dynamically sized or of aggregate type,
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// the shim function looks like:
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//
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// void S(struct { X x; Y y; Z *z; } *args) {
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// F(args->z, args->x, args->y);
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// }
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//
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// Note: on i386, the layout of the args struct is generally the same
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// as the desired layout of the arguments on the C stack. Therefore,
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// we could use upcall_alloc_c_stack() to allocate the `args`
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// structure and switch the stack pointer appropriately to avoid a
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// round of copies. (In fact, the shim function itself is
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// unnecessary). We used to do this, in fact, and will perhaps do so
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// in the future.
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pub fn trans_foreign_mod(ccx: @CrateContext,
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path: &ast_map::path,
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foreign_mod: &ast::foreign_mod) {
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let _icx = ccx.insn_ctxt("foreign::trans_foreign_mod");
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let arch = ccx.sess.targ_cfg.arch;
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let abi = match foreign_mod.abis.for_arch(arch) {
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None => {
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ccx.sess.fatal(
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fmt!("No suitable ABI for target architecture \
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in module %s",
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ast_map::path_to_str(*path,
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ccx.sess.intr())));
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}
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Some(abi) => abi,
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};
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for vec::each(foreign_mod.items) |&foreign_item| {
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match foreign_item.node {
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ast::foreign_item_fn(*) => {
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let id = foreign_item.id;
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match abi {
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RustIntrinsic => {
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// Intrinsics are emitted by monomorphic fn
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}
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Rust => {
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// FIXME(#3678) Implement linking to foreign fns with Rust ABI
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ccx.sess.unimpl(
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fmt!("Foreign functions with Rust ABI"));
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}
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Stdcall => {
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build_foreign_fn(ccx, id, foreign_item,
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lib::llvm::X86StdcallCallConv);
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}
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Fastcall => {
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build_foreign_fn(ccx, id, foreign_item,
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lib::llvm::X86FastcallCallConv);
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}
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Cdecl => {
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// FIXME(#3678) should really be more specific
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build_foreign_fn(ccx, id, foreign_item,
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lib::llvm::CCallConv);
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}
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Aapcs => {
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// FIXME(#3678) should really be more specific
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build_foreign_fn(ccx, id, foreign_item,
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lib::llvm::CCallConv);
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}
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C => {
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build_foreign_fn(ccx, id, foreign_item,
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lib::llvm::CCallConv);
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}
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}
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}
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ast::foreign_item_const(*) => {
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let ident = ccx.sess.parse_sess.interner.get(
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foreign_item.ident);
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ccx.item_symbols.insert(foreign_item.id, copy *ident);
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}
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}
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}
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fn build_foreign_fn(ccx: @CrateContext,
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id: ast::node_id,
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foreign_item: @ast::foreign_item,
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cc: lib::llvm::CallConv) {
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let llwrapfn = get_item_val(ccx, id);
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let tys = shim_types(ccx, id);
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if attr::attrs_contains_name(foreign_item.attrs, "rust_stack") {
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build_direct_fn(ccx, llwrapfn, foreign_item,
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&tys, cc);
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} else if attr::attrs_contains_name(foreign_item.attrs, "fast_ffi") {
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build_fast_ffi_fn(ccx, llwrapfn, foreign_item, &tys, cc);
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} else {
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let llshimfn = build_shim_fn(ccx, foreign_item, &tys, cc);
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build_wrap_fn(ccx, &tys, llshimfn, llwrapfn);
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}
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}
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fn build_shim_fn(ccx: @CrateContext,
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foreign_item: @ast::foreign_item,
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tys: &ShimTypes,
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cc: lib::llvm::CallConv)
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-> ValueRef {
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/*!
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*
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* Build S, from comment above:
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*
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* void S(struct { X x; Y y; Z *z; } *args) {
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* F(args->z, args->x, args->y);
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* }
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*/
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let _icx = ccx.insn_ctxt("foreign::build_shim_fn");
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fn build_args(bcx: block, tys: &ShimTypes, llargbundle: ValueRef)
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-> ~[ValueRef] {
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let _icx = bcx.insn_ctxt("foreign::shim::build_args");
