; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py UTC_ARGS: --version 5 ; RUN: llc -mtriple=armv7a-none-eabi %s -o - | FileCheck %s declare i32 @many_args_callee(i32 %0, i32 %1, i32 %2, i32 %3, i32 %4, i32 %5) define i32 @many_args_tail(i32 %0, i32 %1, i32 %2, i32 %3, i32 %4, i32 %5) { ; CHECK-LABEL: many_args_tail: ; CHECK: @ %bb.0: ; CHECK-NEXT: mov r0, #5 ; CHECK-NEXT: mov r1, #2 ; CHECK-NEXT: str r0, [sp] ; CHECK-NEXT: mov r0, #6 ; CHECK-NEXT: str r0, [sp, #4] ; CHECK-NEXT: mov r0, #1 ; CHECK-NEXT: mov r2, #3 ; CHECK-NEXT: mov r3, #4 ; CHECK-NEXT: b many_args_callee %ret = tail call i32 @many_args_callee(i32 1, i32 2, i32 3, i32 4, i32 5, i32 6) ret i32 %ret } define i32 @many_args_musttail(i32 %0, i32 %1, i32 %2, i32 %3, i32 %4, i32 %5) { ; CHECK-LABEL: many_args_musttail: ; CHECK: @ %bb.0: ; CHECK-NEXT: mov r0, #5 ; CHECK-NEXT: mov r1, #2 ; CHECK-NEXT: str r0, [sp] ; CHECK-NEXT: mov r0, #6 ; CHECK-NEXT: str r0, [sp, #4] ; CHECK-NEXT: mov r0, #1 ; CHECK-NEXT: mov r2, #3 ; CHECK-NEXT: mov r3, #4 ; CHECK-NEXT: b many_args_callee %ret = musttail call i32 @many_args_callee(i32 1, i32 2, i32 3, i32 4, i32 5, i32 6) ret i32 %ret } ; This function has more arguments than it's tail-callee. This isn't valid for ; the musttail attribute, but can still be tail-called as a non-guaranteed ; optimisation, because the outgoing arguments to @many_args_callee fit in the ; stack space allocated by the caller of @more_args_tail. define i32 @more_args_tail(i32 %0, i32 %1, i32 %2, i32 %3, i32 %4, i32 %5, i32 %6) { ; CHECK-LABEL: more_args_tail: ; CHECK: @ %bb.0: ; CHECK-NEXT: mov r0, #5 ; CHECK-NEXT: mov r1, #2 ; CHECK-NEXT: str r0, [sp] ; CHECK-NEXT: mov r0, #6 ; CHECK-NEXT: str r0, [sp, #4] ; CHECK-NEXT: mov r0, #1 ; CHECK-NEXT: mov r2, #3 ; CHECK-NEXT: mov r3, #4 ; CHECK-NEXT: b many_args_callee %ret = tail call i32 @many_args_callee(i32 1, i32 2, i32 3, i32 4, i32 5, i32 6) ret i32 %ret } ; Again, this isn't valid for musttail, but can be tail-called in practice ; because the stack size if the same. define i32 @different_args_tail(i64 %0, i64 %1, i64 %2) { ; CHECK-LABEL: different_args_tail: ; CHECK: @ %bb.0: ; CHECK-NEXT: mov r0, #5 ; CHECK-NEXT: mov r1, #2 ; CHECK-NEXT: str r0, [sp] ; CHECK-NEXT: mov r0, #6 ; CHECK-NEXT: str r0, [sp, #4] ; CHECK-NEXT: mov r0, #1 ; CHECK-NEXT: mov r2, #3 ; CHECK-NEXT: mov r3, #4 ; CHECK-NEXT: b many_args_callee %ret = tail call i32 @many_args_callee(i32 1, i32 2, i32 3, i32 4, i32 5, i32 6) ret i32 %ret } ; Here, the caller requires less stack space for it's arguments than the ; callee, so it would not ba valid to do a tail-call. define i32 @fewer_args_tail(i32 %0, i32 %1, i32 %2, i32 %3, i32 %4) { ; CHECK-LABEL: fewer_args_tail: ; CHECK: @ %bb.0: ; CHECK-NEXT: .save {r11, lr} ; CHECK-NEXT: push {r11, lr} ; CHECK-NEXT: .pad #8 ; CHECK-NEXT: sub sp, sp, #8 ; CHECK-NEXT: mov r1, #6 ; CHECK-NEXT: mov r0, #5 ; CHECK-NEXT: strd r0, r1, [sp] ; CHECK-NEXT: mov r0, #1 ; CHECK-NEXT: mov r1, #2 ; CHECK-NEXT: mov r2, #3 ; CHECK-NEXT: mov r3, #4 ; CHECK-NEXT: bl many_args_callee ; CHECK-NEXT: add sp, sp, #8 ; CHECK-NEXT: pop {r11, pc} %ret = tail call i32 @many_args_callee(i32 1, i32 2, i32 3, i32 4, i32 5, i32 6) ret i32 %ret } declare void @sret_callee(ptr sret({ double, double }) align 8) ; Functions which return by sret can be tail-called because the incoming sret ; pointer gets passed through to the callee. define void @sret_caller_tail(ptr sret({ double, double }) align 8 %result) { ; CHECK-LABEL: sret_caller_tail: ; CHECK: @ %bb.0: @ %entry ; CHECK-NEXT: b sret_callee entry: tail call void @sret_callee(ptr sret({ double, double }) align 8 %result) ret void } define void @sret_caller_musttail(ptr sret({ double, double }) align 8 %result) { ; CHECK-LABEL: sret_caller_musttail: ; CHECK: @ %bb.0: @ %entry ; CHECK-NEXT: b sret_callee entry: musttail call void @sret_callee(ptr sret({ double, double }) align 8 %result) ret void } ; Clang only uses byval for arguments of 65 bytes or larger, but we test with a ; 20 byte struct to keep the tests more readable. This size was chosen to still ; make sure that it will be split between registers and the stack, to test all ; of the interesting code paths in the backend. %twenty_bytes = type { [5 x i32] } declare void @large_callee(%twenty_bytes* byval(%twenty_bytes) align 4) ; Functions with byval parameters can be tail-called, because the value is ; actually passed in registers and the stack in the same way for the caller and ; callee. Within @large_caller the first 16 bytes of the argument are spilled ; to the local stack frame, but for the tail-call they are passed in r0-r3, so ; it's safe to de-allocate that memory before the call. ; TODO: The SUB and STM instructions are unnecessary and could be optimised ; out, but the behaviour of this is still correct. define void @large_caller(%twenty_bytes* byval(%twenty_bytes) align 4 %a) { ; CHECK-LABEL: large_caller: ; CHECK: @ %bb.0: @ %entry ; CHECK-NEXT: .pad #16 ; CHECK-NEXT: sub sp, sp, #16 ; CHECK-NEXT: stm sp!, {r0, r1, r2, r3} ; CHECK-NEXT: b large_callee entry: musttail call void @large_callee(%twenty_bytes* byval(%twenty_bytes) align 4 %a) ret void } ; As above, but with some inline asm to test that the arguments in r0-r3 are ; re-loaded before the call. define void @large_caller_check_regs(%twenty_bytes* byval(%twenty_bytes) align 4 %a) { ; CHECK-LABEL: large_caller_check_regs: ; CHECK: @ %bb.0: @ %entry ; CHECK-NEXT: .pad #16 ; CHECK-NEXT: sub sp, sp, #16 ; CHECK-NEXT: stm sp, {r0, r1, r2, r3} ; CHECK-NEXT: @APP ; CHECK-NEXT: @NO_APP ; CHECK-NEXT: pop {r0, r1, r2, r3} ; CHECK-NEXT: b large_callee entry: tail call void asm sideeffect "", "~{r0},~{r1},~{r2},~{r3}"() musttail call void @large_callee(%twenty_bytes* byval(%twenty_bytes) align 4 %a) ret void } ; The IR for this one looks dodgy, because it has an alloca passed to a ; musttail function, but it is passed as a byval argument, so will be copied ; into the stack space allocated by @large_caller_new_value's caller, so is ; valid. define void @large_caller_new_value(%twenty_bytes* byval(%twenty_bytes) align 4 %a) { ; CHECK-LABEL: large_caller_new_value: ; CHECK: @ %bb.0: @ %entry ; CHECK-NEXT: .pad #36 ; CHECK-NEXT: sub sp, sp, #36 ; CHECK-NEXT: add r12, sp, #20 ; CHECK-NEXT: stm r12, {r0, r1, r2, r3} ; CHECK-NEXT: mov r0, #4 ; CHECK-NEXT: add r1, sp, #36 ; CHECK-NEXT: str r0, [sp, #16] ; CHECK-NEXT: mov r0, #3 ; CHECK-NEXT: str r0, [sp, #12] ; CHECK-NEXT: mov r0, #2 ; CHECK-NEXT: str r0, [sp, #8] ; CHECK-NEXT: mov r0, #1 ; CHECK-NEXT: str r0, [sp, #4] ; CHECK-NEXT: mov r0, #0 ; CHECK-NEXT: str r0, [sp] ; CHECK-NEXT: mov r0, sp ; CHECK-NEXT: add r0, r0, #16 ; CHECK-NEXT: mov r3, #3 ; CHECK-NEXT: ldr r2, [r0], #4 ; CHECK-NEXT: str r2, [r1], #4 ; CHECK-NEXT: mov r0, #0 ; CHECK-NEXT: mov r1, #1 ; CHECK-NEXT: mov r2, #2 ; CHECK-NEXT: add sp, sp, #36 ; CHECK-NEXT: b large_callee entry: %y = alloca %twenty_bytes, align 4 store i32 0, ptr %y, align 4 %0 = getelementptr inbounds i8, ptr %y, i32 4 store i32 1, ptr %0, align 4 %1 = getelementptr inbounds i8, ptr %y, i32 8 store i32 2, ptr %1, align 4 %2 = getelementptr inbounds i8, ptr %y, i32 12 store i32 3, ptr %2, align 4 %3 = getelementptr inbounds i8, ptr %y, i32 16 store i32 4, ptr %3, align 4 musttail call void @large_callee(%twenty_bytes* byval(%twenty_bytes) align 4 %y) ret void } declare void @two_byvals_callee(%twenty_bytes* byval(%twenty_bytes) align 4, %twenty_bytes* byval(%twenty_bytes) align 4) define void @swap_byvals(%twenty_bytes* byval(%twenty_bytes) align 4 %a, %twenty_bytes* byval(%twenty_bytes) align 4 %b) { ; CHECK-LABEL: swap_byvals: ; CHECK: @ %bb.0: @ %entry ; CHECK-NEXT: .pad #16 ; CHECK-NEXT: sub sp, sp, #16 ; CHECK-NEXT: .save {r4, r5, r11, lr} ; CHECK-NEXT: push {r4, r5, r11, lr} ; CHECK-NEXT: .pad #40 ; CHECK-NEXT: sub sp, sp, #40 ; CHECK-NEXT: add r12, sp, #56 ; CHECK-NEXT: add lr, sp, #20 ; CHECK-NEXT: stm r12, {r0, r1, r2, r3} ; CHECK-NEXT: add r0, sp, #56 ; CHECK-NEXT: mov r12, sp ; CHECK-NEXT: ldr r1, [r0], #4 ; CHECK-NEXT: mov r2, r12 ; CHECK-NEXT: str r1, [r2], #4 ; CHECK-NEXT: add r3, sp, #20 ; CHECK-NEXT: ldr r1, [r0], #4 ; CHECK-NEXT: add r4, sp, #76 ; CHECK-NEXT: str r1, [r2], #4 ; CHECK-NEXT: ldr r1, [r0], #4 ; CHECK-NEXT: str r1, [r2], #4 ; CHECK-NEXT: ldr r1, [r0], #4 ; CHECK-NEXT: str r1, [r2], #4 ; CHECK-NEXT: ldr r1, [r0], #4 ; CHECK-NEXT: add r0, sp, #76 ; CHECK-NEXT: str r1, [r2], #4 ; CHECK-NEXT: mov r2, lr ; CHECK-NEXT: ldr r1, [r0], #4 ; CHECK-NEXT: str r1, [r2], #4 ; CHECK-NEXT: ldr r1, [r0], #4 ; CHECK-NEXT: str r1, [r2], #4 ; CHECK-NEXT: ldr r1, [r0], #4 ; CHECK-NEXT: str r1, [r2], #4 ; CHECK-NEXT: ldr r1, [r0], #4 ; CHECK-NEXT: str r1, [r2], #4 ; CHECK-NEXT: ldr r1, [r0], #4 ; CHECK-NEXT: str r1, [r2], #4 ; CHECK-NEXT: ldm r3, {r0, r1, r2, r3} ; CHECK-NEXT: ldr r5, [r12], #4 ; CHECK-NEXT: str r5, [r4], #4 ; CHECK-NEXT: ldr r5, [r12], #4 ; CHECK-NEXT: str