; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py ; RUN: llc -mtriple=riscv32 -mattr=+v -verify-machineinstrs < %s \ ; RUN: | FileCheck %s --check-prefixes=CHECK,RV32 ; RUN: llc -mtriple=riscv64 -mattr=+v -verify-machineinstrs < %s \ ; RUN: | FileCheck %s --check-prefixes=CHECK,RV64 declare i8 @llvm.vp.reduce.add.nxv1i8(i8, , , i32) define signext i8 @vpreduce_add_nxv1i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_add_nxv1i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf8, ta, ma ; CHECK-NEXT: vredsum.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.add.nxv1i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.umax.nxv1i8(i8, , , i32) define signext i8 @vpreduce_umax_nxv1i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_umax_nxv1i8: ; CHECK: # %bb.0: ; CHECK-NEXT: andi a0, a0, 255 ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf8, ta, ma ; CHECK-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.umax.nxv1i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.smax.nxv1i8(i8, , , i32) define signext i8 @vpreduce_smax_nxv1i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smax_nxv1i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf8, ta, ma ; CHECK-NEXT: vredmax.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.smax.nxv1i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.umin.nxv1i8(i8, , , i32) define signext i8 @vpreduce_umin_nxv1i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_umin_nxv1i8: ; CHECK: # %bb.0: ; CHECK-NEXT: andi a0, a0, 255 ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf8, ta, ma ; CHECK-NEXT: vredminu.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.umin.nxv1i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.smin.nxv1i8(i8, , , i32) define signext i8 @vpreduce_smin_nxv1i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smin_nxv1i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf8, ta, ma ; CHECK-NEXT: vredmin.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.smin.nxv1i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.and.nxv1i8(i8, , , i32) define signext i8 @vpreduce_and_nxv1i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_and_nxv1i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf8, ta, ma ; CHECK-NEXT: vredand.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.and.nxv1i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.or.nxv1i8(i8, , , i32) define signext i8 @vpreduce_or_nxv1i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_or_nxv1i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf8, ta, ma ; CHECK-NEXT: vredor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.or.nxv1i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.xor.nxv1i8(i8, , , i32) define signext i8 @vpreduce_xor_nxv1i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_xor_nxv1i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf8, ta, ma ; CHECK-NEXT: vredxor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.xor.nxv1i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.add.nxv2i8(i8, , , i32) define signext i8 @vpreduce_add_nxv2i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_add_nxv2i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf4, ta, ma ; CHECK-NEXT: vredsum.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.add.nxv2i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.umax.nxv2i8(i8, , , i32) define signext i8 @vpreduce_umax_nxv2i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_umax_nxv2i8: ; CHECK: # %bb.0: ; CHECK-NEXT: andi a0, a0, 255 ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf4, ta, ma ; CHECK-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.umax.nxv2i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.smax.nxv2i8(i8, , , i32) define signext i8 @vpreduce_smax_nxv2i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smax_nxv2i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf4, ta, ma ; CHECK-NEXT: vredmax.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.smax.nxv2i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.umin.nxv2i8(i8, , , i32) define signext i8 @vpreduce_umin_nxv2i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_umin_nxv2i8: ; CHECK: # %bb.0: ; CHECK-NEXT: andi a0, a0, 255 ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf4, ta, ma ; CHECK-NEXT: vredminu.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.umin.nxv2i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.smin.nxv2i8(i8, , , i32) define signext i8 @vpreduce_smin_nxv2i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smin_nxv2i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf4, ta, ma ; CHECK-NEXT: vredmin.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.smin.nxv2i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.and.nxv2i8(i8, , , i32) define signext i8 @vpreduce_and_nxv2i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_and_nxv2i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf4, ta, ma ; CHECK-NEXT: vredand.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.and.nxv2i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.or.nxv2i8(i8, , , i32) define signext i8 @vpreduce_or_nxv2i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_or_nxv2i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf4, ta, ma ; CHECK-NEXT: vredor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.or.nxv2i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.xor.nxv2i8(i8, , , i32) define signext i8 @vpreduce_xor_nxv2i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_xor_nxv2i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf4, ta, ma ; CHECK-NEXT: vredxor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.xor.nxv2i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.smax.nxv3i8(i8, , , i32) define signext i8 @vpreduce_smax_nxv3i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smax_nxv3i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf2, ta, ma ; CHECK-NEXT: vredmax.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.smax.nxv3i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.add.nxv4i8(i8, , , i32) define signext i8 @vpreduce_add_nxv4i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_add_nxv4i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf2, ta, ma ; CHECK-NEXT: vredsum.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.add.nxv4i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.umax.nxv4i8(i8, , , i32) define signext i8 @vpreduce_umax_nxv4i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_umax_nxv4i8: ; CHECK: # %bb.0: ; CHECK-NEXT: andi a0, a0, 255 ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf2, ta, ma ; CHECK-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.umax.nxv4i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.smax.nxv4i8(i8, , , i32) define signext i8 @vpreduce_smax_nxv4i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smax_nxv4i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf2, ta, ma ; CHECK-NEXT: vredmax.