; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py ; Test patterns which generates lzcnt instructions. ; Eg: zext(or(setcc(cmp), setcc(cmp))) -> shr(or(lzcnt, lzcnt)) ; RUN: llc < %s -mtriple=x86_64-pc-linux -mcpu=btver2 | FileCheck %s ; RUN: llc < %s -mtriple=x86_64-pc-linux -mcpu=btver2 -mattr=-fast-lzcnt | FileCheck --check-prefix=NOFASTLZCNT %s ; RUN: llc < %s -mtriple=x86_64-pc-linux -mcpu=znver1 | FileCheck %s ; RUN: llc < %s -mtriple=x86_64-pc-linux -mcpu=znver1 -mattr=-fast-lzcnt | FileCheck --check-prefix=NOFASTLZCNT %s ; Test one 32-bit input, output is 32-bit, no transformations expected. define i32 @test_zext_cmp0(i32 %a) { ; CHECK-LABEL: test_zext_cmp0: ; CHECK: # BB#0: # %entry ; CHECK-NEXT: xorl %eax, %eax ; CHECK-NEXT: testl %edi, %edi ; CHECK-NEXT: sete %al ; CHECK-NEXT: retq ; ; NOFASTLZCNT-LABEL: test_zext_cmp0: ; NOFASTLZCNT: # BB#0: # %entry ; NOFASTLZCNT-NEXT: xorl %eax, %eax ; NOFASTLZCNT-NEXT: testl %edi, %edi ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: retq entry: %cmp = icmp eq i32 %a, 0 %conv = zext i1 %cmp to i32 ret i32 %conv } ; Test two 32-bit inputs, output is 32-bit. define i32 @test_zext_cmp1(i32 %a, i32 %b) { ; CHECK-LABEL: test_zext_cmp1: ; CHECK: # BB#0: ; CHECK-NEXT: lzcntl %edi, %ecx ; CHECK-NEXT: lzcntl %esi, %eax ; CHECK-NEXT: orl %ecx, %eax ; CHECK-NEXT: shrl $5, %eax ; CHECK-NEXT: retq ; ; NOFASTLZCNT-LABEL: test_zext_cmp1: ; NOFASTLZCNT: # BB#0: ; NOFASTLZCNT-NEXT: testl %edi, %edi ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: testl %esi, %esi ; NOFASTLZCNT-NEXT: sete %cl ; NOFASTLZCNT-NEXT: orb %al, %cl ; NOFASTLZCNT-NEXT: movzbl %cl, %eax ; NOFASTLZCNT-NEXT: retq %cmp = icmp eq i32 %a, 0 %cmp1 = icmp eq i32 %b, 0 %or = or i1 %cmp, %cmp1 %lor.ext = zext i1 %or to i32 ret i32 %lor.ext } ; Test two 64-bit inputs, output is 64-bit. define i64 @test_zext_cmp2(i64 %a, i64 %b) { ; CHECK-LABEL: test_zext_cmp2: ; CHECK: # BB#0: ; CHECK-NEXT: lzcntq %rdi, %rcx ; CHECK-NEXT: lzcntq %rsi, %rax ; CHECK-NEXT: orl %ecx, %eax ; CHECK-NEXT: shrl $6, %eax ; CHECK-NEXT: retq ; ; NOFASTLZCNT-LABEL: test_zext_cmp2: ; NOFASTLZCNT: # BB#0: ; NOFASTLZCNT-NEXT: testq %rdi, %rdi ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: testq %rsi, %rsi ; NOFASTLZCNT-NEXT: sete %cl ; NOFASTLZCNT-NEXT: orb %al, %cl ; NOFASTLZCNT-NEXT: movzbl %cl, %eax ; NOFASTLZCNT-NEXT: retq %cmp = icmp eq i64 %a, 0 %cmp1 = icmp eq i64 %b, 0 %or = or i1 %cmp, %cmp1 %lor.ext = zext i1 %or to i64 ret i64 %lor.ext } ; Test two 16-bit inputs, output is 16-bit. ; The transform is disabled for the 