2 use crate::context::CodegenCx;
3 use crate::type_of::LayoutLlvmExt;
4 use crate::builder::Builder;
5 use crate::value::Value;
8 use rustc_codegen_ssa::traits::*;
10 use rustc_codegen_ssa::mir::place::PlaceRef;
11 use rustc_codegen_ssa::mir::operand::OperandValue;
13 use std::ffi::{CStr, CString};
14 use libc::{c_uint, c_char};
17 impl AsmBuilderMethods<'tcx> for Builder<'a, 'll, 'tcx> {
18 fn codegen_inline_asm(
21 outputs: Vec<PlaceRef<'tcx, &'ll Value>>,
22 mut inputs: Vec<&'ll Value>
24 let mut ext_constraints = vec![];
25 let mut output_types = vec![];
27 // Prepare the output operands
28 let mut indirect_outputs = vec![];
29 for (i, (out, &place)) in ia.outputs.iter().zip(&outputs).enumerate() {
31 inputs.push(self.load_operand(place).immediate());
32 ext_constraints.push(i.to_string());
35 indirect_outputs.push(self.load_operand(place).immediate());
37 output_types.push(place.layout.llvm_type(self.cx()));
40 if !indirect_outputs.is_empty() {
41 indirect_outputs.extend_from_slice(&inputs);
42 inputs = indirect_outputs;
45 let clobbers = ia.clobbers.iter()
46 .map(|s| format!("~{{{}}}", &s));
48 // Default per-arch clobbers
49 // Basically what clang does
50 let arch_clobbers = match &self.sess().target.target.arch[..] {
51 "x86" | "x86_64" => vec!["~{dirflag}", "~{fpsr}", "~{flags}"],
52 "mips" | "mips64" => vec!["~{$1}"],
57 ia.outputs.iter().map(|out| out.constraint.to_string())
58 .chain(ia.inputs.iter().map(|s| s.to_string()))
59 .chain(ext_constraints)
61 .chain(arch_clobbers.iter().map(|s| s.to_string()))
62 .collect::<Vec<String>>().join(",");
64 debug!("Asm Constraints: {}", &all_constraints);
66 // Depending on how many outputs we have, the return type is different
67 let num_outputs = output_types.len();
68 let output_type = match num_outputs {
69 0 => self.type_void(),
71 _ => self.type_struct(&output_types, false)
74 let asm = CString::new(ia.asm.as_str().as_bytes()).unwrap();
75 let constraint_cstr = CString::new(all_constraints).unwrap();
76 let r = inline_asm_call(
91 // Again, based on how many outputs we have
92 let outputs = ia.outputs.iter().zip(&outputs).filter(|&(ref o, _)| !o.is_indirect);
93 for (i, (_, &place)) in outputs.enumerate() {
94 let v = if num_outputs == 1 { r } else { self.extract_value(r, i as u64) };
95 OperandValue::Immediate(v).store(self, place);
98 // Store mark in a metadata node so we can map LLVM errors
99 // back to source locations. See #17552.
102 let kind = llvm::LLVMGetMDKindIDInContext(self.llcx,
103 key.as_ptr() as *const c_char, key.len() as c_uint);
105 let val: &'ll Value = self.const_i32(ia.ctxt.outer().as_u32() as i32);
107 llvm::LLVMSetMetadata(r, kind,
108 llvm::LLVMMDNodeInContext(self.llcx, &val, 1));
115 impl AsmMethods<'tcx> for CodegenCx<'ll, 'tcx> {
116 fn codegen_global_asm(&self, ga: &hir::GlobalAsm) {
117 let asm = CString::new(ga.asm.as_str().as_bytes()).unwrap();
119 llvm::LLVMRustAppendModuleInlineAsm(self.llmod, asm.as_ptr());
125 bx: &mut Builder<'a, 'll, 'tcx>,
128 inputs: &[&'ll Value],
129 output: &'ll llvm::Type,
132 dia: ::syntax::ast::AsmDialect,
133 ) -> Option<&'ll Value> {
134 let volatile = if volatile { llvm::True }
135 else { llvm::False };
136 let alignstack = if alignstack { llvm::True }
137 else { llvm::False };
139 let argtys = inputs.iter().map(|v| {
140 debug!("Asm Input Type: {:?}", *v);
142 }).collect::<Vec<_>>();
144 debug!("Asm Output Type: {:?}", output);
145 let fty = bx.cx.type_func(&argtys[..], output);
147 // Ask LLVM to verify that the constraints are well-formed.
148 let constraints_ok = llvm::LLVMRustInlineAsmVerify(fty, cons.as_ptr());
149 debug!("Constraint verification result: {:?}", constraints_ok);
151 let v = llvm::LLVMRustInlineAsm(
157 llvm::AsmDialect::from_generic(dia),
159 Some(bx.call(v, inputs, None))
161 // LLVM has detected an issue with our constraints, bail out