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.smax.nxv4i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.umin.nxv4i8(i8, , , i32) define signext i8 @vpreduce_umin_nxv4i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_umin_nxv4i8: ; CHECK: # %bb.0: ; CHECK-NEXT: andi a0, a0, 255 ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf2, ta, ma ; CHECK-NEXT: vredminu.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.umin.nxv4i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.smin.nxv4i8(i8, , , i32) define signext i8 @vpreduce_smin_nxv4i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smin_nxv4i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf2, ta, ma ; CHECK-NEXT: vredmin.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.smin.nxv4i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.and.nxv4i8(i8, , , i32) define signext i8 @vpreduce_and_nxv4i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_and_nxv4i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf2, ta, ma ; CHECK-NEXT: vredand.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.and.nxv4i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.or.nxv4i8(i8, , , i32) define signext i8 @vpreduce_or_nxv4i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_or_nxv4i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf2, ta, ma ; CHECK-NEXT: vredor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.or.nxv4i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i8 @llvm.vp.reduce.xor.nxv4i8(i8, , , i32) define signext i8 @vpreduce_xor_nxv4i8(i8 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_xor_nxv4i8: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e8, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e8, mf2, ta, ma ; CHECK-NEXT: vredxor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i8 @llvm.vp.reduce.xor.nxv4i8(i8 %s, %v, %m, i32 %evl) ret i8 %r } declare i16 @llvm.vp.reduce.add.nxv1i16(i16, , , i32) define signext i16 @vpreduce_add_nxv1i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_add_nxv1i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, mf4, ta, ma ; CHECK-NEXT: vredsum.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.add.nxv1i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.umax.nxv1i16(i16, , , i32) define signext i16 @vpreduce_umax_nxv1i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umax_nxv1i16: ; RV32: # %bb.0: ; RV32-NEXT: slli a0, a0, 16 ; RV32-NEXT: srli a0, a0, 16 ; RV32-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; RV32-NEXT: vmv.s.x v9, a0 ; RV32-NEXT: vsetvli zero, a1, e16, mf4, ta, ma ; RV32-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umax_nxv1i16: ; RV64: # %bb.0: ; RV64-NEXT: slli a0, a0, 48 ; RV64-NEXT: srli a0, a0, 48 ; RV64-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e16, mf4, ta, ma ; RV64-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i16 @llvm.vp.reduce.umax.nxv1i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.smax.nxv1i16(i16, , , i32) define signext i16 @vpreduce_smax_nxv1i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smax_nxv1i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, mf4, ta, ma ; CHECK-NEXT: vredmax.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.smax.nxv1i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.umin.nxv1i16(i16, , , i32) define signext i16 @vpreduce_umin_nxv1i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umin_nxv1i16: ; RV32: # %bb.0: ; RV32-NEXT: slli a0, a0, 16 ; RV32-NEXT: srli a0, a0, 16 ; RV32-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; RV32-NEXT: vmv.s.x v9, a0 ; RV32-NEXT: vsetvli zero, a1, e16, mf4, ta, ma ; RV32-NEXT: vredminu.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umin_nxv1i16: ; RV64: # %bb.0: ; RV64-NEXT: slli a0, a0, 48 ; RV64-NEXT: srli a0, a0, 48 ; RV64-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e16, mf4, ta, ma ; RV64-NEXT: vredminu.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i16 @llvm.vp.reduce.umin.nxv1i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.smin.nxv1i16(i16, , , i32) define signext i16 @vpreduce_smin_nxv1i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smin_nxv1i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, mf4, ta, ma ; CHECK-NEXT: vredmin.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.smin.nxv1i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.and.nxv1i16(i16, , , i32) define signext i16 @vpreduce_and_nxv1i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_and_nxv1i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, mf4, ta, ma ; CHECK-NEXT: vredand.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.and.nxv1i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.or.nxv1i16(i16, , , i32) define signext i16 @vpreduce_or_nxv1i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_or_nxv1i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, mf4, ta, ma ; CHECK-NEXT: vredor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.or.nxv1i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.xor.nxv1i16(i16, , , i32) define signext i16 @vpreduce_xor_nxv1i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_xor_nxv1i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, mf4, ta, ma ; CHECK-NEXT: vredxor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.xor.nxv1i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.add.nxv2i16(i16, , , i32) define signext i16 @vpreduce_add_nxv2i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_add_nxv2i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, mf2, ta, ma ; CHECK-NEXT: vredsum.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.add.nxv2i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.umax.nxv2i16(i16, , , i32) define signext i16 @vpreduce_umax_nxv2i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umax_nxv2i16: ; RV32: # %bb.0: ; RV32-NEXT: slli a0, a0, 16 ; RV32-NEXT: srli a0, a0, 16 ; RV32-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; RV32-NEXT: vmv.s.x v9, a0 ; RV32-NEXT: vsetvli zero, a1, e16, mf2, ta, ma ; RV32-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umax_nxv2i16: ; RV64: # %bb.0: ; RV64-NEXT: slli a0, a0, 48 ; RV64-NEXT: srli a0, a0, 48 ; RV64-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e16, mf2, ta, ma ; RV64-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i16 @llvm.vp.reduce.umax.nxv2i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.smax.nxv2i16(i16, , , i32) define signext i16 @vpreduce_smax_nxv2i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smax_nxv2i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, mf2, ta, ma ; CHECK-NEXT: vredmax.