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tys.fn_ty.build_shim_args(bcx, tys.llsig.llarg_tys, llargbundle)
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}
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fn build_ret(bcx: block,
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tys: &ShimTypes,
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llargbundle: ValueRef,
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llretval: ValueRef) {
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let _icx = bcx.insn_ctxt("foreign::shim::build_ret");
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tys.fn_ty.build_shim_ret(bcx,
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tys.llsig.llarg_tys,
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tys.ret_def,
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llargbundle,
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llretval);
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build_return(bcx);
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}
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let lname = link_name(ccx, foreign_item);
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let llbasefn = base_fn(ccx, *lname, tys, cc);
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// Name the shim function
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let shim_name = *lname + ~"__c_stack_shim";
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build_shim_fn_(ccx,
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shim_name,
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llbasefn,
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tys,
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cc,
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build_args,
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build_ret)
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}
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fn base_fn(ccx: @CrateContext,
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lname: &str,
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tys: &ShimTypes,
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cc: lib::llvm::CallConv)
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-> ValueRef {
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// Declare the "prototype" for the base function F:
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do tys.fn_ty.decl_fn |fnty| {
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decl_fn(ccx.llmod, lname, cc, fnty)
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}
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}
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// FIXME (#2535): this is very shaky and probably gets ABIs wrong all
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// over the place
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fn build_direct_fn(ccx: @CrateContext,
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decl: ValueRef,
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item: @ast::foreign_item,
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tys: &ShimTypes,
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cc: lib::llvm::CallConv) {
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debug!("build_direct_fn(%s)", *link_name(ccx, item));
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let fcx = new_fn_ctxt(ccx, ~[], decl, tys.fn_sig.output, None);
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let bcx = top_scope_block(fcx, None), lltop = bcx.llbb;
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let llbasefn = base_fn(ccx, *link_name(ccx, item), tys, cc);
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let ty = ty::lookup_item_type(ccx.tcx,
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ast_util::local_def(item.id)).ty;
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let args = vec::from_fn(ty::ty_fn_args(ty).len(), |i| {
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get_param(decl, i + first_real_arg)
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});
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let retval = Call(bcx, llbasefn, args);
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let ret_ty = ty::ty_fn_ret(ty);
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if !ty::type_is_nil(ret_ty) && !ty::type_is_bot(ret_ty) {
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Store(bcx, retval, fcx.llretptr.get());
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}
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build_return(bcx);
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finish_fn(fcx, lltop);
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}
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// FIXME (#2535): this is very shaky and probably gets ABIs wrong all
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// over the place
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fn build_fast_ffi_fn(ccx: @CrateContext,
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decl: ValueRef,
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item: @ast::foreign_item,
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tys: &ShimTypes,
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cc: lib::llvm::CallConv) {
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debug!("build_fast_ffi_fn(%s)", *link_name(ccx, item));
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let fcx = new_fn_ctxt(ccx, ~[], decl, tys.fn_sig.output, None);
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let bcx = top_scope_block(fcx, None), lltop = bcx.llbb;
|
|
let llbasefn = base_fn(ccx, *link_name(ccx, item), tys, cc);
|
|
set_no_inline(fcx.llfn);
|
|
set_fixed_stack_segment(fcx.llfn);
|
|
let ty = ty::lookup_item_type(ccx.tcx,
|
|
ast_util::local_def(item.id)).ty;
|
|
let args = vec::from_fn(ty::ty_fn_args(ty).len(), |i| {
|
|
get_param(decl, i + first_real_arg)
|
|
});
|
|
let retval = Call(bcx, llbasefn, args);
|
|
let ret_ty = ty::ty_fn_ret(ty);
|
|
if !ty::type_is_nil(ret_ty) && !ty::type_is_bot(ret_ty) {
|
|
Store(bcx, retval, fcx.llretptr.get());
|
|
}
|
|
build_return(bcx);
|
|
finish_fn(fcx, lltop);
|
|
}
|
|
|
|
fn build_wrap_fn(ccx: @CrateContext,
|
|
tys: &ShimTypes,
|
|
llshimfn: ValueRef,
|
|
llwrapfn: ValueRef) {
|
|
/*!
|
|
*
|
|
* Build W, from comment above:
|
|
*
|
|
* void W(Z* dest, void *env, X x, Y y) {
|
|
* struct { X x; Y y; Z *z; } args = { x, y, z };
|
|
* call_on_c_stack_shim(S, &args);
|
|
* }
|
|
*
|
|
* One thing we have to be very careful of is to
|
|
* account for the Rust modes.
|
|
*/
|
|
|
|
let _icx = ccx.insn_ctxt("foreign::build_wrap_fn");
|
|
|
|
build_wrap_fn_(ccx,
|
|
tys,
|
|
llshimfn,
|
|
llwrapfn,
|
|
ccx.upcalls.call_shim_on_c_stack,
|
|
false,
|
|
build_args,
|
|
build_ret);
|
|
|
|
fn build_args(bcx: block,
|
|
tys: &ShimTypes,
|
|
llwrapfn: ValueRef,
|
|
llargbundle: ValueRef) {
|
|
let _icx = bcx.insn_ctxt("foreign::wrap::build_args");
|
|
let ccx = bcx.ccx();
|
|
let n = vec::len(tys.llsig.llarg_tys);
|
|
let implicit_args = first_real_arg; // return + env
|
|
for uint::range(0, n) |i| {
|
|
let mut llargval = get_param(llwrapfn, i + implicit_args);
|
|
|
|
// In some cases, Rust will pass a pointer which the
|
|
// native C type doesn't have. In that case, just
|
|
// load the value from the pointer.
|
|
if type_of::arg_is_indirect(ccx, &tys.fn_sig.inputs[i]) {
|
|
llargval = Load(bcx, llargval);
|
|
}
|
|
|
|
store_inbounds(bcx, llargval, llargbundle, ~[0u, i]);
|
|
}
|
|
let llretptr = bcx.fcx.llretptr.get();
|
|
store_inbounds(bcx, llretptr, llargbundle, ~[0u, n]);
|
|
}
|
|
|
|
fn build_ret(bcx: block,
|
|
shim_types: &ShimTypes,
|
|
llargbundle: ValueRef) {
|
|
let _icx = bcx.insn_ctxt("foreign::wrap::build_ret");
|
|
let arg_count = shim_types.fn_sig.inputs.len();
|
|
let llretptr = load_inbounds(bcx, llargbundle, ~[0, arg_count]);
|
|
Store(bcx, Load(bcx, llretptr), bcx.fcx.llretptr.get());
|
|
build_return(bcx);
|
|
}
|
|
}
|
|
}
|
|
|
|
pub fn trans_intrinsic(ccx: @CrateContext,
|
|
decl: ValueRef,
|
|
item: @ast::foreign_item,
|
|
path: ast_map::path,
|
|
substs: @param_substs,
|
|
attributes: &[ast::attribute],
|
|
ref_id: Option<ast::node_id>) {
|
|
debug!("trans_intrinsic(item.ident=%s)", *ccx.sess.str_of(item.ident));
|
|
|
|
let output_type = ty::ty_fn_ret(ty::node_id_to_type(ccx.tcx, item.id));
|
|
|
|
// XXX: Bad copy.
