; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py ; RUN: llc -mtriple=riscv32 -verify-machineinstrs < %s \ ; RUN: | FileCheck -check-prefix=RV32I-FPELIM %s ; RUN: llc -mtriple=riscv32 -mattr=+f -target-abi ilp32f \ ; RUN: -verify-machineinstrs < %s \ ; RUN: | FileCheck -check-prefix=RV32I-FPELIM %s ; RUN: llc -mtriple=riscv32 -mattr=+d -target-abi ilp32d \ ; RUN: -verify-machineinstrs < %s \ ; RUN: | FileCheck -check-prefix=RV32I-FPELIM %s ; RUN: llc -mtriple=riscv32 -verify-machineinstrs -frame-pointer=all < %s \ ; RUN: | FileCheck -check-prefix=RV32I-WITHFP %s ; RUN: llc -mtriple=riscv32 -verify-machineinstrs -frame-pointer=all \ ; RUN: -mattr=+f -target-abi ilp32f < %s \ ; RUN: | FileCheck -check-prefix=RV32I-WITHFP %s ; RUN: llc -mtriple=riscv32 -verify-machineinstrs -frame-pointer=all \ ; RUN: -mattr=+d -target-abi ilp32d < %s \ ; RUN: | FileCheck -check-prefix=RV32I-WITHFP %s ; This file contains tests that should have identical output for the ilp32, ; ilp32f, and ilp32d ABIs. i.e. where no arguments are passed according to ; the floating point ABI. As well as calling convention details, we check that ; ra and fp are consistently stored to fp-4 and fp-8. ; Check that on RV32, i64 is passed in a pair of registers. Unlike ; the convention for varargs, this need not be an aligned pair. define i32 @callee_i64_in_regs(i32 %a, i64 %b) nounwind { ; RV32I-FPELIM-LABEL: callee_i64_in_regs: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: add a0, a0, a1 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: callee_i64_in_regs: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: add a0, a0, a1 ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %b_trunc = trunc i64 %b to i32 %1 = add i32 %a, %b_trunc ret i32 %1 } define i32 @caller_i64_in_regs() nounwind { ; RV32I-FPELIM-LABEL: caller_i64_in_regs: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: addi sp, sp, -16 ; RV32I-FPELIM-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-FPELIM-NEXT: li a0, 1 ; RV32I-FPELIM-NEXT: li a1, 2 ; RV32I-FPELIM-NEXT: li a2, 0 ; RV32I-FPELIM-NEXT: call callee_i64_in_regs@plt ; RV32I-FPELIM-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-FPELIM-NEXT: addi sp, sp, 16 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: caller_i64_in_regs: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: li a0, 1 ; RV32I-WITHFP-NEXT: li a1, 2 ; RV32I-WITHFP-NEXT: li a2, 0 ; RV32I-WITHFP-NEXT: call callee_i64_in_regs@plt ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %1 = call i32 @callee_i64_in_regs(i32 1, i64 2) ret i32 %1 } ; Check that the stack is used once the GPRs are exhausted define i32 @callee_many_scalars(i8 %a, i16 %b, i32 %c, i64 %d, i32 %e, i32 %f, i64 %g, i32 %h) nounwind { ; RV32I-FPELIM-LABEL: callee_many_scalars: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: lw t0, 4(sp) ; RV32I-FPELIM-NEXT: lw t1, 0(sp) ; RV32I-FPELIM-NEXT: andi a0, a0, 255 ; RV32I-FPELIM-NEXT: slli a1, a1, 16 ; RV32I-FPELIM-NEXT: srli a1, a1, 16 ; RV32I-FPELIM-NEXT: add a0, a0, a1 ; RV32I-FPELIM-NEXT: add a0, a0, a2 ; RV32I-FPELIM-NEXT: xor a1, a4, t1 ; RV32I-FPELIM-NEXT: xor a2, a3, a7 ; RV32I-FPELIM-NEXT: or a1, a2, a1 ; RV32I-FPELIM-NEXT: seqz a1, a1 ; RV32I-FPELIM-NEXT: add a0, a1, a0 ; RV32I-FPELIM-NEXT: add a0, a0, a5 ; RV32I-FPELIM-NEXT: add a0, a0, a6 ; RV32I-FPELIM-NEXT: add a0, a0, t0 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: callee_many_scalars: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: lw t0, 4(s0) ; RV32I-WITHFP-NEXT: lw t1, 0(s0) ; RV32I-WITHFP-NEXT: andi a0, a0, 255 ; RV32I-WITHFP-NEXT: slli a1, a1, 16 ; RV32I-WITHFP-NEXT: srli a1, a1, 16 ; RV32I-WITHFP-NEXT: add a0, a0, a1 ; RV32I-WITHFP-NEXT: add a0, a0, a2 ; RV32I-WITHFP-NEXT: xor a1, a4, t1 ; RV32I-WITHFP-NEXT: xor a2, a3, a7 ; RV32I-WITHFP-NEXT: or a1, a2, a1 ; RV32I-WITHFP-NEXT: seqz a1, a1 ; RV32I-WITHFP-NEXT: add a0, a1, a0 ; RV32I-WITHFP-NEXT: add a0, a0, a5 ; RV32I-WITHFP-NEXT: add a0, a0, a6 ; RV32I-WITHFP-NEXT: add a0, a0, t0 ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %a_ext = zext i8 %a to i32 %b_ext = zext i16 %b to i32 %1 = add i32 %a_ext, %b_ext %2 = add i32 %1, %c %3 = icmp eq i64 %d, %g %4 = zext i1 %3 to i32 %5 = add i32 %4, %2 %6 = add i32 %5, %e %7 = add i32 %6, %f %8 = add i32 %7, %h ret i32 %8 } define i32 @caller_many_scalars() nounwind { ; RV32I-FPELIM-LABEL: caller_many_scalars: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: addi sp, sp, -16 ; RV32I-FPELIM-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-FPELIM-NEXT: li a0, 8 ; RV32I-FPELIM-NEXT: sw a0, 4(sp) ; RV32I-FPELIM-NEXT: li a0, 1 ; RV32I-FPELIM-NEXT: li a1, 2 ; RV32I-FPELIM-NEXT: li a2, 3 ; RV32I-FPELIM-NEXT: li a3, 4 ; RV32I-FPELIM-NEXT: li a5, 5 ; RV32I-FPELIM-NEXT: li a6, 6 ; RV32I-FPELIM-NEXT: li a7, 7 ; RV32I-FPELIM-NEXT: sw zero, 0(sp) ; RV32I-FPELIM-NEXT: li a4, 0 ; RV32I-FPELIM-NEXT: call callee_many_scalars@plt ; RV32I-FPELIM-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-FPELIM-NEXT: addi sp, sp, 16 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: caller_many_scalars: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: li a0, 8 ; RV32I-WITHFP-NEXT: sw a0, 4(sp) ; RV32I-WITHFP-NEXT: li a0, 1 ; RV32I-WITHFP-NEXT: li a1, 2 ; RV32I-WITHFP-NEXT: li a2, 3 ; RV32I-WITHFP-NEXT: li a3, 4 ; RV32I-WITHFP-NEXT: li a5, 5 ; RV32I-WITHFP-NEXT: li a6, 6 ; RV32I-WITHFP-NEXT: li a7, 7 ; RV32I-WITHFP-NEXT: sw zero, 0(sp) ; RV32I-WITHFP-NEXT: li a4, 0 ; RV32I-WITHFP-NEXT: call callee_many_scalars@plt ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %1 = call i32 @callee_many_scalars(i8 1, i16 2, i32 3, i64 4, i32 5, i32 6, i64 7, i32 8) ret i32 %1 } ; Check that i128 and fp128 are passed indirectly define i32 @callee_large_scalars(i128 %a, fp128 %b) nounwind { ; RV32I-FPELIM-LABEL: callee_large_scalars: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: lw a2, 0(a1) ; RV32I-FPELIM-NEXT: lw a3, 0(a0) ; RV32I-FPELIM-NEXT: lw a4, 4(a1) ; RV32I-FPELIM-NEXT: lw a5, 12(a1) ; RV32I-FPELIM-NEXT: lw a6, 12(a0) ; RV32I-FPELIM-NEXT: lw a7, 4(a0) ; RV32I-FPELIM-NEXT: lw a1, 8(a1) ; RV32I-FPELIM-NEXT: lw a0, 8(a0) ; RV32I-FPELIM-NEXT: xor a5, a6, a5 ; RV32I-FPELIM-NEXT: xor a4, a7, a4 ; RV32I-FPELIM-NEXT: or a4, a4, a5 ; RV32I-FPELIM-NEXT: xor a0, a0, a1 ; RV32I-FPELIM-NEXT: xor a1, a3, a2 ; RV32I-FPELIM-NEXT: or a0, a1, a0 ; RV32I-FPELIM-NEXT: or a0, a0, a4 ; RV32I-FPELIM-NEXT: seqz a0, a0 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: callee_large_scalars: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: lw a2, 0(a1) ; RV32I-WITHFP-NEXT: lw a3, 0(a0) ; RV32I-WITHFP-NEXT: lw a4, 4(a1) ; RV32I-WITHFP-NEXT: lw a5, 12(a1) ; RV32I-WITHFP-NEXT: lw a6, 12(a0) ; RV32I-WITHFP-NEXT: lw a7, 4(a0) ; RV32I-WITHFP-NEXT: lw a1, 8(a1) ; RV32I-WITHFP-NEXT: lw a0, 8(a0) ; RV32I-WITHFP-NEXT: xor a5, a6, a5 ; RV32I-WITHFP-NEXT: xor a4, a7, a4 ; RV32I-WITHFP-NEXT: or a4, a4, a5 ; RV32I-WITHFP-NEXT: xor a0, a0, a1 ; RV32I-WITHFP-NEXT: xor a1, a3, a2 ; RV32I-WITHFP-NEXT: or a0, a1, a0 ; RV32I-WITHFP-NEXT: or a0, a0, a4 ; RV32I-WITHFP-NEXT: seqz a0, a0 ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %b_bitcast = bitcast fp128 %b to i128 %1 = icmp eq i128 %a, %b_bitcast %2 = zext i1 %1 to i32 ret i32 %2 } define i32 @caller_large_scalars() nounwind { ; RV32I-FPELIM-LABEL: caller_large_scalars: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: addi sp, sp, -48 ; RV32I-FPELIM-NEXT: sw ra, 44(sp) # 4-byte Folded Spill ; RV32I-FPELIM-NEXT: lui a0, 524272 ; RV32I-FPELIM-NEXT: sw a0, 12(sp) ; RV32I-FPELIM-NEXT: sw zero, 8(sp) ; RV32I-FPELIM-NEXT: sw zero, 4(sp) ; RV32I-FPELIM-NEXT: sw zero, 0(sp) ; RV32I-FPELIM-NEXT: sw zero, 36(sp) ; RV32I-FPELIM-NEXT: sw zero, 32(sp) ; RV32I-FPELIM-NEXT: sw zero, 28(sp) ; RV32I-FPELIM-NEXT: li a2, 1 ; RV32I-FPELIM-NEXT: addi a0, sp, 24 ; RV32I-FPELIM-NEXT: mv a1, sp ; RV32I-FPELIM-NEXT: sw a2, 24(sp) ; RV32I-FPELIM-NEXT: call callee_large_scalars@plt ; RV32I-FPELIM-NEXT: lw ra, 44(sp) # 4-byte Folded Reload ; RV32I-FPELIM-NEXT: addi sp, sp, 48 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: caller_large_scalars: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -48 ; RV32I-WITHFP-NEXT: sw ra, 44(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 40(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 48 ; RV32I-WITHFP-NEXT: lui a0, 524272 ; RV32I-WITHFP-NEXT: sw a0, -36(s0) ; RV32I-WITHFP-NEXT: sw zero, -40(s0) ; RV32I-WITHFP-NEXT: sw zero, -44(s0) ; RV32I-WITHFP-NEXT: sw zero, -48(s0) ; RV32I-WITHFP-NEXT: sw zero, -12(s0) ; RV32I-WITHFP-NEXT: sw zero, -16(s0) ; RV32I-WITHFP-NEXT: sw zero, -20(s0) ; RV32I-WITHFP-NEXT: li a2, 1 ; RV32I-WITHFP-NEXT: addi a0, s0, -24 ; RV32I-WITHFP-NEXT: addi a1, s0, -48 ; RV32I-WITHFP-NEXT: sw a2, -24(s0) ; RV32I-WITHFP-NEXT: call callee_large_scalars@plt ; RV32I-WITHFP-NEXT: lw ra, 44(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 40(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 48 ; RV32I-WITHFP-NEXT: ret %1 = call i32 @callee_large_scalars(i128 1, fp128 0xL00000000000000007FFF000000000000) ret i32 %1 } ; Check that arguments larger than 2*xlen are handled correctly when their ; address is passed on the stack rather than in memory ; Must keep define on a single line due to an update_llc_test_checks.py limitation define i32 @callee_large_scalars_exhausted_regs(i32 %a, i32 %b, i32 %c, i32 %d, i32 %e, i32 %f, i32 %g, i128 %h, i32 %i, fp128 %j) nounwind { ; RV32I-FPELIM-LABEL: callee_large_scalars_exhausted_regs: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: lw a0, 4(sp) ; RV32I-FPELIM-NEXT: lw a1, 0(a0) ; RV32I-FPELIM-NEXT: lw a2, 0(a7) ; RV32I-FPELIM-NEXT: lw a3, 4(a0) ; RV32I-FPELIM-NEXT: lw a4, 12(a0) ; RV32I-FPELIM-NEXT: lw a5, 12(a7) ; RV32I-FPELIM-NEXT: lw a6, 4(a7) ; RV32I-FPELIM-NEXT: lw a0, 8(a0) ; RV32I-FPELIM-NEXT: lw a7, 8(a7) ; RV32I-FPELIM-NEXT: xor a4, a5, a4 ; RV32I-FPELIM-NEXT: xor a3, a6, a3 ; RV32I-FPELIM-NEXT: or a3, a3, a4 ; RV32I-FPELIM-NEXT: xor a0, a7, a0 ; RV32I-FPELIM-NEXT: xor a1, a2, a1 ; RV32I-FPELIM-NEXT: or a0, a1, a0 ; RV32I-FPELIM-NEXT: or a0, a0, a3 ; RV32I-FPELIM-NEXT: seqz a0, a0 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: callee_large_scalars_exhausted_regs: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: lw a0, 4(s0) ; RV32I-WITHFP-NEXT: lw a1, 0(a0) ; RV32I-WITHFP-NEXT: lw a2, 0(a7) ; RV32I-WITHFP-NEXT: lw a3, 4(a0) ; RV32I-WITHFP-NEXT: lw a4, 12(a0) ; RV32I-WITHFP-NEXT: lw a5, 12(a7) ; RV32I-WITHFP-NEXT: lw a6, 4(a7) ; RV32I-WITHFP-NEXT: lw a0, 8(a0) ; RV32I-WITHFP-NEXT: lw a7, 8(a7) ; RV32I-WITHFP-NEXT: xor a4, a5, a4 ; RV32I-WITHFP-NEXT: xor a3, a6, a3 ; RV32I-WITHFP-NEXT: or a3, a3, a4 ; RV32I-WITHFP-NEXT: xor a0, a7, a0 ; RV32I-WITHFP-NEXT: xor a1, a2, a1 ; RV32I-WITHFP-NEXT: or a0, a1, a0 ; RV32I-WITHFP-NEXT: or a0, a0, a3 ; RV32I-WITHFP-NEXT: seqz a0, a0 ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %j_bitcast = bitcast fp128 %j to i128 %1 = icmp eq i128 %h, %j_bitcast %2 = zext i1 %1 to i32 ret i32 %2 } define i32 @caller_large_scalars_exhausted_regs() nounwind { ; RV32I-FPELIM-LABEL: caller_large_scalars_exhausted_regs: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: addi sp, sp, -64 ; RV32I-FPELIM-NEXT: sw ra, 60(sp) # 4-byte Folded Spill ; RV32I-FPELIM-NEXT: addi a0, sp, 16 ; RV32I-FPELIM-NEXT: sw a0, 4(sp) ; RV32I-FPELIM-NEXT: li a0, 9 ; RV32I-FPELIM-NEXT: sw a0, 0(sp) ; RV32I-FPELIM-NEXT: lui a0, 524272 ; RV32I-FPELIM-NEXT: sw a0, 28(sp) ; RV32I-FPELIM-NEXT: sw zero, 24(sp) ; RV32I-FPELIM-NEXT: sw zero, 20(sp) ; RV32I-FPELIM-NEXT: sw zero, 16(sp) ; RV32I-FPELIM-NEXT: sw zero, 52(sp) ; RV32I-FPELIM-NEXT: sw zero, 48(sp) ; RV32I-FPELIM-NEXT: sw zero, 44(sp) ; RV32I-FPELIM-NEXT: li t0, 8 ; RV32I-FPELIM-NEXT: li a0, 1 ; RV32I-FPELIM-NEXT: li a1, 2 ; RV32I-FPELIM-NEXT: li a2, 3 ; RV32I-FPELIM-NEXT: li a3, 4 ; RV32I-FPELIM-NEXT: li a4, 5 ; RV32I-FPELIM-NEXT: li a5, 6 ; RV32I-FPELIM-NEXT: li a6, 7 ; RV32I-FPELIM-NEXT: addi a7, sp, 40 ; RV32I-FPELIM-NEXT: sw t0, 40(sp) ; RV32I-FPELIM-NEXT: call callee_large_scalars_exhausted_regs@plt ; RV32I-FPELIM-NEXT: lw ra, 60(sp) # 4-byte Folded Reload ; RV32I-FPELIM-NEXT: addi sp, sp, 64 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: caller_large_scalars_exhausted_regs: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -64 ; RV32I-WITHFP-NEXT: sw ra, 60(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 56(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 64 ; RV32I-WITHFP-NEXT: addi a0, s0, -48 ; RV32I-WITHFP-NEXT: sw a0, 4(sp) ; RV32I-WITHFP-NEXT: li a0, 9 ; RV32I-WITHFP-NEXT: sw a0, 0(sp) ; RV32I-WITHFP-NEXT: lui a0, 524272 ; RV32I-WITHFP-NEXT: sw a0, -36(s0) ; RV32I-WITHFP-NEXT: sw zero, -40(s0) ; RV32I-WITHFP-NEXT: sw zero, -44(s0) ; RV32I-WITHFP-NEXT: sw zero, -48(s0) ; RV32I-WITHFP-NEXT: sw zero, -12(s0) ; RV32I-WITHFP-NEXT: sw zero, -16(s0) ; RV32I-WITHFP-NEXT: sw zero, -20(s0) ; RV32I-WITHFP-NEXT: li t0, 8 ; RV32I-WITHFP-NEXT: li a0, 1 ; RV32I-WITHFP-NEXT: li a1, 2 ; RV32I-WITHFP-NEXT: li a2, 3 ; RV32I-WITHFP-NEXT: li a3, 4 ; RV32I-WITHFP-NEXT: li a4, 5 ; RV32I-WITHFP-NEXT: li a5, 6 ; RV32I-WITHFP-NEXT: li a6, 7 ; RV32I-WITHFP-NEXT: addi a7, s0, -24 ; RV32I-WITHFP-NEXT: sw t0, -24(s0) ; RV32I-WITHFP-NEXT: call callee_large_scalars_exhausted_regs@plt ; RV32I-WITHFP-NEXT: lw ra, 60(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 56(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 64 ; RV32I-WITHFP-NEXT: ret %1 = call i32 @callee_large_scalars_exhausted_regs( i32 1, i32 2, i32 3, i32 4, i32 5, i32 6, i32 7, i128 8, i32 9, fp128 0xL00000000000000007FFF000000000000) ret i32 %1 } ; Ensure that libcalls generated in the middle-end obey the calling convention define i32 @caller_mixed_scalar_libcalls(i64 %a) nounwind { ; RV32I-FPELIM-LABEL: caller_mixed_scalar_libcalls: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: addi sp, sp, -32 ; RV32I-FPELIM-NEXT: sw ra, 28(sp) # 4-byte Folded Spill ; RV32I-FPELIM-NEXT: mv a2, a1 ; RV32I-FPELIM-NEXT: mv a1, a0 ; RV32I-FPELIM-NEXT: addi a0, sp, 8 ; RV32I-FPELIM-NEXT: call __floatditf@plt ; RV32I-FPELIM-NEXT: lw a0, 8(sp) ; RV32I-FPELIM-NEXT: lw ra, 28(sp) # 4-byte Folded Reload ; RV32I-FPELIM-NEXT: addi sp, sp, 32 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: caller_mixed_scalar_libcalls: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -32 ; RV32I-WITHFP-NEXT: sw ra, 28(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 24(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 32 ; RV32I-WITHFP-NEXT: mv a2, a1 ; RV32I-WITHFP-NEXT: mv a1, a0 ; RV32I-WITHFP-NEXT: addi a0, s0, -24 ; RV32I-WITHFP-NEXT: call __floatditf@plt ; RV32I-WITHFP-NEXT: lw a0, -24(s0) ; RV32I-WITHFP-NEXT: lw ra, 28(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 24(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 32 ; RV32I-WITHFP-NEXT: ret %1 = sitofp i64 %a to fp128 %2 = bitcast fp128 %1 to i128 %3 = trunc i128 %2 to i32 ret i32 %3 } ; Check passing of coerced integer arrays %struct.small = type { i32, i32* } define i32 @callee_small_coerced_struct([2 x i32] %a.coerce) nounwind { ; RV32I-FPELIM-LABEL: callee_small_coerced_struct: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: xor a0, a0, a1 ; RV32I-FPELIM-NEXT: seqz a0, a0 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: callee_small_coerced_struct: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: xor a0, a0, a1 ; RV32I-WITHFP-NEXT: seqz a0, a0 ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %1 = extractvalue [2 x i32] %a.coerce, 0 %2 = extractvalue [2 x i32] %a.coerce, 1 %3 = icmp eq i32 %1, %2 %4 = zext i1 %3 to i32 ret i32 %4 } define i32 @caller_small_coerced_struct() nounwind { ; RV32I-FPELIM-LABEL: caller_small_coerced_struct: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: addi sp, sp, -16 ; RV32I-FPELIM-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-FPELIM-NEXT: li a0, 1 ; RV32I-FPELIM-NEXT: li a1, 2 ; RV32I-FPELIM-NEXT: call callee_small_coerced_struct@plt ; RV32I-FPELIM-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-FPELIM-NEXT: addi sp, sp, 16 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: caller_small_coerced_struct: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: li a0, 1 ; RV32I-WITHFP-NEXT: li a1, 2 ; RV32I-WITHFP-NEXT: call callee_small_coerced_struct@plt ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %1 = call