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.smax.nxv2i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.umin.nxv2i16(i16, , , i32) define signext i16 @vpreduce_umin_nxv2i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umin_nxv2i16: ; RV32: # %bb.0: ; RV32-NEXT: slli a0, a0, 16 ; RV32-NEXT: srli a0, a0, 16 ; RV32-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; RV32-NEXT: vmv.s.x v9, a0 ; RV32-NEXT: vsetvli zero, a1, e16, mf2, ta, ma ; RV32-NEXT: vredminu.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umin_nxv2i16: ; RV64: # %bb.0: ; RV64-NEXT: slli a0, a0, 48 ; RV64-NEXT: srli a0, a0, 48 ; RV64-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e16, mf2, ta, ma ; RV64-NEXT: vredminu.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i16 @llvm.vp.reduce.umin.nxv2i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.smin.nxv2i16(i16, , , i32) define signext i16 @vpreduce_smin_nxv2i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smin_nxv2i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, mf2, ta, ma ; CHECK-NEXT: vredmin.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.smin.nxv2i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.and.nxv2i16(i16, , , i32) define signext i16 @vpreduce_and_nxv2i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_and_nxv2i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, mf2, ta, ma ; CHECK-NEXT: vredand.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.and.nxv2i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.or.nxv2i16(i16, , , i32) define signext i16 @vpreduce_or_nxv2i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_or_nxv2i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, mf2, ta, ma ; CHECK-NEXT: vredor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.or.nxv2i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.xor.nxv2i16(i16, , , i32) define signext i16 @vpreduce_xor_nxv2i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_xor_nxv2i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, mf2, ta, ma ; CHECK-NEXT: vredxor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.xor.nxv2i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.add.nxv4i16(i16, , , i32) define signext i16 @vpreduce_add_nxv4i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_add_nxv4i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, m1, ta, ma ; CHECK-NEXT: vredsum.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.add.nxv4i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.umax.nxv4i16(i16, , , i32) define signext i16 @vpreduce_umax_nxv4i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umax_nxv4i16: ; RV32: # %bb.0: ; RV32-NEXT: slli a0, a0, 16 ; RV32-NEXT: srli a0, a0, 16 ; RV32-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; RV32-NEXT: vmv.s.x v9, a0 ; RV32-NEXT: vsetvli zero, a1, e16, m1, ta, ma ; RV32-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umax_nxv4i16: ; RV64: # %bb.0: ; RV64-NEXT: slli a0, a0, 48 ; RV64-NEXT: srli a0, a0, 48 ; RV64-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e16, m1, ta, ma ; RV64-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i16 @llvm.vp.reduce.umax.nxv4i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.smax.nxv4i16(i16, , , i32) define signext i16 @vpreduce_smax_nxv4i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smax_nxv4i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, m1, ta, ma ; CHECK-NEXT: vredmax.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.smax.nxv4i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.umin.nxv4i16(i16, , , i32) define signext i16 @vpreduce_umin_nxv4i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umin_nxv4i16: ; RV32: # %bb.0: ; RV32-NEXT: slli a0, a0, 16 ; RV32-NEXT: srli a0, a0, 16 ; RV32-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; RV32-NEXT: vmv.s.x v9, a0 ; RV32-NEXT: vsetvli zero, a1, e16, m1, ta, ma ; RV32-NEXT: vredminu.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umin_nxv4i16: ; RV64: # %bb.0: ; RV64-NEXT: slli a0, a0, 48 ; RV64-NEXT: srli a0, a0, 48 ; RV64-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e16, m1, ta, ma ; RV64-NEXT: vredminu.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i16 @llvm.vp.reduce.umin.nxv4i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.smin.nxv4i16(i16, , , i32) define signext i16 @vpreduce_smin_nxv4i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smin_nxv4i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, m1, ta, ma ; CHECK-NEXT: vredmin.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.smin.nxv4i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.and.nxv4i16(i16, , , i32) define signext i16 @vpreduce_and_nxv4i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_and_nxv4i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, m1, ta, ma ; CHECK-NEXT: vredand.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.and.nxv4i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.or.nxv4i16(i16, , , i32) define signext i16 @vpreduce_or_nxv4i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_or_nxv4i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, m1, ta, ma ; CHECK-NEXT: vredor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.or.nxv4i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i16 @llvm.vp.reduce.xor.nxv4i16(i16, , , i32) define signext i16 @vpreduce_xor_nxv4i16(i16 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_xor_nxv4i16: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e16, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e16, m1, ta, ma ; CHECK-NEXT: vredxor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i16 @llvm.vp.reduce.xor.nxv4i16(i16 %s, %v, %m, i32 %evl) ret i16 %r } declare i32 @llvm.vp.reduce.add.nxv1i32(i32, , , i32) define signext i32 @vpreduce_add_nxv1i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_add_nxv1i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, mf2, ta, ma ; CHECK-NEXT: vredsum.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.add.nxv1i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.umax.nxv1i32(i32, , , i32) define signext i32 @vpreduce_umax_nxv1i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umax_nxv1i32: ; RV32: # %bb.0: ; RV32-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; RV32-NEXT: vmv.s.x v9, a0 ; RV32-NEXT: vsetvli zero, a1, e32, mf2, ta, ma ; RV32-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umax_nxv1i32: ; RV64: # %bb.0: ; RV64-NEXT: andi a0, a0, -1 ; RV64-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e32, mf2, ta, ma ; RV64-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i32 @llvm.vp.reduce.umax.nxv1i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.smax.nxv1i32(i32, , , i32) define signext i32 @vpreduce_smax_nxv1i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smax_nxv1i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, mf2, ta, ma ; CHECK-NEXT: vredmax.