|
|
let fcx = new_fn_ctxt_w_id(ccx,
|
|
path,
|
|
decl,
|
|
item.id,
|
|
output_type,
|
|
None,
|
|
Some(copy substs),
|
|
Some(item.span));
|
|
|
|
// Set the fixed stack segment flag if necessary.
|
|
if attr::attrs_contains_name(attributes, "fixed_stack_segment") {
|
|
set_fixed_stack_segment(fcx.llfn);
|
|
}
|
|
|
|
let mut bcx = top_scope_block(fcx, None);
|
|
let lltop = bcx.llbb;
|
|
match *ccx.sess.str_of(item.ident) {
|
|
~"atomic_cxchg" => {
|
|
let old = AtomicCmpXchg(bcx,
|
|
get_param(decl, first_real_arg),
|
|
get_param(decl, first_real_arg + 1u),
|
|
get_param(decl, first_real_arg + 2u),
|
|
SequentiallyConsistent);
|
|
Store(bcx, old, fcx.llretptr.get());
|
|
}
|
|
~"atomic_cxchg_acq" => {
|
|
let old = AtomicCmpXchg(bcx,
|
|
get_param(decl, first_real_arg),
|
|
get_param(decl, first_real_arg + 1u),
|
|
get_param(decl, first_real_arg + 2u),
|
|
Acquire);
|
|
Store(bcx, old, fcx.llretptr.get());
|
|
}
|
|
~"atomic_cxchg_rel" => {
|
|
let old = AtomicCmpXchg(bcx,
|
|
get_param(decl, first_real_arg),
|
|
get_param(decl, first_real_arg + 1u),
|
|
get_param(decl, first_real_arg + 2u),
|
|
Release);
|
|
Store(bcx, old, fcx.llretptr.get());
|
|
}
|
|
~"atomic_xchg" => {
|
|
let old = AtomicRMW(bcx, Xchg,
|
|
get_param(decl, first_real_arg),
|
|
get_param(decl, first_real_arg + 1u),
|
|
SequentiallyConsistent);
|
|
Store(bcx, old, fcx.llretptr.get());
|
|
}
|
|
~"atomic_xchg_acq" => {
|
|
let old = AtomicRMW(bcx, Xchg,
|
|
get_param(decl, first_real_arg),
|
|
get_param(decl, first_real_arg + 1u),
|
|
Acquire);
|
|
Store(bcx, old, fcx.llretptr.get());
|
|
}
|
|
~"atomic_xchg_rel" => {
|
|
let old = AtomicRMW(bcx, Xchg,
|
|
get_param(decl, first_real_arg),
|
|
get_param(decl, first_real_arg + 1u),
|
|
Release);
|
|
Store(bcx, old, fcx.llretptr.get());
|
|
}
|
|
~"atomic_xadd" => {
|
|
let old = AtomicRMW(bcx, lib::llvm::Add,
|
|
get_param(decl, first_real_arg),
|
|
get_param(decl, first_real_arg + 1u),
|
|
SequentiallyConsistent);
|
|
Store(bcx, old, fcx.llretptr.get());
|
|
}
|
|
~"atomic_xadd_acq" => {
|
|
let old = AtomicRMW(bcx, lib::llvm::Add,
|
|
get_param(decl, first_real_arg),
|
|
get_param(decl, first_real_arg + 1u),
|
|
Acquire);
|
|
Store(bcx, old, fcx.llretptr.get());
|
|
}
|
|
~"atomic_xadd_rel" => {
|
|
let old = AtomicRMW(bcx, lib::llvm::Add,
|
|
get_param(decl, first_real_arg),
|
|
get_param(decl, first_real_arg + 1u),
|
|
Release);
|
|
Store(bcx, old, fcx.llretptr.get());
|
|
}
|
|
~"atomic_xsub" => {
|
|
let old = AtomicRMW(bcx, lib::llvm::Sub,
|
|
get_param(decl, first_real_arg),
|
|
get_param(decl, first_real_arg + 1u),
|
|
SequentiallyConsistent);
|
|
Store(bcx, old, fcx.llretptr.get());
|
|
}
|
|
~"atomic_xsub_acq" => {
|
|
let old = AtomicRMW(bcx, lib::llvm::Sub,
|
|
get_param(decl, first_real_arg),
|
|
get_param(decl, first_real_arg + 1u),
|
|
Acquire);
|
|
Store(bcx, old, fcx.llretptr.get());
|
|
}
|
|
~"atomic_xsub_rel" => {
|
|
let old = AtomicRMW(bcx, lib::llvm::Sub,
|
|
get_param(decl, first_real_arg),
|
|
get_param(decl, first_real_arg + 1u),
|
|
Release);
|
|
Store(bcx, old, fcx.llretptr.get());
|
|
}
|
|
~"size_of" => {
|
|
let tp_ty = substs.tys[0];
|
|
let lltp_ty = type_of::type_of(ccx, tp_ty);
|
|
Store(bcx, C_uint(ccx, machine::llsize_of_real(ccx, lltp_ty)),
|
|
fcx.llretptr.get());
|
|
}
|
|
~"move_val" => {
|
|
// Create a datum reflecting the value being moved:
|
|
//
|
|
// - the datum will be by ref if the value is non-immediate;
|
|
//
|
|
// - the datum has a RevokeClean source because, that way,
|
|
// the `move_to()` method does not feel compelled to
|
|
// zero out the memory where the datum resides. Zeroing
|
|
// is not necessary since, for intrinsics, there is no
|
|
// cleanup to concern ourselves with.
