llvm-project/llvm/test/CodeGen/RISCV/half-bitmanip-dagcombines.ll

127 lines
3.7 KiB
LLVM

; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py
; RUN: llc -mtriple=riscv32 -verify-machineinstrs < %s \
; RUN: | FileCheck -check-prefix=RV32I %s
; RUN: llc -mtriple=riscv32 -mattr=+experimental-zfh -verify-machineinstrs \
; RUN: < %s | FileCheck -check-prefix=RV32IZFH %s
; RUN: llc -mtriple=riscv64 -verify-machineinstrs < %s \
; RUN: | FileCheck -check-prefix=RV64I %s
; RUN: llc -mtriple=riscv64 -mattr=+experimental-zfh -verify-machineinstrs \
; RUN: < %s | FileCheck -check-prefix=RV64IZFH %s
; This file tests cases where simple floating point operations can be
; profitably handled though bit manipulation if a soft-float ABI is being used
; (e.g. fneg implemented by XORing the sign bit). This is typically handled in
; DAGCombiner::visitBITCAST, but this target-independent code may not trigger
; in cases where we perform custom legalisation (e.g. RV64F).
define half @fneg(half %a) nounwind {
; RV32I-LABEL: fneg:
; RV32I: # %bb.0:
; RV32I-NEXT: lui a1, 1048568
; RV32I-NEXT: xor a0, a0, a1
; RV32I-NEXT: ret
;
; RV32IZFH-LABEL: fneg:
; RV32IZFH: # %bb.0:
; RV32IZFH-NEXT: lui a1, 1048568
; RV32IZFH-NEXT: xor a0, a0, a1
; RV32IZFH-NEXT: ret
;
; RV64I-LABEL: fneg:
; RV64I: # %bb.0:
; RV64I-NEXT: lui a1, 1048568
; RV64I-NEXT: xor a0, a0, a1
; RV64I-NEXT: ret
;
; RV64IZFH-LABEL: fneg:
; RV64IZFH: # %bb.0:
; RV64IZFH-NEXT: lui a1, 1048568
; RV64IZFH-NEXT: xor a0, a0, a1
; RV64IZFH-NEXT: ret
%1 = fneg half %a
ret half %1
}
declare half @llvm.fabs.f16(half)
define half @fabs(half %a) nounwind {
; RV32I-LABEL: fabs:
; RV32I: # %bb.0:
; RV32I-NEXT: lui a1, 8
; RV32I-NEXT: addi a1, a1, -1
; RV32I-NEXT: and a0, a0, a1
; RV32I-NEXT: ret
;
; RV32IZFH-LABEL: fabs:
; RV32IZFH: # %bb.0:
; RV32IZFH-NEXT: lui a1, 8
; RV32IZFH-NEXT: addi a1, a1, -1
; RV32IZFH-NEXT: and a0, a0, a1
; RV32IZFH-NEXT: ret
;
; RV64I-LABEL: fabs:
; RV64I: # %bb.0:
; RV64I-NEXT: lui a1, 8
; RV64I-NEXT: addiw a1, a1, -1
; RV64I-NEXT: and a0, a0, a1
; RV64I-NEXT: ret
;
; RV64IZFH-LABEL: fabs:
; RV64IZFH: # %bb.0:
; RV64IZFH-NEXT: lui a1, 8
; RV64IZFH-NEXT: addiw a1, a1, -1
; RV64IZFH-NEXT: and a0, a0, a1
; RV64IZFH-NEXT: ret
%1 = call half @llvm.fabs.f16(half %a)
ret half %1
}
declare half @llvm.copysign.f16(half, half)
; DAGTypeLegalizer::SoftenFloatRes_FCOPYSIGN will convert to bitwise
; operations if half precision floating point isn't supported. A combine could
; be written to do the same even when f16 is legal.
define half @fcopysign_fneg(half %a, half %b) nounwind {
; RV32I-LABEL: fcopysign_fneg:
; RV32I: # %bb.0:
; RV32I-NEXT: not a1, a1
; RV32I-NEXT: lui a2, 1048568
; RV32I-NEXT: and a1, a1, a2
; RV32I-NEXT: lui a2, 8
; RV32I-NEXT: addi a2, a2, -1
; RV32I-NEXT: and a0, a0, a2
; RV32I-NEXT: or a0, a0, a1
; RV32I-NEXT: ret
;
; RV32IZFH-LABEL: fcopysign_fneg:
; RV32IZFH: # %bb.0:
; RV32IZFH-NEXT: fmv.h.x ft0, a1
; RV32IZFH-NEXT: fmv.h.x ft1, a0
; RV32IZFH-NEXT: fsgnjn.h ft0, ft1, ft0
; RV32IZFH-NEXT: fmv.x.h a0, ft0
; RV32IZFH-NEXT: ret
;
; RV64I-LABEL: fcopysign_fneg:
; RV64I: # %bb.0:
; RV64I-NEXT: not a1, a1
; RV64I-NEXT: lui a2, 1048568
; RV64I-NEXT: and a1, a1, a2
; RV64I-NEXT: lui a2, 8
; RV64I-NEXT: addiw a2, a2, -1
; RV64I-NEXT: and a0, a0, a2
; RV64I-NEXT: or a0, a0, a1
; RV64I-NEXT: ret
;
; RV64IZFH-LABEL: fcopysign_fneg:
; RV64IZFH: # %bb.0:
; RV64IZFH-NEXT: fmv.h.x ft0, a1
; RV64IZFH-NEXT: fmv.h.x ft1, a0
; RV64IZFH-NEXT: fsgnjn.h ft0, ft1, ft0
; RV64IZFH-NEXT: fmv.x.h a0, ft0
; RV64IZFH-NEXT: ret
%1 = fneg half %b
%2 = call half @llvm.copysign.f16(half %a, half %1)
ret half %2
}