i32 @callee_small_coerced_struct([2 x i32] [i32 1, i32 2]) ret i32 %1 } ; Check large struct arguments, which are passed byval %struct.large = type { i32, i32, i32, i32 } define i32 @callee_large_struct(%struct.large* byval(%struct.large) align 4 %a) nounwind { ; RV32I-FPELIM-LABEL: callee_large_struct: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: lw a1, 0(a0) ; RV32I-FPELIM-NEXT: lw a0, 12(a0) ; RV32I-FPELIM-NEXT: add a0, a1, a0 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: callee_large_struct: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: lw a1, 0(a0) ; RV32I-WITHFP-NEXT: lw a0, 12(a0) ; RV32I-WITHFP-NEXT: add a0, a1, a0 ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %1 = getelementptr inbounds %struct.large, %struct.large* %a, i32 0, i32 0 %2 = getelementptr inbounds %struct.large, %struct.large* %a, i32 0, i32 3 %3 = load i32, i32* %1 %4 = load i32, i32* %2 %5 = add i32 %3, %4 ret i32 %5 } define i32 @caller_large_struct() nounwind { ; RV32I-FPELIM-LABEL: caller_large_struct: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: addi sp, sp, -48 ; RV32I-FPELIM-NEXT: sw ra, 44(sp) # 4-byte Folded Spill ; RV32I-FPELIM-NEXT: li a0, 1 ; RV32I-FPELIM-NEXT: sw a0, 24(sp) ; RV32I-FPELIM-NEXT: li a1, 2 ; RV32I-FPELIM-NEXT: sw a1, 28(sp) ; RV32I-FPELIM-NEXT: li a2, 3 ; RV32I-FPELIM-NEXT: sw a2, 32(sp) ; RV32I-FPELIM-NEXT: li a3, 4 ; RV32I-FPELIM-NEXT: sw a3, 36(sp) ; RV32I-FPELIM-NEXT: sw a0, 8(sp) ; RV32I-FPELIM-NEXT: sw a1, 12(sp) ; RV32I-FPELIM-NEXT: sw a2, 16(sp) ; RV32I-FPELIM-NEXT: sw a3, 20(sp) ; RV32I-FPELIM-NEXT: addi a0, sp, 8 ; RV32I-FPELIM-NEXT: call callee_large_struct@plt ; RV32I-FPELIM-NEXT: lw ra, 44(sp) # 4-byte Folded Reload ; RV32I-FPELIM-NEXT: addi sp, sp, 48 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: caller_large_struct: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -48 ; RV32I-WITHFP-NEXT: sw ra, 44(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 40(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 48 ; RV32I-WITHFP-NEXT: li a0, 1 ; RV32I-WITHFP-NEXT: sw a0, -24(s0) ; RV32I-WITHFP-NEXT: li a1, 2 ; RV32I-WITHFP-NEXT: sw a1, -20(s0) ; RV32I-WITHFP-NEXT: li a2, 3 ; RV32I-WITHFP-NEXT: sw a2, -16(s0) ; RV32I-WITHFP-NEXT: li a3, 4 ; RV32I-WITHFP-NEXT: sw a3, -12(s0) ; RV32I-WITHFP-NEXT: sw a0, -40(s0) ; RV32I-WITHFP-NEXT: sw a1, -36(s0) ; RV32I-WITHFP-NEXT: sw a2, -32(s0) ; RV32I-WITHFP-NEXT: sw a3, -28(s0) ; RV32I-WITHFP-NEXT: addi a0, s0, -40 ; RV32I-WITHFP-NEXT: call callee_large_struct@plt ; RV32I-WITHFP-NEXT: lw ra, 44(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 40(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 48 ; RV32I-WITHFP-NEXT: ret %ls = alloca %struct.large, align 4 %1 = bitcast %struct.large* %ls to i8* %a = getelementptr inbounds %struct.large, %struct.large* %ls, i32 0, i32 0 store i32 1, i32* %a %b = getelementptr inbounds %struct.large, %struct.large* %ls, i32 0, i32 1 store i32 2, i32* %b %c = getelementptr inbounds %struct.large, %struct.large* %ls, i32 0, i32 2 store i32 3, i32* %c %d = getelementptr inbounds %struct.large, %struct.large* %ls, i32 0, i32 3 store i32 4, i32* %d %2 = call i32 @callee_large_struct(%struct.large* byval(%struct.large) align 4 %ls) ret i32 %2 } ; Check 2x*xlen values are aligned appropriately when passed on the stack ; Must keep define on a single line due to an update_llc_test_checks.py limitation define i32 @callee_aligned_stack(i32 %a, i32 %b, fp128 %c, i32 %d, i32 %e, i64 %f, i32 %g, i32 %h, i64 %i, i32 %j, [2 x i32] %k) nounwind { ; The i64 should be 8-byte aligned on the stack, but the two-element array ; should only be 4-byte aligned ; RV32I-FPELIM-LABEL: callee_aligned_stack: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: lw a0, 0(a2) ; RV32I-FPELIM-NEXT: lw a1, 20(sp) ; RV32I-FPELIM-NEXT: lw a2, 0(sp) ; RV32I-FPELIM-NEXT: lw a3, 8(sp) ; RV32I-FPELIM-NEXT: lw a4, 16(sp) ; RV32I-FPELIM-NEXT: add a0, a0, a7 ; RV32I-FPELIM-NEXT: add a0, a0, a2 ; RV32I-FPELIM-NEXT: add a0, a0, a3 ; RV32I-FPELIM-NEXT: add a0, a0, a4 ; RV32I-FPELIM-NEXT: add a0, a0, a1 