|
|
let tp_ty = substs.tys[0];
|
|
let mode = appropriate_mode(tp_ty);
|
|
let src = Datum {val: get_param(decl, first_real_arg + 1u),
|
|
ty: tp_ty, mode: mode, source: RevokeClean};
|
|
bcx = src.move_to(bcx, DROP_EXISTING,
|
|
get_param(decl, first_real_arg));
|
|
}
|
|
~"move_val_init" => {
|
|
// See comments for `"move_val"`.
|
|
let tp_ty = substs.tys[0];
|
|
let mode = appropriate_mode(tp_ty);
|
|
let src = Datum {val: get_param(decl, first_real_arg + 1u),
|
|
ty: tp_ty, mode: mode, source: RevokeClean};
|
|
bcx = src.move_to(bcx, INIT, get_param(decl, first_real_arg));
|
|
}
|
|
~"min_align_of" => {
|
|
let tp_ty = substs.tys[0];
|
|
let lltp_ty = type_of::type_of(ccx, tp_ty);
|
|
Store(bcx, C_uint(ccx, machine::llalign_of_min(ccx, lltp_ty)),
|
|
fcx.llretptr.get());
|
|
}
|
|
~"pref_align_of"=> {
|
|
let tp_ty = substs.tys[0];
|
|
let lltp_ty = type_of::type_of(ccx, tp_ty);
|
|
Store(bcx, C_uint(ccx, machine::llalign_of_pref(ccx, lltp_ty)),
|
|
fcx.llretptr.get());
|
|
}
|
|
~"get_tydesc" => {
|
|
let tp_ty = substs.tys[0];
|
|
let static_ti = get_tydesc(ccx, tp_ty);
|
|
glue::lazily_emit_all_tydesc_glue(ccx, static_ti);
|
|
|
|
// FIXME (#3727): change this to T_ptr(ccx.tydesc_ty) when the
|
|
// core::sys copy of the get_tydesc interface dies off.
|
|
let td = PointerCast(bcx, static_ti.tydesc, T_ptr(T_nil()));
|
|
Store(bcx, td, fcx.llretptr.get());
|
|
}
|
|
~"init" => {
|
|
let tp_ty = substs.tys[0];
|
|
let lltp_ty = type_of::type_of(ccx, tp_ty);
|
|
if !ty::type_is_nil(tp_ty) {
|
|
Store(bcx, C_null(lltp_ty), fcx.llretptr.get());
|
|
}
|
|
}
|
|
~"forget" => {}
|
|
~"reinterpret_cast" => {
|
|
let tp_ty = substs.tys[0];
|
|
let lltp_ty = type_of::type_of(ccx, tp_ty);
|
|
let llout_ty = type_of::type_of(ccx, substs.tys[1]);
|
|
let tp_sz = machine::llbitsize_of_real(ccx, lltp_ty),
|
|
out_sz = machine::llbitsize_of_real(ccx, llout_ty);
|
|
if tp_sz != out_sz {
|
|
let sp = match *ccx.tcx.items.get(&ref_id.get()) {
|
|
ast_map::node_expr(e) => e.span,
|
|
_ => fail!(~"reinterpret_cast or forget has non-expr arg")
|
|
};
|
|
ccx.sess.span_fatal(
|
|
sp, fmt!("reinterpret_cast called on types \
|
|
with different size: %s (%u bit(s)) to %s \
|
|
(%u bit(s))",
|
|
ty_to_str(ccx.tcx, tp_ty), tp_sz,
|
|
ty_to_str(ccx.tcx, substs.tys[1]), out_sz));
|
|
}
|
|
if !ty::type_is_nil(substs.tys[1]) {
|
|
// NB: Do not use a Load and Store here. This causes
|
|
// massive code bloat when reinterpret_cast is used on
|
|
// large structural types.