r5, [r4], #4 ; CHECK-NEXT: ldr r5, [r12], #4 ; CHECK-NEXT: str r5, [r4], #4 ; CHECK-NEXT: ldr r5, [r12], #4 ; CHECK-NEXT: str r5, [r4], #4 ; CHECK-NEXT: ldr r5, [r12], #4 ; CHECK-NEXT: str r5, [r4], #4 ; CHECK-NEXT: add r5, lr, #16 ; CHECK-NEXT: add r12, sp, #72 ; CHECK-NEXT: ldr r4, [r5], #4 ; CHECK-NEXT: str r4, [r12], #4 ; CHECK-NEXT: add sp, sp, #40 ; CHECK-NEXT: pop {r4, r5, r11, lr} ; CHECK-NEXT: add sp, sp, #16 ; CHECK-NEXT: b two_byvals_callee entry: musttail call void @two_byvals_callee(%twenty_bytes* byval(%twenty_bytes) align 4 %b, %twenty_bytes* byval(%twenty_bytes) align 4 %a) ret void } ; A forwarded byval arg, but at a different offset on the stack, so it needs to ; be copied to the local stack frame first. This can't be musttail because of ; the different signatures, but is still tail-called as an optimisation. declare void @shift_byval_callee(%twenty_bytes* byval(%twenty_bytes) align 4) define void @shift_byval(i32 %a, %twenty_bytes* byval(%twenty_bytes) align 4 %b) { ; CHECK-LABEL: shift_byval: ; CHECK: @ %bb.0: @ %entry ; CHECK-NEXT: .pad #12 ; CHECK-NEXT: sub sp, sp, #12 ; CHECK-NEXT: .save {r4, lr} ; CHECK-NEXT: push {r4, lr} ; CHECK-NEXT: .pad #20 ; CHECK-NEXT: sub sp, sp, #20 ; CHECK-NEXT: add r0, sp, #28 ; CHECK-NEXT: add lr, sp, #40 ; CHECK-NEXT: stm r0, {r1, r2, r3} ; CHECK-NEXT: add r0, sp, #28 ; CHECK-NEXT: mov r1, sp ; CHECK-NEXT: ldr r2, [r0], #4 ; CHECK-NEXT: add r12, r1, #16 ; CHECK-NEXT: str r2, [r1], #4 ; CHECK-NEXT: ldr r2, [r0], #4 ; CHECK-NEXT: str r2, [r1], #4 ; CHECK-NEXT: ldr r2, [r0], #4 ; CHECK-NEXT: str r2, [r1], #4 ; CHECK-NEXT: ldr r2, [r0], #4 ; CHECK-NEXT: str r2, [r1], #4 ; CHECK-NEXT: ldr r2, [r0], #4 ; CHECK-NEXT: str r2, [r1], #4 ; CHECK-NEXT: ldm sp, {r0, r1, r2, r3} ; CHECK-NEXT: ldr r4, [r12], #4 ; CHECK-NEXT: str r4, [lr], #4 ; CHECK-NEXT: add sp, sp, #20 ; CHECK-NEXT: pop {r4, lr} ; CHECK-NEXT: add sp, sp, #12 ; CHECK-NEXT: b shift_byval_callee entry: tail call void @shift_byval_callee(%twenty_bytes* byval(%twenty_bytes) align 4 %b) ret void } ; A global object passed to a byval argument, so it must be copied, but doesn't ; need a stack temporary. @large_global = external global %twenty_bytes define void @large_caller_from_global(%twenty_bytes* byval(%twenty_bytes) align 4 %a) { ; CHECK-LABEL: large_caller_from_global: ; CHECK: @ %bb.0: @ %entry ; CHECK-NEXT: .pad #16 ; CHECK-NEXT: sub sp, sp, #16 ; CHECK-NEXT: .save {r4, lr} ; CHECK-NEXT: push {r4, lr} ; CHECK-NEXT: add r12, sp, #8 ; CHECK-NEXT: add lr, sp, #24 ; CHECK-NEXT: stm r12, {r0, r1, r2, r3} ; CHECK-NEXT: movw r3, :lower16:large_global ; CHECK-NEXT: movt r3, :upper16:large_global ; CHECK-NEXT: add r12, r3, #16 ; CHECK-NEXT: ldm r3, {r0, r1, r2, r3} ; CHECK-NEXT: ldr r4, [r12], #4 ; CHECK-NEXT: str r4, [lr], #4 ; CHECK-NEXT: pop {r4, lr} ; CHECK-NEXT: add sp, sp, #16 ; CHECK-NEXT: b large_callee entry: musttail call void @large_callee(%twenty_bytes* byval(%twenty_bytes) align 4 @large_global) ret void }