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.smax.nxv1i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.umin.nxv1i32(i32, , , i32) define signext i32 @vpreduce_umin_nxv1i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umin_nxv1i32: ; RV32: # %bb.0: ; RV32-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; RV32-NEXT: vmv.s.x v9, a0 ; RV32-NEXT: vsetvli zero, a1, e32, mf2, ta, ma ; RV32-NEXT: vredminu.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umin_nxv1i32: ; RV64: # %bb.0: ; RV64-NEXT: andi a0, a0, -1 ; RV64-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e32, mf2, ta, ma ; RV64-NEXT: vredminu.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i32 @llvm.vp.reduce.umin.nxv1i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.smin.nxv1i32(i32, , , i32) define signext i32 @vpreduce_smin_nxv1i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smin_nxv1i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, mf2, ta, ma ; CHECK-NEXT: vredmin.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.smin.nxv1i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.and.nxv1i32(i32, , , i32) define signext i32 @vpreduce_and_nxv1i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_and_nxv1i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, mf2, ta, ma ; CHECK-NEXT: vredand.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.and.nxv1i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.or.nxv1i32(i32, , , i32) define signext i32 @vpreduce_or_nxv1i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_or_nxv1i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, mf2, ta, ma ; CHECK-NEXT: vredor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.or.nxv1i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.xor.nxv1i32(i32, , , i32) define signext i32 @vpreduce_xor_nxv1i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_xor_nxv1i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, mf2, ta, ma ; CHECK-NEXT: vredxor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.xor.nxv1i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.add.nxv2i32(i32, , , i32) define signext i32 @vpreduce_add_nxv2i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_add_nxv2i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, m1, ta, ma ; CHECK-NEXT: vredsum.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.add.nxv2i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.umax.nxv2i32(i32, , , i32) define signext i32 @vpreduce_umax_nxv2i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umax_nxv2i32: ; RV32: # %bb.0: ; RV32-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; RV32-NEXT: vmv.s.x v9, a0 ; RV32-NEXT: vsetvli zero, a1, e32, m1, ta, ma ; RV32-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umax_nxv2i32: ; RV64: # %bb.0: ; RV64-NEXT: andi a0, a0, -1 ; RV64-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e32, m1, ta, ma ; RV64-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i32 @llvm.vp.reduce.umax.nxv2i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.smax.nxv2i32(i32, , , i32) define signext i32 @vpreduce_smax_nxv2i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smax_nxv2i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, m1, ta, ma ; CHECK-NEXT: vredmax.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.smax.nxv2i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.umin.nxv2i32(i32, , , i32) define signext i32 @vpreduce_umin_nxv2i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umin_nxv2i32: ; RV32: # %bb.0: ; RV32-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; RV32-NEXT: vmv.s.x v9, a0 ; RV32-NEXT: vsetvli zero, a1, e32, m1, ta, ma ; RV32-NEXT: vredminu.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umin_nxv2i32: ; RV64: # %bb.0: ; RV64-NEXT: andi a0, a0, -1 ; RV64-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e32, m1, ta, ma ; RV64-NEXT: vredminu.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i32 @llvm.vp.reduce.umin.nxv2i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.smin.nxv2i32(i32, , , i32) define signext i32 @vpreduce_smin_nxv2i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smin_nxv2i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, m1, ta, ma ; CHECK-NEXT: vredmin.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.smin.nxv2i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.and.nxv2i32(i32, , , i32) define signext i32 @vpreduce_and_nxv2i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_and_nxv2i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, m1, ta, ma ; CHECK-NEXT: vredand.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.and.nxv2i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.or.nxv2i32(i32, , , i32) define signext i32 @vpreduce_or_nxv2i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_or_nxv2i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, m1, ta, ma ; CHECK-NEXT: vredor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.or.nxv2i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.xor.nxv2i32(i32, , , i32) define signext i32 @vpreduce_xor_nxv2i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_xor_nxv2i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v9, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, m1, ta, ma ; CHECK-NEXT: vredxor.vs v9, v8, v9, v0.t ; CHECK-NEXT: vmv.x.s a0, v9 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.xor.nxv2i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.add.nxv4i32(i32, , , i32) define signext i32 @vpreduce_add_nxv4i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_add_nxv4i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v10, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, m2, ta, ma ; CHECK-NEXT: vredsum.vs v10, v8, v10, v0.t ; CHECK-NEXT: vmv.x.s a0, v10 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.add.nxv4i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.umax.nxv4i32(i32, , , i32) define signext i32 @vpreduce_umax_nxv4i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umax_nxv4i32: ; RV32: # %bb.0: ; RV32-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; RV32-NEXT: vmv.s.x v10, a0 ; RV32-NEXT: vsetvli zero, a1, e32, m2, ta, ma ; RV32-NEXT: vredmaxu.vs v10, v8, v10, v0.t ; RV32-NEXT: vmv.x.s a0, v10 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umax_nxv4i32: ; RV64: # %bb.0: ; RV64-NEXT: andi a0, a0, -1 ; RV64-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; RV64-NEXT: vmv.s.x v10, a0 ; RV64-NEXT: vsetvli zero, a1, e32, m2, ta, ma ; RV64-NEXT: vredmaxu.vs v10, v8, v10, v0.t ; RV64-NEXT: vmv.x.s a0, v10 ; RV64-NEXT: ret %r = call i32 @llvm.vp.reduce.umax.nxv4i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.umax.nxv32i32(i32, , , i32) define signext i32 @vpreduce_umax_nxv32i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umax_nxv32i32: ; RV32: # %bb.0: ; RV32-NEXT: csrr a3, vlenb ; RV32-NEXT: srli a2, a3, 2 ; RV32-NEXT: vsetvli a4, zero, e8, mf2, ta, ma ; RV32-NEXT: vslidedown.vx v24, v0, a2 ; RV32-NEXT: slli a3, a3, 1 ; RV32-NEXT: sub a2, a1, a3 ; RV32-NEXT: sltu a4, a1, a2 ; RV32-NEXT: addi a4, a4, -1 ; RV32-NEXT: and a2, a4, a2 ; RV32-NEXT: bltu a1, a3, .LBB67_2 ; RV32-NEXT: # %bb.1: ; RV32-NEXT: mv a1, a3 ; RV32-NEXT: .LBB67_2: ; RV32-NEXT: vsetvli zero, zero, e32, m2, ta, ma ; RV32-NEXT: vmv.s.x v25, a0 ; RV32-NEXT: vsetvli zero, a1, e32, m8, ta, ma ; RV32-NEXT: vredmaxu.vs v25, v8, v25, v0.t ; RV32-NEXT: vsetvli zero, a2, e32, m8, ta, ma ; RV32-NEXT: vmv1r.v v0, v24 ; RV32-NEXT: vredmaxu.vs v25, v16, v25, v0.t ; RV32-NEXT: vmv.x.s a0, v25 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umax_nxv32i32: ; RV64: # %bb.0: ; RV64-NEXT: csrr a3, vlenb ; RV64-NEXT: srli a2, a3, 2 ; RV64-NEXT: vsetvli a4, zero, e8, mf2, ta, ma ; RV64-NEXT: vslidedown.vx v24, v0, a2 ; RV64-NEXT: andi a2, a0, -1 ; RV64-NEXT: slli a3, a3, 1 ; RV64-NEXT: sub a0, a1, a3 ; RV64-NEXT: sltu a4, a1, a0 ; RV64-NEXT: addi a4, a4, -1 ; RV64-NEXT: and a0, a4, a0 ; RV64-NEXT: bltu a1, a3, .LBB67_2 ; RV64-NEXT: # %bb.1: ; RV64-NEXT: mv a1, a3 ; RV64-NEXT: .LBB67_2: ; RV64-NEXT: vsetvli zero, zero, e32, m2, ta, ma ; RV64-NEXT: vmv.s.x v25, a2 ; RV64-NEXT: vsetvli zero, a1, e32, m8, ta, ma ; RV64-NEXT: vredmaxu.vs v25, v8, v25, v0.t ; RV64-NEXT: vsetvli zero, a0, e32, m8, ta, ma ; RV64-NEXT: vmv1r.v v0, v24 ; RV64-NEXT: vredmaxu.vs v25, v16, v25, v0.t ; RV64-NEXT: vmv.x.s a0, v25 ; RV64-NEXT: ret %r = call i32 @llvm.vp.reduce.umax.nxv32i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.smax.nxv4i32(i32, , , i32) define signext i32 @vpreduce_smax_nxv4i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smax_nxv4i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v10, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, m2, ta, ma ; CHECK-NEXT: vredmax.vs v10, v8, v10, v0.t ; CHECK-NEXT: vmv.x.s a0, v10 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.smax.nxv4i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.umin.nxv4i32(i32, , , i32) define signext i32 @vpreduce_umin_nxv4i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umin_nxv4i32: ; RV32: # %bb.0: ; RV32-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; RV32-NEXT: vmv.s.x v10, a0 ; RV32-NEXT: vsetvli zero, a1, e32, m2, ta, ma ; RV32-NEXT: vredminu.vs v10, v8, v10, v0.t ; RV32-NEXT: vmv.x.s a0, v10 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umin_nxv4i32: ; RV64: # %bb.0: ; RV64-NEXT: andi a0, a0, -1 ; RV64-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; RV64-NEXT: vmv.s.x v10, a0 ; RV64-NEXT: vsetvli zero, a1, e32, m2, ta, ma ; RV64-NEXT: vredminu.vs v10, v8, v10, v0.t ; RV64-NEXT: vmv.x.s a0, v10 ; RV64-NEXT: ret %r = call i32 @llvm.vp.reduce.umin.nxv4i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.smin.nxv4i32(i32, , , i32) define signext i32 @vpreduce_smin_nxv4i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_smin_nxv4i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v10, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, m2, ta, ma ; CHECK-NEXT: vredmin.vs v10, v8, v10, v0.t ; CHECK-NEXT: vmv.x.s a0, v10 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.smin.nxv4i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.and.nxv4i32(i32, , , i32) define signext i32 @vpreduce_and_nxv4i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_and_nxv4i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v10, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, m2, ta, ma ; CHECK-NEXT: vredand.vs v10, v8, v10, v0.t ; CHECK-NEXT: vmv.x.s a0, v10 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.and.nxv4i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.or.nxv4i32(i32, , , i32) define signext i32 @vpreduce_or_nxv4i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_or_nxv4i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v10, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, m2, ta, ma ; CHECK-NEXT: vredor.vs v10, v8, v10, v0.t ; CHECK-NEXT: vmv.x.s a0, v10 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.or.nxv4i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i32 @llvm.vp.reduce.xor.nxv4i32(i32, , , i32) define signext i32 @vpreduce_xor_nxv4i32(i32 signext %s, %v, %m, i32 zeroext %evl) { ; CHECK-LABEL: vpreduce_xor_nxv4i32: ; CHECK: # %bb.0: ; CHECK-NEXT: vsetivli zero, 1, e32, m1, ta, ma ; CHECK-NEXT: vmv.s.x v10, a0 ; CHECK-NEXT: vsetvli zero, a1, e32, m2, ta, ma ; CHECK-NEXT: vredxor.vs v10, v8, v10, v0.t ; CHECK-NEXT: vmv.x.s a0, v10 ; CHECK-NEXT: ret %r = call i32 @llvm.vp.reduce.xor.nxv4i32(i32 %s, %v, %m, i32 %evl) ret i32 %r } declare i64 @llvm.vp.reduce.add.nxv1i64(i64, , , i32) define signext i64 @vpreduce_add_nxv1i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_add_nxv1i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v9, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m1, ta, ma ; RV32-NEXT: vredsum.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v9, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_add_nxv1i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m1, ta, ma ; RV64-NEXT: vredsum.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.add.nxv1i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } define signext i64 @vpwreduce_add_nxv1i32(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpwreduce_add_nxv1i32: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v9, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e32, mf2, ta, ma ; RV32-NEXT: vwredsum.vs v9, v8, v9, v0.t ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsrl.vx v8, v9, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpwreduce_add_nxv1i32: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e32, mf2, ta, ma ; RV64-NEXT: vwredsum.vs v9, v8, v9, v0.t ; RV64-NEXT: vsetvli zero, zero, e64, m1, ta, ma ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %e = sext %v to %r = call i64 @llvm.vp.reduce.add.nxv1i64(i64 %s, %e, %m, i32 %evl) ret i64 %r } define signext i64 @vpwreduce_uadd_nxv1i32(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpwreduce_uadd_nxv1i32: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v9, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e32, mf2, ta, ma ; RV32-NEXT: vwredsum.vs v9, v8, v9, v0.t ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsrl.vx v8, v9, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpwreduce_uadd_nxv1i32: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e32, mf2, ta, ma ; RV64-NEXT: vwredsum.vs v9, v8, v9, v0.t ; RV64-NEXT: vsetvli zero, zero, e64, m1, ta, ma ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %e = sext %v to %r = call i64 @llvm.vp.reduce.add.nxv1i64(i64 %s, %e, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.umax.nxv1i64(i64, , , i32) define signext i64 @vpreduce_umax_nxv1i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umax_nxv1i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v9, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m1, ta, ma ; RV32-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v9, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umax_nxv1i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m1, ta, ma ; RV64-NEXT: vredmaxu.