|
|
let llretptr = fcx.llretptr.get();
|
|
let llretptr = PointerCast(bcx, llretptr, T_ptr(T_i8()));
|
|
let llcast = get_param(decl, first_real_arg);
|
|
let llcast = PointerCast(bcx, llcast, T_ptr(T_i8()));
|
|
call_memcpy(bcx, llretptr, llcast, llsize_of(ccx, lltp_ty));
|
|
}
|
|
}
|
|
~"addr_of" => {
|
|
Store(bcx, get_param(decl, first_real_arg), fcx.llretptr.get());
|
|
}
|
|
~"needs_drop" => {
|
|
let tp_ty = substs.tys[0];
|
|
Store(bcx,
|
|
C_bool(ty::type_needs_drop(ccx.tcx, tp_ty)),
|
|
fcx.llretptr.get());
|
|
}
|
|
~"visit_tydesc" => {
|
|
let td = get_param(decl, first_real_arg);
|
|
let visitor = get_param(decl, first_real_arg + 1u);
|
|
let td = PointerCast(bcx, td, T_ptr(ccx.tydesc_type));
|
|
glue::call_tydesc_glue_full(bcx, visitor, td,
|
|
abi::tydesc_field_visit_glue, None);
|
|
}
|
|
~"frame_address" => {
|
|
let frameaddress = *ccx.intrinsics.get(&~"llvm.frameaddress");
|
|
let frameaddress_val = Call(bcx, frameaddress, ~[C_i32(0i32)]);
|
|
let star_u8 = ty::mk_imm_ptr(
|
|
bcx.tcx(),
|
|
ty::mk_mach_uint(ast::ty_u8));
|
|
let fty = ty::mk_closure(bcx.tcx(), ty::ClosureTy {
|
|
purity: ast::impure_fn,
|
|
sigil: ast::BorrowedSigil,
|
|
onceness: ast::Many,
|
|
region: ty::re_bound(ty::br_anon(0)),
|
|
sig: FnSig {bound_lifetime_names: opt_vec::Empty,
|
|
inputs: ~[arg {mode: ast::expl(ast::by_copy),
|
|
ty: star_u8}],
|
|
output: ty::mk_nil()}
|
|
});
|
|
let datum = Datum {val: get_param(decl, first_real_arg),
|
|
mode: ByRef, ty: fty, source: ZeroMem};
|
|
let arg_vals = ~[frameaddress_val];
|
|
bcx = trans_call_inner(
|
|
bcx, None, fty, ty::mk_nil(),
|
|
|bcx| Callee {bcx: bcx, data: Closure(datum)},
|
|
ArgVals(arg_vals), Ignore, DontAutorefArg);
|
|
}
|
|
~"morestack_addr" => {
|
|
// XXX This is a hack to grab the address of this particular
|
|
// native function. There should be a general in-language
|
|
// way to do this
|
|
let llfty = type_of_fn(bcx.ccx(), ~[], ty::mk_nil());
|
|
let morestack_addr = decl_cdecl_fn(
|
|
bcx.ccx().llmod, ~"__morestack", llfty);
|
|
let morestack_addr = PointerCast(bcx, morestack_addr,
|
|
T_ptr(T_nil()));
|
|
Store(bcx, morestack_addr, fcx.llretptr.get());
|
|
}
|
|
~"memmove32" => {
|
|
let dst_ptr = get_param(decl, first_real_arg);
|
|
let src_ptr = get_param(decl, first_real_arg + 1);
|
|
let size = get_param(decl, first_real_arg + 2);
|
|
let align = C_i32(1);
|
|
let volatile = C_i1(false);
|
|
let llfn = *bcx.ccx().intrinsics.get(
|
|
&~"llvm.memmove.p0i8.p0i8.i32");
|
|
Call(bcx, llfn, ~[dst_ptr, src_ptr, size, align, volatile]);
|
|
}
|
|
~"memmove64" => {
|
|
let dst_ptr = get_param(decl, first_real_arg);
|
|
let src_ptr = get_param(decl, first_real_arg + 1);
|
|
let size = get_param(decl, first_real_arg + 2);
|
|
let align = C_i32(1);
|
|
let volatile = C_i1(false);
|
|
let llfn = *bcx.ccx().intrinsics.get(
|
|
&~"llvm.memmove.p0i8.p0i8.i64");
|
|
Call(bcx, llfn, ~[dst_ptr, src_ptr, size, align, volatile]);
|
|
}
|
|
~"sqrtf32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let sqrtf = *ccx.intrinsics.get(&~"llvm.sqrt.f32");
|
|
Store(bcx, Call(bcx, sqrtf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"sqrtf64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let sqrtf = *ccx.intrinsics.get(&~"llvm.sqrt.f64");
|
|
Store(bcx, Call(bcx, sqrtf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"powif32" => {
|
|
let a = get_param(decl, first_real_arg);
|
|
let x = get_param(decl, first_real_arg + 1u);
|
|
let powif = *ccx.intrinsics.get(&~"llvm.powi.f32");
|
|
Store(bcx, Call(bcx, powif, ~[a, x]), fcx.llretptr.get());
|
|
}
|
|
~"powif64" => {
|
|
let a = get_param(decl, first_real_arg);
|
|
let x = get_param(decl, first_real_arg + 1u);
|
|
let powif = *ccx.intrinsics.get(&~"llvm.powi.f64");
|
|
Store(bcx, Call(bcx, powif, ~[a, x]), fcx.llretptr.get());
|
|
}
|
|
~"sinf32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let sinf = *ccx.intrinsics.get(&~"llvm.sin.f32");
|
|
Store(bcx, Call(bcx, sinf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"sinf64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let sinf = *ccx.intrinsics.get(&~"llvm.sin.f64");
|
|
Store(bcx, Call(bcx, sinf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"cosf32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let cosf = *ccx.intrinsics.get(&~"llvm.cos.f32");
|
|
Store(bcx, Call(bcx, cosf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"cosf64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let cosf = *ccx.intrinsics.get(&~"llvm.cos.f64");
|
|
Store(bcx, Call(bcx, cosf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"powf32" => {
|
|
let a = get_param(decl, first_real_arg);
|
|
let x = get_param(decl, first_real_arg + 1u);
|
|
let powf = *ccx.intrinsics.get(&~"llvm.pow.f32");
|
|
Store(bcx, Call(bcx, powf, ~[a, x]), fcx.llretptr.get());
|
|
}
|
|
~"powf64" => {
|
|
let a = get_param(decl, first_real_arg);
|
|
let x = get_param(decl, first_real_arg + 1u);
