llvm-project/llvm/test/CodeGen/X86/musttail-varargs.ll

127 lines
3.9 KiB
LLVM

; RUN: llc < %s -enable-tail-merge=0 -mtriple=x86_64-linux | FileCheck %s --check-prefix=LINUX
; RUN: llc < %s -enable-tail-merge=0 -mtriple=x86_64-windows | FileCheck %s --check-prefix=WINDOWS
; Test that we actually spill and reload all arguments in the variadic argument
; pack. Doing a normal call will clobber all argument registers, and we will
; spill around it. A simple adjustment should not require any XMM spills.
declare void @llvm.va_start(i8*) nounwind
declare void(i8*, ...)* @get_f(i8* %this)
define void @f_thunk(i8* %this, ...) {
; Use va_start so that we exercise the combination.
%ap = alloca [4 x i8*], align 16
%ap_i8 = bitcast [4 x i8*]* %ap to i8*
call void @llvm.va_start(i8* %ap_i8)
%fptr = call void(i8*, ...)*(i8*)* @get_f(i8* %this)
musttail call void (i8*, ...)* %fptr(i8* %this, ...)
ret void
}
; Save and restore 6 GPRs, 8 XMMs, and AL around the call.
; LINUX-LABEL: f_thunk:
; LINUX-DAG: movq %rdi, {{.*}}
; LINUX-DAG: movq %rsi, {{.*}}
; LINUX-DAG: movq %rdx, {{.*}}
; LINUX-DAG: movq %rcx, {{.*}}
; LINUX-DAG: movq %r8, {{.*}}
; LINUX-DAG: movq %r9, {{.*}}
; LINUX-DAG: movb %al, {{.*}}
; LINUX-DAG: movaps %xmm0, {{[0-9]*}}(%rsp)
; LINUX-DAG: movaps %xmm1, {{[0-9]*}}(%rsp)
; LINUX-DAG: movaps %xmm2, {{[0-9]*}}(%rsp)
; LINUX-DAG: movaps %xmm3, {{[0-9]*}}(%rsp)
; LINUX-DAG: movaps %xmm4, {{[0-9]*}}(%rsp)
; LINUX-DAG: movaps %xmm5, {{[0-9]*}}(%rsp)
; LINUX-DAG: movaps %xmm6, {{[0-9]*}}(%rsp)
; LINUX-DAG: movaps %xmm7, {{[0-9]*}}(%rsp)
; LINUX: callq get_f
; LINUX-DAG: movaps {{[0-9]*}}(%rsp), %xmm0
; LINUX-DAG: movaps {{[0-9]*}}(%rsp), %xmm1
; LINUX-DAG: movaps {{[0-9]*}}(%rsp), %xmm2
; LINUX-DAG: movaps {{[0-9]*}}(%rsp), %xmm3
; LINUX-DAG: movaps {{[0-9]*}}(%rsp), %xmm4
; LINUX-DAG: movaps {{[0-9]*}}(%rsp), %xmm5
; LINUX-DAG: movaps {{[0-9]*}}(%rsp), %xmm6
; LINUX-DAG: movaps {{[0-9]*}}(%rsp), %xmm7
; LINUX-DAG: movq {{.*}}, %rdi
; LINUX-DAG: movq {{.*}}, %rsi
; LINUX-DAG: movq {{.*}}, %rdx
; LINUX-DAG: movq {{.*}}, %rcx
; LINUX-DAG: movq {{.*}}, %r8
; LINUX-DAG: movq {{.*}}, %r9
; LINUX-DAG: movb {{.*}}, %al
; LINUX: jmpq *{{.*}} # TAILCALL
; WINDOWS-LABEL: f_thunk:
; WINDOWS-NOT: mov{{.}}ps
; WINDOWS-DAG: movq %rdx, {{.*}}
; WINDOWS-DAG: movq %rcx, {{.*}}
; WINDOWS-DAG: movq %r8, {{.*}}
; WINDOWS-DAG: movq %r9, {{.*}}
; WINDOWS-NOT: mov{{.}}ps
; WINDOWS: callq get_f
; WINDOWS-NOT: mov{{.}}ps
; WINDOWS-DAG: movq {{.*}}, %rdx
; WINDOWS-DAG: movq {{.*}}, %rcx
; WINDOWS-DAG: movq {{.*}}, %r8
; WINDOWS-DAG: movq {{.*}}, %r9
; WINDOWS-NOT: mov{{.}}ps
; WINDOWS: jmpq *{{.*}} # TAILCALL
; This thunk shouldn't require any spills and reloads, assuming the register
; allocator knows what it's doing.
define void @g_thunk(i8* %fptr_i8, ...) {
%fptr = bitcast i8* %fptr_i8 to void (i8*, ...)*
musttail call void (i8*, ...)* %fptr(i8* %fptr_i8, ...)
ret void
}
; LINUX-LABEL: g_thunk:
; LINUX-NOT: movq
; LINUX: jmpq *%rdi # TAILCALL
; WINDOWS-LABEL: g_thunk:
; WINDOWS-NOT: movq
; WINDOWS: jmpq *%rcx # TAILCALL
; Do a simple multi-exit multi-bb test.
%struct.Foo = type { i1, i8*, i8* }
@g = external global i32
define void @h_thunk(%struct.Foo* %this, ...) {
%cond_p = getelementptr %struct.Foo* %this, i32 0, i32 0
%cond = load i1* %cond_p
br i1 %cond, label %then, label %else
then:
%a_p = getelementptr %struct.Foo* %this, i32 0, i32 1
%a_i8 = load i8** %a_p
%a = bitcast i8* %a_i8 to void (%struct.Foo*, ...)*
musttail call void (%struct.Foo*, ...)* %a(%struct.Foo* %this, ...)
ret void
else:
%b_p = getelementptr %struct.Foo* %this, i32 0, i32 2
%b_i8 = load i8** %b_p
%b = bitcast i8* %b_i8 to void (%struct.Foo*, ...)*
store i32 42, i32* @g
musttail call void (%struct.Foo*, ...)* %b(%struct.Foo* %this, ...)
ret void
}
; LINUX-LABEL: h_thunk:
; LINUX: jne
; LINUX: jmpq *{{.*}} # TAILCALL
; LINUX: jmpq *{{.*}} # TAILCALL
; WINDOWS-LABEL: h_thunk:
; WINDOWS: jne
; WINDOWS: jmpq *{{.*}} # TAILCALL
; WINDOWS: jmpq *{{.*}} # TAILCALL