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: callee_aligned_stack: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: lw a0, 0(a2) ; RV32I-WITHFP-NEXT: lw a1, 20(s0) ; RV32I-WITHFP-NEXT: lw a2, 0(s0) ; RV32I-WITHFP-NEXT: lw a3, 8(s0) ; RV32I-WITHFP-NEXT: lw a4, 16(s0) ; RV32I-WITHFP-NEXT: add a0, a0, a7 ; RV32I-WITHFP-NEXT: add a0, a0, a2 ; RV32I-WITHFP-NEXT: add a0, a0, a3 ; RV32I-WITHFP-NEXT: add a0, a0, a4 ; RV32I-WITHFP-NEXT: add a0, a0, a1 ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %1 = bitcast fp128 %c to i128 %2 = trunc i128 %1 to i32 %3 = add i32 %2, %g %4 = add i32 %3, %h %5 = trunc i64 %i to i32 %6 = add i32 %4, %5 %7 = add i32 %6, %j %8 = extractvalue [2 x i32] %k, 0 %9 = add i32 %7, %8 ret i32 %9 } define void @caller_aligned_stack() nounwind { ; The i64 should be 8-byte aligned on the stack, but the two-element array ; should only be 4-byte aligned ; RV32I-FPELIM-LABEL: caller_aligned_stack: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: addi sp, sp, -64 ; RV32I-FPELIM-NEXT: sw ra, 60(sp) # 4-byte Folded Spill ; RV32I-FPELIM-NEXT: li a0, 19 ; RV32I-FPELIM-NEXT: sw a0, 24(sp) ; RV32I-FPELIM-NEXT: li a0, 18 ; RV32I-FPELIM-NEXT: sw a0, 20(sp) ; RV32I-FPELIM-NEXT: li a0, 17 ; RV32I-FPELIM-NEXT: sw a0, 16(sp) ; RV32I-FPELIM-NEXT: sw zero, 12(sp) ; RV32I-FPELIM-NEXT: li a0, 16 ; RV32I-FPELIM-NEXT: sw a0, 8(sp) ; RV32I-FPELIM-NEXT: li a0, 15 ; RV32I-FPELIM-NEXT: sw a0, 0(sp) ; RV32I-FPELIM-NEXT: lui a0, 262153 ; RV32I-FPELIM-NEXT: addi a0, a0, 491 ; RV32I-FPELIM-NEXT: sw a0, 44(sp) ; RV32I-FPELIM-NEXT: lui a0, 545260 ; RV32I-FPELIM-NEXT: addi a0, a0, -1967 ; RV32I-FPELIM-NEXT: sw a0, 40(sp) ; RV32I-FPELIM-NEXT: lui a0, 964690 ; RV32I-FPELIM-NEXT: addi a0, a0, -328 ; RV32I-FPELIM-NEXT: sw a0, 36(sp) ; RV32I-FPELIM-NEXT: lui a0, 335544 ; RV32I-FPELIM-NEXT: addi t0, a0, 1311 ; RV32I-FPELIM-NEXT: lui a0, 688509 ; RV32I-FPELIM-NEXT: addi a5, a0, -2048 ; RV32I-FPELIM-NEXT: li a0, 1 ; RV32I-FPELIM-NEXT: li a1, 11 ; RV32I-FPELIM-NEXT: addi a2, sp, 32 ; RV32I-FPELIM-NEXT: li a3, 12 ; RV32I-FPELIM-NEXT: li a4, 13 ; RV32I-FPELIM-NEXT: li a6, 4 ; RV32I-FPELIM-NEXT: li a7, 14 ; RV32I-FPELIM-NEXT: sw t0, 32(sp) ; RV32I-FPELIM-NEXT: call callee_aligned_stack@plt ; RV32I-FPELIM-NEXT: lw ra, 60(sp) # 4-byte Folded Reload ; RV32I-FPELIM-NEXT: addi sp, sp, 64 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: caller_aligned_stack: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -64 ; RV32I-WITHFP-NEXT: sw ra, 60(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 56(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 64 ; RV32I-WITHFP-NEXT: li a0, 19 ; RV32I-WITHFP-NEXT: sw a0, 24(sp) ; RV32I-WITHFP-NEXT: li a0, 18 ; RV32I-WITHFP-NEXT: sw a0, 20(sp) ; RV32I-WITHFP-NEXT: li a0, 17 ; RV32I-WITHFP-NEXT: sw a0, 16(sp) ; RV32I-WITHFP-NEXT: sw zero, 12(sp) ; RV32I-WITHFP-NEXT: li a0, 16 ; RV32I-WITHFP-NEXT: sw a0, 8(sp) ; RV32I-WITHFP-NEXT: li a0, 15 ; RV32I-WITHFP-NEXT: sw a0, 0(sp) ; RV32I-WITHFP-NEXT: lui a0, 262153 ; RV32I-WITHFP-NEXT: addi a0, a0, 491 ; RV32I-WITHFP-NEXT: sw a0, -20(s0) ; RV32I-WITHFP-NEXT: lui a0, 545260 ; RV32I-WITHFP-NEXT: addi a0, a0, -1967 ; RV32I-WITHFP-NEXT: sw a0, -24(s0) ; RV32I-WITHFP-NEXT: lui a0, 964690 ; RV32I-WITHFP-NEXT: addi a0, a0, -328 ; RV32I-WITHFP-NEXT: sw a0, -28(s0) ; RV32I-WITHFP-NEXT: lui a0, 335544 ; RV32I-WITHFP-NEXT: addi t0, a0, 1311 ; RV32I-WITHFP-NEXT: lui a0, 688509 ; RV32I-WITHFP-NEXT: addi a5, a0, -2048 ; RV32I-WITHFP-NEXT: li a0, 1 ; RV32I-WITHFP-NEXT: li a1, 11 ; RV32I-WITHFP-NEXT: addi a2, s0, -32 ; RV32I-WITHFP-NEXT: li a3, 12 ; RV32I-WITHFP-NEXT: li a4, 13 ; RV32I-WITHFP-NEXT: li a6, 4 ; RV32I-WITHFP-NEXT: li a7, 14 ; RV32I-WITHFP-NEXT: sw t0, -32(s0) ; RV32I-WITHFP-NEXT: call callee_aligned_stack@plt ; RV32I-WITHFP-NEXT: lw ra, 60(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 56(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 64 ; RV32I-WITHFP-NEXT: ret %1 = call i32 @callee_aligned_stack(i32 1, i32 11, fp128 0xLEB851EB851EB851F400091EB851EB851, i32 12, i32 13, i64 20000000000, i32 14, i32 15, i64 16, i32 17, [2 x