|
|
let powf = *ccx.intrinsics.get(&~"llvm.pow.f64");
|
|
Store(bcx, Call(bcx, powf, ~[a, x]), fcx.llretptr.get());
|
|
}
|
|
~"expf32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let expf = *ccx.intrinsics.get(&~"llvm.exp.f32");
|
|
Store(bcx, Call(bcx, expf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"expf64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let expf = *ccx.intrinsics.get(&~"llvm.exp.f64");
|
|
Store(bcx, Call(bcx, expf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"exp2f32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let exp2f = *ccx.intrinsics.get(&~"llvm.exp2.f32");
|
|
Store(bcx, Call(bcx, exp2f, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"exp2f64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let exp2f = *ccx.intrinsics.get(&~"llvm.exp2.f64");
|
|
Store(bcx, Call(bcx, exp2f, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"logf32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let logf = *ccx.intrinsics.get(&~"llvm.log.f32");
|
|
Store(bcx, Call(bcx, logf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"logf64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let logf = *ccx.intrinsics.get(&~"llvm.log.f64");
|
|
Store(bcx, Call(bcx, logf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"log10f32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let log10f = *ccx.intrinsics.get(&~"llvm.log10.f32");
|
|
Store(bcx, Call(bcx, log10f, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"log10f64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let log10f = *ccx.intrinsics.get(&~"llvm.log10.f64");
|
|
Store(bcx, Call(bcx, log10f, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"log2f32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let log2f = *ccx.intrinsics.get(&~"llvm.log2.f32");
|
|
Store(bcx, Call(bcx, log2f, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"log2f64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let log2f = *ccx.intrinsics.get(&~"llvm.log2.f64");
|
|
Store(bcx, Call(bcx, log2f, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"fmaf32" => {
|
|
let a = get_param(decl, first_real_arg);
|
|
let b = get_param(decl, first_real_arg + 1u);
|
|
let c = get_param(decl, first_real_arg + 2u);
|
|
let fmaf = *ccx.intrinsics.get(&~"llvm.fma.f32");
|
|
Store(bcx, Call(bcx, fmaf, ~[a, b, c]), fcx.llretptr.get());
|
|
}
|
|
~"fmaf64" => {
|
|
let a = get_param(decl, first_real_arg);
|
|
let b = get_param(decl, first_real_arg + 1u);
|
|
let c = get_param(decl, first_real_arg + 2u);
|
|
let fmaf = *ccx.intrinsics.get(&~"llvm.fma.f64");
|
|
Store(bcx, Call(bcx, fmaf, ~[a, b, c]), fcx.llretptr.get());
|
|
}
|
|
~"fabsf32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let fabsf = *ccx.intrinsics.get(&~"llvm.fabs.f32");
|
|
Store(bcx, Call(bcx, fabsf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"fabsf64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let fabsf = *ccx.intrinsics.get(&~"llvm.fabs.f64");
|
|
Store(bcx, Call(bcx, fabsf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"floorf32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let floorf = *ccx.intrinsics.get(&~"llvm.floor.f32");
|
|
Store(bcx, Call(bcx, floorf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"floorf64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let floorf = *ccx.intrinsics.get(&~"llvm.floor.f64");
|
|
Store(bcx, Call(bcx, floorf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"ceilf32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let ceilf = *ccx.intrinsics.get(&~"llvm.ceil.f32");
|
|
Store(bcx, Call(bcx, ceilf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"ceilf64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let ceilf = *ccx.intrinsics.get(&~"llvm.ceil.f64");
|
|
Store(bcx, Call(bcx, ceilf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"truncf32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let truncf = *ccx.intrinsics.get(&~"llvm.trunc.f32");
|
|
Store(bcx, Call(bcx, truncf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"truncf64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let truncf = *ccx.intrinsics.get(&~"llvm.trunc.f64");
|
|
Store(bcx, Call(bcx, truncf, ~[x]), fcx.llretptr.get());
|
|
}
|
|
~"ctpop8" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let ctpop = *ccx.intrinsics.get(&~"llvm.ctpop.i8");
|
|
Store(bcx, Call(bcx, ctpop, ~[x]), fcx.llretptr.get())
|
|
}
|
|
~"ctpop16" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let ctpop = *ccx.intrinsics.get(&~"llvm.ctpop.i16");
|
|
Store(bcx, Call(bcx, ctpop, ~[x]), fcx.llretptr.get())
|
|
}
|
|
~"ctpop32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let ctpop = *ccx.intrinsics.get(&~"llvm.ctpop.i32");
|
|
Store(bcx, Call(bcx, ctpop, ~[x]), fcx.llretptr.get())
|
|
}
|
|
~"ctpop64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let ctpop = *ccx.intrinsics.get(&~"llvm.ctpop.i64");