16-bit case, as we still have to clear the ; upper 16-bits, adding one more instruction. define i16 @test_zext_cmp3(i16 %a, i16 %b) { ; CHECK-LABEL: test_zext_cmp3: ; CHECK: # BB#0: ; CHECK-NEXT: testw %di, %di ; CHECK-NEXT: sete %al ; CHECK-NEXT: testw %si, %si ; CHECK-NEXT: sete %cl ; CHECK-NEXT: orb %al, %cl ; CHECK-NEXT: movzbl %cl, %eax ; CHECK-NEXT: # kill: %AX %AX %EAX ; CHECK-NEXT: retq ; ; NOFASTLZCNT-LABEL: test_zext_cmp3: ; NOFASTLZCNT: # BB#0: ; NOFASTLZCNT-NEXT: testw %di, %di ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: testw %si, %si ; NOFASTLZCNT-NEXT: sete %cl ; NOFASTLZCNT-NEXT: orb %al, %cl ; NOFASTLZCNT-NEXT: movzbl %cl, %eax ; NOFASTLZCNT-NEXT: # kill: %AX %AX %EAX ; NOFASTLZCNT-NEXT: retq %cmp = icmp eq i16 %a, 0 %cmp1 = icmp eq i16 %b, 0 %or = or i1 %cmp, %cmp1 %lor.ext = zext i1 %or to i16 ret i16 %lor.ext } ; Test two 32-bit inputs, output is 64-bit. define i64 @test_zext_cmp4(i32 %a, i32 %b) { ; CHECK-LABEL: test_zext_cmp4: ; CHECK: # BB#0: # %entry ; CHECK-NEXT: lzcntl %edi, %ecx ; CHECK-NEXT: lzcntl %esi, %eax ; CHECK-NEXT: orl %ecx, %eax ; CHECK-NEXT: shrl $5, %eax ; CHECK-NEXT: retq ; ; NOFASTLZCNT-LABEL: test_zext_cmp4: ; NOFASTLZCNT: # BB#0: # %entry ; NOFASTLZCNT-NEXT: testl %edi, %edi ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: testl %esi, %esi ; NOFASTLZCNT-NEXT: sete %cl ; NOFASTLZCNT-NEXT: orb %al, %cl ; NOFASTLZCNT-NEXT: movzbl %cl, %eax ; NOFASTLZCNT-NEXT: retq entry: %cmp = icmp eq i32 %a, 0 %cmp1 = icmp eq i32 %b, 0 %0 = or i1 %cmp, %cmp1 %conv = zext i1 %0 to i64 ret i64 %conv } ; Test two 64-bit inputs, output is 32-bit. define i32 @test_zext_cmp5(i64 %a, i64 %b) { ; CHECK-LABEL: test_zext_cmp5: ; CHECK: # BB#0: # %entry ; CHECK-NEXT: lzcntq %rdi, %rcx ; CHECK-NEXT: lzcntq %rsi, %rax ; CHECK-NEXT: orl %ecx, %eax ; CHECK-NEXT: shrl $6, %eax ; CHECK-NEXT: # kill: %EAX %EAX %RAX ; CHECK-NEXT: retq ; ; NOFASTLZCNT-LABEL: test_zext_cmp5: ; NOFASTLZCNT: # BB#0: # %entry ; NOFASTLZCNT-NEXT: testq %rdi, %rdi ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: testq %rsi, %rsi ; NOFASTLZCNT-NEXT: sete %cl ; NOFASTLZCNT-NEXT: orb %al, %cl ; NOFASTLZCNT-NEXT: movzbl %cl, %eax ; NOFASTLZCNT-NEXT: retq entry: %cmp = icmp eq i64 %a, 0 %cmp1 = icmp eq i64 %b, 0 %0 = or i1 %cmp, %cmp1 %lor.ext = zext i1 %0 to i32 ret i32 %lor.ext } ; Test three 32-bit inputs, output is 32-bit. define i32 @test_zext_cmp6(i32 %a, i32 %b, i32 %c) { ; CHECK-LABEL: test_zext_cmp6: ; CHECK: # BB#0: # %entry ; CHECK-NEXT: lzcntl %edi, %eax ; CHECK-NEXT: lzcntl %esi, %ecx ; CHECK-NEXT: orl %eax, %ecx ; CHECK-NEXT: lzcntl %edx, %eax ; CHECK-NEXT: orl %ecx, %eax ; CHECK-NEXT: shrl $5, %eax ; CHECK-NEXT: retq ; ; NOFASTLZCNT-LABEL: test_zext_cmp6: ; NOFASTLZCNT: # BB#0: # %entry ; NOFASTLZCNT-NEXT: testl %edi, %edi ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: testl %esi, %esi ; NOFASTLZCNT-NEXT: sete %cl ; NOFASTLZCNT-NEXT: orb %al, %cl ; NOFASTLZCNT-NEXT: testl %edx, %edx ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: orb %cl, %al ; NOFASTLZCNT-NEXT: movzbl %al, %eax ; NOFASTLZCNT-NEXT: retq entry: %cmp = icmp eq i32 %a, 0 %cmp1 = icmp eq i32 %b, 0 %or.cond = or i1 %cmp, %cmp1 %cmp2 = icmp eq i32 %c, 0 %.cmp2 = or i1 %or.cond, %cmp2 %lor.ext = zext i1 %.cmp2 to i32 ret i32 %lor.ext } ; Test three 32-bit inputs, output is 32-bit, but compared to test_zext_cmp6 test, ; %.cmp2 inputs' order is inverted. define i32 @test_zext_cmp7(i32 %a, i32 %b, i32 %c) { ; CHECK-LABEL: test_zext_cmp7: ; CHECK: # BB#0: # %entry ; CHECK-NEXT: lzcntl %edi, %eax ; CHECK-NEXT: lzcntl %esi, %ecx ; CHECK-NEXT: orl %eax, %ecx ; CHECK-NEXT: lzcntl %edx, %eax ; CHECK-NEXT: orl %ecx, %eax ; CHECK-NEXT: shrl $5, %eax ; CHECK-NEXT: retq ; ; NOFASTLZCNT-LABEL: test_zext_cmp7: ; NOFASTLZCNT: # BB#0: # %entry ; NOFASTLZCNT-NEXT: testl %edi, %edi ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: testl %esi, %esi ; NOFASTLZCNT-NEXT: sete %cl ; NOFASTLZCNT-NEXT: orb %al, %cl ; NOFASTLZCNT-NEXT: testl %edx, %edx ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: orb %cl, %al ; NOFASTLZCNT-NEXT: movzbl %al, %eax ; NOFASTLZCNT-NEXT: retq entry: %cmp = icmp eq i32 %a, 0 %cmp1 = icmp eq i32 %b, 0 %or.cond = or i1 %cmp, %cmp1 %cmp2 = icmp eq i32 %c, 0 %.cmp2 = or i1 %cmp2, %or.cond %lor.ext = zext i1 %.cmp2 to i32 ret i32 %lor.ext } ; Test four 32-bit inputs, output is 32-bit. define i32 @test_zext_cmp8(i32 %a, i32 %b, i32 %c, i32 %d) { ; CHECK-LABEL: test_zext_cmp8: ; CHECK: # BB#0: # %entry ; CHECK-NEXT: lzcntl %edi, %eax ; CHECK-NEXT: lzcntl %esi, %esi ; CHECK-NEXT: lzcntl %edx, %edx ; CHECK-NEXT: orl %eax, %esi ; CHECK-NEXT: lzcntl %ecx, %eax ; CHECK-NEXT: orl %edx, %eax ; CHECK-NEXT: orl %esi, %eax ; CHECK-NEXT: shrl $5, %eax ; CHECK-NEXT: retq ; ; NOFASTLZCNT-LABEL: test_zext_cmp8: ; NOFASTLZCNT: # BB#0: # %entry ; NOFASTLZCNT-NEXT: testl %edi, %edi ; NOFASTLZCNT-NEXT: sete %dil ; NOFASTLZCNT-NEXT: testl %esi, %esi ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: orb %dil, %al ; NOFASTLZCNT-NEXT: testl %edx, %edx ; NOFASTLZCNT-NEXT: sete %dl ; NOFASTLZCNT-NEXT: testl %ecx, %ecx ; NOFASTLZCNT-NEXT: sete %cl ; NOFASTLZCNT-NEXT: orb %dl, %cl ; NOFASTLZCNT-NEXT: orb %al, %cl ; NOFASTLZCNT-NEXT: movzbl %cl, %eax ; NOFASTLZCNT-NEXT: retq entry: %cmp = icmp eq i32 %a, 0 %cmp1 = icmp eq i32 %b, 0 %or.cond = or i1 %cmp, %cmp1 %cmp3 = icmp eq i32 %c, 0 %or.cond5 = or i1 %or.cond, %cmp3 %cmp4 = icmp eq i32 %d, 0 %.cmp4 = or i1 %or.cond5, %cmp4 %lor.ext = zext i1 %.cmp4 to i32 ret i32 %lor.ext } ; Test one 32-bit input, one 64-bit input, output is 32-bit. define i32 @test_zext_cmp9(i32 %a, i64 %b) { ; CHECK-LABEL: test_zext_cmp9: ; CHECK: # BB#0: # %entry ; CHECK-NEXT: lzcntq %rsi, %rax ; CHECK-NEXT: lzcntl %edi, %ecx ; CHECK-NEXT: shrl $5, %ecx ; CHECK-NEXT: shrl $6, %eax ; CHECK-NEXT: orl %ecx, %eax ; CHECK-NEXT: # kill: %EAX %EAX %RAX ; CHECK-NEXT: retq ; ; NOFASTLZCNT-LABEL: test_zext_cmp9: ; NOFASTLZCNT: # BB#0: # %entry ; NOFASTLZCNT-NEXT: testl %edi, %edi ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: testq %rsi, %rsi ; NOFASTLZCNT-NEXT: sete %cl ; NOFASTLZCNT-NEXT: orb %al, %cl ; NOFASTLZCNT-NEXT: movzbl %cl, %eax ; NOFASTLZCNT-NEXT: retq entry: %cmp = icmp eq i32 %a, 0 %cmp1 = icmp eq i64 %b, 0 %0 = or i1 %cmp, %cmp1 %lor.ext = zext i1 %0 to i32 ret i32 %lor.ext } ; Test 2 128-bit inputs, output is 32-bit, no transformations expected. define i32 @test_zext_cmp10(i64 %a.coerce0, i64 %a.coerce1, i64 %b.coerce0, i64 %b.coerce1) { ; CHECK-LABEL: test_zext_cmp10: ; CHECK: # BB#0: # %entry ; CHECK-NEXT: orq %rsi, %rdi ; CHECK-NEXT: sete %al ; CHECK-NEXT: orq %rcx, %rdx ; CHECK-NEXT: sete %cl ; CHECK-NEXT: orb %al, %cl ; CHECK-NEXT: movzbl %cl, %eax ; CHECK-NEXT: retq ; ; NOFASTLZCNT-LABEL: test_zext_cmp10: ; NOFASTLZCNT: # BB#0: # %entry ; NOFASTLZCNT-NEXT: orq %rsi, %rdi ; NOFASTLZCNT-NEXT: sete %al ; NOFASTLZCNT-NEXT: orq %rcx, %rdx ; NOFASTLZCNT-NEXT: sete %cl ; NOFASTLZCNT-NEXT: orb %al, %cl ; NOFASTLZCNT-NEXT: movzbl %cl, %eax ; NOFASTLZCNT-NEXT: retq entry: %a.sroa.2.0.insert.ext = zext i64 %a.coerce1 to i128 %a.sroa.2.0.insert.shift = shl nuw i128 %a.sroa.2.0.insert.ext, 64 %a.sroa.0.0.insert.ext = zext i64 %a.coerce0 to i128 %a.sroa.0.0.insert.insert = or i128 %a.sroa.2.0.insert.shift, %a.sroa.0.0.insert.ext %b.sroa.2.0.insert.ext = zext i64 %b.coerce1 to i128 %b.sroa.2.0.insert.shift = shl nuw i128 %b.sroa.2.0.insert.ext, 64 %b.sroa.0.0.insert.ext = zext i64 %b.coerce0 to i128 %b.sroa.0.0.insert.insert = or i128 %b.sroa.2.0.insert.shift, %b.sroa.0.0.insert.ext %cmp = icmp eq i128 %a.sroa.0.0.insert.insert, 0 %cmp3 = icmp eq i128 %b.sroa.0.0.insert.insert, 0 %0 = or i1 %cmp, %cmp3 %lor.ext = zext i1 %0 to i32 ret i32 %lor.ext }