i32] [i32 18, i32 19]) ret void } ; Check return of 2x xlen scalars define i64 @callee_small_scalar_ret() nounwind { ; RV32I-FPELIM-LABEL: callee_small_scalar_ret: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: lui a0, 466866 ; RV32I-FPELIM-NEXT: addi a0, a0, 1677 ; RV32I-FPELIM-NEXT: li a1, 287 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: callee_small_scalar_ret: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: lui a0, 466866 ; RV32I-WITHFP-NEXT: addi a0, a0, 1677 ; RV32I-WITHFP-NEXT: li a1, 287 ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret ret i64 1234567898765 } define i32 @caller_small_scalar_ret() nounwind { ; RV32I-FPELIM-LABEL: caller_small_scalar_ret: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: addi sp, sp, -16 ; RV32I-FPELIM-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-FPELIM-NEXT: call callee_small_scalar_ret@plt ; RV32I-FPELIM-NEXT: lui a2, 56 ; RV32I-FPELIM-NEXT: addi a2, a2, 580 ; RV32I-FPELIM-NEXT: xor a1, a1, a2 ; RV32I-FPELIM-NEXT: lui a2, 200614 ; RV32I-FPELIM-NEXT: addi a2, a2, 647 ; RV32I-FPELIM-NEXT: xor a0, a0, a2 ; RV32I-FPELIM-NEXT: or a0, a0, a1 ; RV32I-FPELIM-NEXT: seqz a0, a0 ; RV32I-FPELIM-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-FPELIM-NEXT: addi sp, sp, 16 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: caller_small_scalar_ret: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: call callee_small_scalar_ret@plt ; RV32I-WITHFP-NEXT: lui a2, 56 ; RV32I-WITHFP-NEXT: addi a2, a2, 580 ; RV32I-WITHFP-NEXT: xor a1, a1, a2 ; RV32I-WITHFP-NEXT: lui a2, 200614 ; RV32I-WITHFP-NEXT: addi a2, a2, 647 ; RV32I-WITHFP-NEXT: xor a0, a0, a2 ; RV32I-WITHFP-NEXT: or a0, a0, a1 ; RV32I-WITHFP-NEXT: seqz a0, a0 ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %1 = call i64 @callee_small_scalar_ret() %2 = icmp eq i64 987654321234567, %1 %3 = zext i1 %2 to i32 ret i32 %3 } ; Check return of 2x xlen structs define %struct.small @callee_small_struct_ret() nounwind { ; RV32I-FPELIM-LABEL: callee_small_struct_ret: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: li a0, 1 ; RV32I-FPELIM-NEXT: li a1, 0 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: callee_small_struct_ret: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: li a0, 1 ; RV32I-WITHFP-NEXT: li a1, 0 ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret ret %struct.small { i32 1, i32* null } } define i32 @caller_small_struct_ret() nounwind { ; RV32I-FPELIM-LABEL: caller_small_struct_ret: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: addi sp, sp, -16 ; RV32I-FPELIM-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-FPELIM-NEXT: call callee_small_struct_ret@plt ; RV32I-FPELIM-NEXT: add a0, a0, a1 ; RV32I-FPELIM-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-FPELIM-NEXT: addi sp, sp, 16 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: caller_small_struct_ret: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: call callee_small_struct_ret@plt ; RV32I-WITHFP-NEXT: add a0, a0, a1 ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %1 = call %struct.small @callee_small_struct_ret() %2 = extractvalue %struct.small %1, 0 %3 = extractvalue %struct.small %1, 1 %4 = ptrtoint i32* %3 to i32 %5 = add i32 %2, %4 ret i32 %5 } ; Check return of >2x xlen scalars define fp128 @callee_large_scalar_ret() nounwind { ; RV32I-FPELIM-LABEL: callee_large_scalar_ret: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: lui a1, 524272 ; RV32I-FPELIM-NEXT: sw a1, 12(a0) ; RV32I-FPELIM-NEXT: sw zero, 8(a0) ; RV32I-FPELIM-NEXT: sw zero, 4(a0) ; RV32I-FPELIM-NEXT: sw zero, 0(a0) ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: callee_large_scalar_ret: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: lui a1, 524272 ; RV32I-WITHFP-NEXT: sw a1, 12(a0) ; RV32I-WITHFP-NEXT: sw zero, 8(a0) ; RV32I-WITHFP-NEXT: sw zero, 4(a0) ; RV32I-WITHFP-NEXT: sw zero, 0(a0) ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret ret fp128 0xL00000000000000007FFF000000000000 } define void @caller_large_scalar_ret() nounwind { ; RV32I-FPELIM-LABEL: caller_large_scalar_ret: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: addi sp, sp, -32 ; RV32I-FPELIM-NEXT: sw ra, 28(sp) # 4-byte Folded Spill ; RV32I-FPELIM-NEXT: mv a0, sp ; RV32I-FPELIM-NEXT: call callee_large_scalar_ret@plt ; RV32I-FPELIM-NEXT: lw ra, 28(sp) # 4-byte Folded Reload ; RV32I-FPELIM-NEXT: addi sp, sp, 32 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: caller_large_scalar_ret: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -32 ; RV32I-WITHFP-NEXT: sw ra, 28(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 24(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 32 ; RV32I-WITHFP-NEXT: addi a0, s0, -32 ; RV32I-WITHFP-NEXT: call callee_large_scalar_ret@plt ; RV32I-WITHFP-NEXT: lw ra, 28(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 24(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 32 ; RV32I-WITHFP-NEXT: ret %1 = call fp128 @callee_large_scalar_ret() ret void } ; Check return of >2x xlen structs define void @callee_large_struct_ret(%struct.large* noalias sret(%struct.large) %agg.result) nounwind { ; RV32I-FPELIM-LABEL: callee_large_struct_ret: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: li a1, 1 ; RV32I-FPELIM-NEXT: sw a1, 0(a0) ; RV32I-FPELIM-NEXT: li a1, 2 ; RV32I-FPELIM-NEXT: sw a1, 4(a0) ; RV32I-FPELIM-NEXT: li a1, 3 ; RV32I-FPELIM-NEXT: sw a1, 8(a0) ; RV32I-FPELIM-NEXT: li a1, 4 ; RV32I-FPELIM-NEXT: sw a1, 12(a0) ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: callee_large_struct_ret: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -16 ; RV32I-WITHFP-NEXT: sw ra, 12(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 8(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 16 ; RV32I-WITHFP-NEXT: li a1, 1 ; RV32I-WITHFP-NEXT: sw a1, 0(a0) ; RV32I-WITHFP-NEXT: li a1, 2 ; RV32I-WITHFP-NEXT: sw a1, 4(a0) ; RV32I-WITHFP-NEXT: li a1, 3 ; RV32I-WITHFP-NEXT: sw a1, 8(a0) ; RV32I-WITHFP-NEXT: li a1, 4 ; RV32I-WITHFP-NEXT: sw a1, 12(a0) ; RV32I-WITHFP-NEXT: lw ra, 12(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 8(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 16 ; RV32I-WITHFP-NEXT: ret %a = getelementptr inbounds %struct.large, %struct.large* %agg.result, i32 0, i32 0 store i32 1, i32* %a, align 4 %b = getelementptr inbounds %struct.large, %struct.large* %agg.result, i32 0, i32 1 store i32 2, i32* %b, align 4 %c = getelementptr inbounds %struct.large, %struct.large* %agg.result, i32 0, i32 2 store i32 3, i32* %c, align 4 %d = getelementptr inbounds %struct.large, %struct.large* %agg.result, i32 0, i32 3 store i32 4, i32* %d, align 4 ret void } define i32 @caller_large_struct_ret() nounwind { ; RV32I-FPELIM-LABEL: caller_large_struct_ret: ; RV32I-FPELIM: # %bb.0: ; RV32I-FPELIM-NEXT: addi sp, sp, -32 ; RV32I-FPELIM-NEXT: sw ra, 28(sp) # 4-byte Folded Spill ; RV32I-FPELIM-NEXT: addi a0, sp, 8 ; RV32I-FPELIM-NEXT: call callee_large_struct_ret@plt ; RV32I-FPELIM-NEXT: lw a0, 8(sp) ; RV32I-FPELIM-NEXT: lw a1, 20(sp) ; RV32I-FPELIM-NEXT: add a0, a0, a1 ; RV32I-FPELIM-NEXT: lw ra, 28(sp) # 4-byte Folded Reload ; RV32I-FPELIM-NEXT: addi sp, sp, 32 ; RV32I-FPELIM-NEXT: ret ; ; RV32I-WITHFP-LABEL: caller_large_struct_ret: ; RV32I-WITHFP: # %bb.0: ; RV32I-WITHFP-NEXT: addi sp, sp, -32 ; RV32I-WITHFP-NEXT: sw ra, 28(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: sw s0, 24(sp) # 4-byte Folded Spill ; RV32I-WITHFP-NEXT: addi s0, sp, 32 ; RV32I-WITHFP-NEXT: addi a0, s0, -24 ; RV32I-WITHFP-NEXT: call callee_large_struct_ret@plt ; RV32I-WITHFP-NEXT: lw a0, -24(s0) ; RV32I-WITHFP-NEXT: lw a1, -12(s0) ; RV32I-WITHFP-NEXT: add a0, a0, a1 ; RV32I-WITHFP-NEXT: lw ra, 28(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: lw s0, 24(sp) # 4-byte Folded Reload ; RV32I-WITHFP-NEXT: addi sp, sp, 32 ; RV32I-WITHFP-NEXT: ret %1 = alloca %struct.large call void @callee_large_struct_ret(%struct.large* sret(%struct.large) %1) %2 = getelementptr inbounds %struct.large, %struct.large* %1, i32 0, i32 0 %3 = load i32, i32* %2 %4 = getelementptr inbounds %struct.large, %struct.large* %1, i32 0, i32 3 %5 = load i32, i32* %4 %6 = add i32 %3, %5 ret i32 %6 }