|
|
Store(bcx, Call(bcx, ctpop, ~[x]), fcx.llretptr.get())
|
|
}
|
|
~"ctlz8" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let y = C_i1(false);
|
|
let ctlz = *ccx.intrinsics.get(&~"llvm.ctlz.i8");
|
|
Store(bcx, Call(bcx, ctlz, ~[x, y]), fcx.llretptr.get())
|
|
}
|
|
~"ctlz16" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let y = C_i1(false);
|
|
let ctlz = *ccx.intrinsics.get(&~"llvm.ctlz.i16");
|
|
Store(bcx, Call(bcx, ctlz, ~[x, y]), fcx.llretptr.get())
|
|
}
|
|
~"ctlz32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let y = C_i1(false);
|
|
let ctlz = *ccx.intrinsics.get(&~"llvm.ctlz.i32");
|
|
Store(bcx, Call(bcx, ctlz, ~[x, y]), fcx.llretptr.get())
|
|
}
|
|
~"ctlz64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let y = C_i1(false);
|
|
let ctlz = *ccx.intrinsics.get(&~"llvm.ctlz.i64");
|
|
Store(bcx, Call(bcx, ctlz, ~[x, y]), fcx.llretptr.get())
|
|
}
|
|
~"cttz8" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let y = C_i1(false);
|
|
let cttz = *ccx.intrinsics.get(&~"llvm.cttz.i8");
|
|
Store(bcx, Call(bcx, cttz, ~[x, y]), fcx.llretptr.get())
|
|
}
|
|
~"cttz16" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let y = C_i1(false);
|
|
let cttz = *ccx.intrinsics.get(&~"llvm.cttz.i16");
|
|
Store(bcx, Call(bcx, cttz, ~[x, y]), fcx.llretptr.get())
|
|
}
|
|
~"cttz32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let y = C_i1(false);
|
|
let cttz = *ccx.intrinsics.get(&~"llvm.cttz.i32");
|
|
Store(bcx, Call(bcx, cttz, ~[x, y]), fcx.llretptr.get())
|
|
}
|
|
~"cttz64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let y = C_i1(false);
|
|
let cttz = *ccx.intrinsics.get(&~"llvm.cttz.i64");
|
|
Store(bcx, Call(bcx, cttz, ~[x, y]), fcx.llretptr.get())
|
|
}
|
|
~"bswap16" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let cttz = *ccx.intrinsics.get(&~"llvm.bswap.i16");
|
|
Store(bcx, Call(bcx, cttz, ~[x]), fcx.llretptr.get())
|
|
}
|
|
~"bswap32" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let cttz = *ccx.intrinsics.get(&~"llvm.bswap.i32");
|
|
Store(bcx, Call(bcx, cttz, ~[x]), fcx.llretptr.get())
|
|
}
|
|
~"bswap64" => {
|
|
let x = get_param(decl, first_real_arg);
|
|
let cttz = *ccx.intrinsics.get(&~"llvm.bswap.i64");
|
|
Store(bcx, Call(bcx, cttz, ~[x]), fcx.llretptr.get())
|
|
}
|
|
_ => {
|
|
// Could we make this an enum rather than a string? does it get
|
|
// checked earlier?
|
|
ccx.sess.span_bug(item.span, ~"unknown intrinsic");
|
|
}
|
|
}
|
|
build_return(bcx);
|
|
finish_fn(fcx, lltop);
|
|
}
|
|
|
|
/**
|
|
* Translates a "crust" fn, meaning a Rust fn that can be called
|
|
* from C code. In this case, we have to perform some adaptation
|
|
* to (1) switch back to the Rust stack and (2) adapt the C calling
|
|
* convention to our own.
|
|
*
|
|
* Example: Given a crust fn F(x: X, y: Y) -> Z, we generate a
|
|
* Rust function R as normal:
|
|
*
|
|
* void R(Z* dest, void *env, X x, Y y) {...}
|
|
*
|
|
* and then we generate a wrapper function W that looks like:
|
|
*
|
|
* Z W(X x, Y y) {
|
|
* struct { X x; Y y; Z *z; } args = { x, y, z };
|
|
* call_on_c_stack_shim(S, &args);
|
|
* }
|
|
*
|
|
* Note that the wrapper follows the foreign (typically "C") ABI.
|
|
* The wrapper is the actual "value" of the foreign fn. Finally,
|
|
* we generate a shim function S that looks like:
|
|
*
|
|
* void S(struct { X x; Y y; Z *z; } *args) {
|
|
* R(args->z, NULL, args->x, args->y);
|
|
* }
|
|
*/
|
|
pub fn trans_foreign_fn(ccx: @CrateContext,
|
|
path: ast_map::path,
|
|
decl: &ast::fn_decl,
|
|
body: &ast::blk,
|
|
llwrapfn: ValueRef,
|
|
id: ast::node_id) {
|
|
let _icx = ccx.insn_ctxt("foreign::build_foreign_fn");
|
|
|
|
fn build_rust_fn(ccx: @CrateContext,
|
|
path: ast_map::path,
|
|
decl: &ast::fn_decl,
|
|
body: &ast::blk,
|
|
id: ast::node_id)
|
|
-> ValueRef {
|
|
let _icx = ccx.insn_ctxt("foreign::foreign::build_rust_fn");
|
|
let t = ty::node_id_to_type(ccx.tcx, id);
|
|
// XXX: Bad copy.
|
|
let ps = link::mangle_internal_name_by_path(
|
|
ccx, vec::append_one(copy path, ast_map::path_name(
|
|
special_idents::clownshoe_abi
|
|
)));
|
|
let llty = type_of_fn_from_ty(ccx, t);
|
|
let llfndecl = decl_internal_cdecl_fn(ccx.llmod, ps, llty);
|
|
trans_fn(ccx,
|
|
path,
|
|
decl,
|
|
body,
|
|
llfndecl,
|
|
no_self,
|
|
None,
|
|
id,
|
|
None,
|
|
[]);
|
|
return llfndecl;
|
|
}
|
|
|
|
fn build_shim_fn(ccx: @CrateContext,
|
|
path: ast_map::path,
|
|
llrustfn: ValueRef,
|
|
tys: &ShimTypes)
|
|
-> ValueRef {
|
|
/*!
|
|
*
|
|
* Generate the shim S:
|
|
*
|
|
* void S(struct { X x; Y y; Z *z; } *args) {
|
|
* R(args->z, NULL, &args->x, args->y);
|
|
* }
|
|
*
|
|
* One complication is that we must adapt to the Rust
|
|
* calling convention, which introduces indirection
|
|
* in some cases. To demonstrate this, I wrote one of the
|
|
* entries above as `&args->x`, because presumably `X` is
|
|
* one of those types that is passed by pointer in Rust.