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.umax.nxv1i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.smax.nxv1i64(i64, , , i32) define signext i64 @vpreduce_smax_nxv1i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_smax_nxv1i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v9, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m1, ta, ma ; RV32-NEXT: vredmax.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v9, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_smax_nxv1i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m1, ta, ma ; RV64-NEXT: vredmax.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.smax.nxv1i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.umin.nxv1i64(i64, , , i32) define signext i64 @vpreduce_umin_nxv1i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umin_nxv1i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v9, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m1, ta, ma ; RV32-NEXT: vredminu.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v9, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umin_nxv1i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m1, ta, ma ; RV64-NEXT: vredminu.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.umin.nxv1i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.smin.nxv1i64(i64, , , i32) define signext i64 @vpreduce_smin_nxv1i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_smin_nxv1i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v9, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m1, ta, ma ; RV32-NEXT: vredmin.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v9, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_smin_nxv1i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m1, ta, ma ; RV64-NEXT: vredmin.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.smin.nxv1i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.and.nxv1i64(i64, , , i32) define signext i64 @vpreduce_and_nxv1i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_and_nxv1i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v9, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m1, ta, ma ; RV32-NEXT: vredand.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v9, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_and_nxv1i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m1, ta, ma ; RV64-NEXT: vredand.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.and.nxv1i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.or.nxv1i64(i64, , , i32) define signext i64 @vpreduce_or_nxv1i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_or_nxv1i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v9, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m1, ta, ma ; RV32-NEXT: vredor.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v9, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_or_nxv1i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m1, ta, ma ; RV64-NEXT: vredor.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.or.nxv1i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.xor.nxv1i64(i64, , , i32) define signext i64 @vpreduce_xor_nxv1i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_xor_nxv1i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v9, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m1, ta, ma ; RV32-NEXT: vredxor.vs v9, v8, v9, v0.t ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v9, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_xor_nxv1i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m1, ta, ma ; RV64-NEXT: vredxor.vs v9, v8, v9, v0.t ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.xor.nxv1i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.add.nxv2i64(i64, , , i32) define signext i64 @vpreduce_add_nxv2i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_add_nxv2i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v10, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m2, ta, ma ; RV32-NEXT: vredsum.vs v10, v8, v10, v0.t ; RV32-NEXT: vmv.x.s a0, v10 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v10, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_add_nxv2i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v10, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m2, ta, ma ; RV64-NEXT: vredsum.vs v10, v8, v10, v0.t ; RV64-NEXT: vmv.x.s a0, v10 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.add.nxv2i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } define signext i64 @vwpreduce_add_nxv2i32(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vwpreduce_add_nxv2i32: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v9, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e32, m1, ta, ma ; RV32-NEXT: vwredsum.vs v9, v8, v9, v0.t ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsrl.vx v8, v9, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vwpreduce_add_nxv2i32: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e32, m1, ta, ma ; RV64-NEXT: vwredsum.vs v9, v8, v9, v0.t ; RV64-NEXT: vsetvli zero, zero, e64, m2, ta, ma ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %e = sext %v to %r = call i64 @llvm.vp.reduce.add.nxv2i64(i64 %s, %e, %m, i32 %evl) ret i64 %r } define signext i64 @vwpreduce_uadd_nxv2i32(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vwpreduce_uadd_nxv2i32: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v9, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e32, m1, ta, ma ; RV32-NEXT: vwredsum.vs v9, v8, v9, v0.t ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vmv.x.s a0, v9 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsrl.vx v8, v9, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vwpreduce_uadd_nxv2i32: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v9, a0 ; RV64-NEXT: vsetvli zero, a1, e32, m1, ta, ma ; RV64-NEXT: vwredsum.vs v9, v8, v9, v0.t ; RV64-NEXT: vsetvli zero, zero, e64, m2, ta, ma ; RV64-NEXT: vmv.x.s a0, v9 ; RV64-NEXT: ret %e = sext %v to %r = call i64 @llvm.vp.reduce.add.nxv2i64(i64 %s, %e, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.umax.nxv2i64(i64, , , i32) define signext i64 @vpreduce_umax_nxv2i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umax_nxv2i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v10, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m2, ta, ma ; RV32-NEXT: vredmaxu.vs v10, v8, v10, v0.t ; RV32-NEXT: vmv.x.s a0, v10 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v10, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umax_nxv2i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v10, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m2, ta, ma ; RV64-NEXT: vredmaxu.vs v10, v8, v10, v0.t ; RV64-NEXT: vmv.x.s a0, v10 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.umax.nxv2i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.smax.nxv2i64(i64, , , i32) define signext i64 @vpreduce_smax_nxv2i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_smax_nxv2i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v10, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m2, ta, ma ; RV32-NEXT: vredmax.vs v10, v8, v10, v0.t ; RV32-NEXT: vmv.x.s a0, v10 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v10, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_smax_nxv2i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v10, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m2, ta, ma ; RV64-NEXT: vredmax.vs v10, v8, v10, v0.t ; RV64-NEXT: vmv.x.s a0, v10 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.smax.nxv2i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.umin.nxv2i64(i64, , , i32) define signext i64 @vpreduce_umin_nxv2i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umin_nxv2i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v10, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m2, ta, ma ; RV32-NEXT: vredminu.vs v10, v8, v10, v0.t ; RV32-NEXT: vmv.x.s a0, v10 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v10, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umin_nxv2i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v10, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m2, ta, ma ; RV64-NEXT: vredminu.vs v10, v8, v10, v0.t ; RV64-NEXT: vmv.x.s a0, v10 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.umin.nxv2i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.smin.nxv2i64(i64, , , i32) define signext i64 @vpreduce_smin_nxv2i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_smin_nxv2i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v10, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m2, ta, ma ; RV32-NEXT: vredmin.vs v10, v8, v10, v0.t ; RV32-NEXT: vmv.x.s a0, v10 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v10, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_smin_nxv2i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v10, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m2, ta, ma ; RV64-NEXT: vredmin.vs v10, v8, v10, v0.t ; RV64-NEXT: vmv.x.s a0, v10 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.smin.nxv2i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.and.nxv2i64(i64, , , i32) define signext i64 @vpreduce_and_nxv2i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_and_nxv2i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v10, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m2, ta, ma ; RV32-NEXT: vredand.vs v10, v8, v10, v0.t ; RV32-NEXT: vmv.x.s a0, v10 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v10, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_and_nxv2i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v10, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m2, ta, ma ; RV64-NEXT: vredand.vs v10, v8, v10, v0.t ; RV64-NEXT: vmv.x.s a0, v10 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.and.nxv2i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.or.nxv2i64(i64, , , i32) define signext i64 @vpreduce_or_nxv2i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_or_nxv2i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v10, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m2, ta, ma ; RV32-NEXT: vredor.vs v10, v8, v10, v0.t ; RV32-NEXT: vmv.x.s a0, v10 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v10, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_or_nxv2i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v10, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m2, ta, ma ; RV64-NEXT: vredor.vs v10, v8, v10, v0.t ; RV64-NEXT: vmv.x.s a0, v10 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.or.nxv2i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.xor.nxv2i64(i64, , , i32) define signext i64 @vpreduce_xor_nxv2i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_xor_nxv2i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v10, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m2, ta, ma ; RV32-NEXT: vredxor.vs v10, v8, v10, v0.t ; RV32-NEXT: vmv.x.s a0, v10 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v10, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_xor_nxv2i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v10, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m2, ta, ma ; RV64-NEXT: vredxor.vs v10, v8, v10, v0.t ; RV64-NEXT: vmv.x.s a0, v10 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.xor.nxv2i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.add.nxv4i64(i64, , , i32) define signext i64 @vpreduce_add_nxv4i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_add_nxv4i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v12, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m4, ta, ma ; RV32-NEXT: vredsum.vs v12, v8, v12, v0.t ; RV32-NEXT: vmv.x.s a0, v12 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v12, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_add_nxv4i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v12, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m4, ta, ma ; RV64-NEXT: vredsum.vs v12, v8, v12, v0.t ; RV64-NEXT: vmv.x.s a0, v12 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.add.nxv4i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } define signext i64 @vpwreduce_add_nxv4i32(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpwreduce_add_nxv4i32: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v10, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e32, m2, ta, ma ; RV32-NEXT: vwredsum.vs v10, v8, v10, v0.t ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vmv.x.s a0, v10 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsrl.vx v8, v10, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpwreduce_add_nxv4i32: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v10, a0 ; RV64-NEXT: vsetvli zero, a1, e32, m2, ta, ma ; RV64-NEXT: vwredsum.vs v10, v8, v10, v0.t ; RV64-NEXT: vsetvli zero, zero, e64, m4, ta, ma ; RV64-NEXT: vmv.x.s a0, v10 ; RV64-NEXT: ret %e = sext %v to %r = call i64 @llvm.vp.reduce.add.nxv4i64(i64 %s, %e, %m, i32 %evl) ret i64 %r } define signext i64 @vpwreduce_uadd_nxv4i32(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpwreduce_uadd_nxv4i32: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v10, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e32, m2, ta, ma ; RV32-NEXT: vwredsumu.vs v10, v8, v10, v0.t ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vmv.x.s a0, v10 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsrl.vx v8, v10, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpwreduce_uadd_nxv4i32: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v10, a0 ; RV64-NEXT: vsetvli zero, a1, e32, m2, ta, ma ; RV64-NEXT: vwredsumu.vs v10, v8, v10, v0.t ; RV64-NEXT: vsetvli zero, zero, e64, m4, ta, ma ; RV64-NEXT: vmv.x.s a0, v10 ; RV64-NEXT: ret %e = zext %v to %r = call i64 @llvm.vp.reduce.add.nxv4i64(i64 %s, %e, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.umax.nxv4i64(i64, , , i32) define signext i64 @vpreduce_umax_nxv4i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umax_nxv4i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v12, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m4, ta, ma ; RV32-NEXT: vredmaxu.vs v12, v8, v12, v0.t ; RV32-NEXT: vmv.x.s a0, v12 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v12, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umax_nxv4i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v12, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m4, ta, ma ; RV64-NEXT: vredmaxu.vs v12, v8, v12, v0.t ; RV64-NEXT: vmv.x.s a0, v12 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.umax.nxv4i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.smax.nxv4i64(i64, , , i32) define signext i64 @vpreduce_smax_nxv4i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_smax_nxv4i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v12, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m4, ta, ma ; RV32-NEXT: vredmax.vs v12, v8, v12, v0.t ; RV32-NEXT: vmv.x.s a0, v12 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v12, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_smax_nxv4i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v12, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m4, ta, ma ; RV64-NEXT: vredmax.vs v12, v8, v12, v0.t ; RV64-NEXT: vmv.x.s a0, v12 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.smax.nxv4i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.umin.nxv4i64(i64, , , i32) define signext i64 @vpreduce_umin_nxv4i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_umin_nxv4i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v12, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m4, ta, ma ; RV32-NEXT: vredminu.vs v12, v8, v12, v0.t ; RV32-NEXT: vmv.x.s a0, v12 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v12, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_umin_nxv4i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v12, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m4, ta, ma ; RV64-NEXT: vredminu.vs v12, v8, v12, v0.t ; RV64-NEXT: vmv.x.s a0, v12 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.umin.nxv4i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.smin.nxv4i64(i64, , , i32) define signext i64 @vpreduce_smin_nxv4i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_smin_nxv4i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v12, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m4, ta, ma ; RV32-NEXT: vredmin.vs v12, v8, v12, v0.t ; RV32-NEXT: vmv.x.s a0, v12 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v12, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_smin_nxv4i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v12, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m4, ta, ma ; RV64-NEXT: vredmin.vs v12, v8, v12, v0.t ; RV64-NEXT: vmv.x.s a0, v12 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.smin.nxv4i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.and.nxv4i64(i64, , , i32) define signext i64 @vpreduce_and_nxv4i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_and_nxv4i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v12, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m4, ta, ma ; RV32-NEXT: vredand.vs v12, v8, v12, v0.t ; RV32-NEXT: vmv.x.s a0, v12 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v12, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_and_nxv4i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v12, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m4, ta, ma ; RV64-NEXT: vredand.vs v12, v8, v12, v0.t ; RV64-NEXT: vmv.x.s a0, v12 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.and.nxv4i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.or.nxv4i64(i64, , , i32) define signext i64 @vpreduce_or_nxv4i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_or_nxv4i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v12, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m4, ta, ma ; RV32-NEXT: vredor.vs v12, v8, v12, v0.t ; RV32-NEXT: vmv.x.s a0, v12 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v12, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_or_nxv4i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v12, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m4, ta, ma ; RV64-NEXT: vredor.vs v12, v8, v12, v0.t ; RV64-NEXT: vmv.x.s a0, v12 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.or.nxv4i64(i64 %s, %v, %m, i32 %evl) ret i64 %r } declare i64 @llvm.vp.reduce.xor.nxv4i64(i64, , , i32) define signext i64 @vpreduce_xor_nxv4i64(i64 signext %s, %v, %m, i32 zeroext %evl) { ; RV32-LABEL: vpreduce_xor_nxv4i64: ; RV32: # %bb.0: ; RV32-NEXT: addi sp, sp, -16 ; RV32-NEXT: .cfi_def_cfa_offset 16 ; RV32-NEXT: sw a1, 12(sp) ; RV32-NEXT: sw a0, 8(sp) ; RV32-NEXT: addi a0, sp, 8 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vlse64.v v12, (a0), zero ; RV32-NEXT: vsetvli zero, a2, e64, m4, ta, ma ; RV32-NEXT: vredxor.vs v12, v8, v12, v0.t ; RV32-NEXT: vmv.x.s a0, v12 ; RV32-NEXT: li a1, 32 ; RV32-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV32-NEXT: vsrl.vx v8, v12, a1 ; RV32-NEXT: vmv.x.s a1, v8 ; RV32-NEXT: addi sp, sp, 16 ; RV32-NEXT: ret ; ; RV64-LABEL: vpreduce_xor_nxv4i64: ; RV64: # %bb.0: ; RV64-NEXT: vsetivli zero, 1, e64, m1, ta, ma ; RV64-NEXT: vmv.s.x v12, a0 ; RV64-NEXT: vsetvli zero, a1, e64, m4, ta, ma ; RV64-NEXT: vredxor.vs v12, v8, v12, v0.t ; RV64-NEXT: vmv.x.s a0, v12 ; RV64-NEXT: ret %r = call i64 @llvm.vp.reduce.xor.nxv4i64(i64 %s, %v, %m, i32 %evl) ret i64 %r }