|
|
*/
|
|
|
|
let _icx = ccx.insn_ctxt("foreign::foreign::build_shim_fn");
|
|
|
|
fn build_args(bcx: block, tys: &ShimTypes, llargbundle: ValueRef)
|
|
-> ~[ValueRef] {
|
|
let _icx = bcx.insn_ctxt("foreign::extern::shim::build_args");
|
|
let ccx = bcx.ccx();
|
|
let mut llargvals = ~[];
|
|
let mut i = 0u;
|
|
let n = tys.fn_sig.inputs.len();
|
|
|
|
if !ty::type_is_immediate(tys.fn_sig.output) {
|
|
let llretptr = load_inbounds(bcx, llargbundle, ~[0u, n]);
|
|
llargvals.push(llretptr);
|
|
} else {
|
|
llargvals.push(C_null(T_ptr(T_i8())));
|
|
}
|
|
|
|
let llenvptr = C_null(T_opaque_box_ptr(bcx.ccx()));
|
|
llargvals.push(llenvptr);
|
|
while i < n {
|
|
// Get a pointer to the argument:
|
|
let mut llargval = GEPi(bcx, llargbundle, [0u, i]);
|
|
|
|
if !type_of::arg_is_indirect(ccx, &tys.fn_sig.inputs[i]) {
|
|
// If Rust would pass this by value, load the value.
|
|
llargval = Load(bcx, llargval);
|
|
}
|
|
|
|
llargvals.push(llargval);
|
|
i += 1u;
|
|
}
|
|
return llargvals;
|
|
}
|
|
|
|
fn build_ret(bcx: block,
|
|
shim_types: &ShimTypes,
|
|
llargbundle: ValueRef,
|
|
llretval: ValueRef) {
|
|
if ty::type_is_immediate(shim_types.fn_sig.output) {
|
|
// Write the value into the argument bundle.
|
|
let arg_count = shim_types.fn_sig.inputs.len();
|
|
let llretptr = load_inbounds(bcx,
|
|
llargbundle,
|
|
~[0, arg_count]);
|
|
Store(bcx, llretval, llretptr);
|
|
} else {
|
|
// NB: The return pointer in the Rust ABI function is wired
|
|
// directly into the return slot in the shim struct.
|
|
}
|
|
|
|
build_return(bcx);
|
|
}
|
|
|
|
let shim_name = link::mangle_internal_name_by_path(
|
|
ccx,
|
|
vec::append_one(path, ast_map::path_name(
|
|
special_idents::clownshoe_stack_shim
|
|
)));
|
|
build_shim_fn_(ccx,
|
|
shim_name,
|
|
llrustfn,
|
|
tys,
|
|
lib::llvm::CCallConv,
|
|
build_args,
|
|
build_ret)
|
|
}
|
|
|
|
fn build_wrap_fn(ccx: @CrateContext,
|
|
llshimfn: ValueRef,
|
|
llwrapfn: ValueRef,
|
|
tys: &ShimTypes) {
|
|
/*!
|
|
*
|
|
* Generate the wrapper W:
|
|
*
|
|
* Z W(X x, Y y) {
|
|
* struct { X x; Y y; Z *z; } args = { x, y, z };
|
|
* call_on_c_stack_shim(S, &args);
|
|
* }
|
|
*/
|
|
|
|
let _icx = ccx.insn_ctxt("foreign::foreign::build_wrap_fn");
|
|
|
|
build_wrap_fn_(ccx,
|
|
tys,
|
|
llshimfn,
|
|
llwrapfn,
|
|
ccx.upcalls.call_shim_on_rust_stack,
|
|
true,
|
|
build_args,
|
|
build_ret);
|
|
|
|
fn build_args(bcx: block,
|
|
tys: &ShimTypes,
|
|
llwrapfn: ValueRef,
|
|
llargbundle: ValueRef) {
|
|
let _icx = bcx.insn_ctxt("foreign::foreign::wrap::build_args");
|
|
tys.fn_ty.build_wrap_args(bcx,
|
|
tys.llsig.llret_ty,
|
|
llwrapfn,
|
|
llargbundle);
|
|
}
|
|
|
|
fn build_ret(bcx: block, tys: &ShimTypes, llargbundle: ValueRef) {
|
|
let _icx = bcx.insn_ctxt("foreign::foreign::wrap::build_ret");
|
|
tys.fn_ty.build_wrap_ret(bcx, tys.llsig.llarg_tys, llargbundle);
|
|
build_return(bcx);
|
|
}
|
|
}
|
|
|
|
let tys = shim_types(ccx, id);
|
|
// The internal Rust ABI function - runs on the Rust stack
|
|
// XXX: Bad copy.
|
|
let llrustfn = build_rust_fn(ccx, copy path, decl, body, id);
|
|
// The internal shim function - runs on the Rust stack
|
|
let llshimfn = build_shim_fn(ccx, path, llrustfn, &tys);
|
|
// The foreign C function - runs on the C stack
|
|
build_wrap_fn(ccx, llshimfn, llwrapfn, &tys)
|
|
}
|
|
|
|
pub fn register_foreign_fn(ccx: @CrateContext,
|
|
sp: span,
|
|
path: ast_map::path,
|
|
node_id: ast::node_id,
|
|
attrs: &[ast::attribute])
|
|
-> ValueRef {
|
|
let _icx = ccx.insn_ctxt("foreign::register_foreign_fn");
|
|
|
|
let t = ty::node_id_to_type(ccx.tcx, node_id);
|
|
|
|
let tys = shim_types(ccx, node_id);
|
|
do tys.fn_ty.decl_fn |fnty| {
|
|
register_fn_fuller(ccx,
|
|
sp,
|
|
/*bad*/copy path,
|
|
node_id,
|
|
attrs,
|
|
t,
|
|
lib::llvm::CCallConv,
|
|
fnty)
|
|
}
|
|
}
|