third_party/llvm-7.0/llvm/test/CodeGen/X86/and-encoding.ll - SwiftShader - Git at Google

 ; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py
 ; RUN: llc -mtriple=x86_64-unknown-unknown -show-mc-encoding < %s | FileCheck %s

 ; Test that the direct object emission selects the 'and' variant with 8-bit
 ; immediate.
 ; We used to get this wrong when using direct object emission, but not when
 ; reading assembly.

 define void @f1() nounwind {
 ; CHECK-LABEL: f1:
 ; CHECK:       # %bb.0:
 ; CHECK-NEXT:    pushq %rbp # encoding: [0x55]
 ; CHECK-NEXT:    movq %rsp, %rbp # encoding: [0x48,0x89,0xe5]
 ; CHECK-NEXT:    andq $-32, %rsp # encoding: [0x48,0x83,0xe4,0xe0]
 ; CHECK-NEXT:    movq %rbp, %rsp # encoding: [0x48,0x89,0xec]
 ; CHECK-NEXT:    popq %rbp # encoding: [0x5d]
 ; CHECK-NEXT:    retq # encoding: [0xc3]
   %foo = alloca i8, align 32
   ret void
 }

 define void @f2(i16 %x, i1 *%y) nounwind  {
 ; CHECK-LABEL: f2:
 ; CHECK:       # %bb.0:
 ; CHECK-NEXT:    andl $1, %edi # encoding: [0x83,0xe7,0x01]
 ; CHECK-NEXT:    movb %dil, (%rsi) # encoding: [0x40,0x88,0x3e]
 ; CHECK-NEXT:    retq # encoding: [0xc3]
   %c = trunc i16 %x to i1
   store i1 %c, i1* %y
   ret void
 }

 define void @f3(i32 %x, i1 *%y) nounwind {
 ; CHECK-LABEL: f3:
 ; CHECK:       # %bb.0:
 ; CHECK-NEXT:    andl $1, %edi # encoding: [0x83,0xe7,0x01]
 ; CHECK-NEXT:    movb %dil, (%rsi) # encoding: [0x40,0x88,0x3e]
 ; CHECK-NEXT:    retq # encoding: [0xc3]
   %c = trunc i32 %x to i1
   store i1 %c, i1* %y
   ret void
 }

 ; The immediate (0x0ffffff0) can be made into an i8 by making it negative.

 define i32 @lopped32_32to8(i32 %x) {
 ; CHECK-LABEL: lopped32_32to8:
 ; CHECK:       # %bb.0:
 ; CHECK-NEXT:    shrl $4, %edi # encoding: [0xc1,0xef,0x04]
 ; CHECK-NEXT:    andl $-16, %edi # encoding: [0x83,0xe7,0xf0]
 ; CHECK-NEXT:    movl %edi, %eax # encoding: [0x89,0xf8]
 ; CHECK-NEXT:    retq # encoding: [0xc3]
   %shr = lshr i32 %x, 4
   %and = and i32 %shr, 268435440
   ret i32 %and
 }

 ; The immediate (0x0ffffff0) can be made into an i8 by making it negative.

 define i64 @lopped64_32to8(i64 %x) {
 ; CHECK-LABEL: lopped64_32to8:
 ; CHECK:       # %bb.0:
 ; CHECK-NEXT:    shrq $36, %rdi # encoding: [0x48,0xc1,0xef,0x24]
 ; CHECK-NEXT:    andl $-16, %edi # encoding: [0x83,0xe7,0xf0]
 ; CHECK-NEXT:    movq %rdi, %rax # encoding: [0x48,0x89,0xf8]
 ; CHECK-NEXT:    retq # encoding: [0xc3]
   %shr = lshr i64 %x, 36
   %and = and i64 %shr, 268435440
   ret i64 %and
 }

 ; The immediate (0x0ffffffffffffff0) can be made into an i8 by making it negative.

 define i64 @lopped64_64to8(i64 %x) {
 ; CHECK-LABEL: lopped64_64to8:
 ; CHECK:       # %bb.0:
 ; CHECK-NEXT:    shrq $4, %rdi # encoding: [0x48,0xc1,0xef,0x04]
 ; CHECK-NEXT:    andq $-16, %rdi # encoding: [0x48,0x83,0xe7,0xf0]
 ; CHECK-NEXT:    movq %rdi, %rax # encoding: [0x48,0x89,0xf8]
 ; CHECK-NEXT:    retq # encoding: [0xc3]
   %shr = lshr i64 %x, 4
   %and = and i64 %shr, 1152921504606846960
   ret i64 %and
 }

 ; The immediate (0x0ffffffffff0fff0) can be made into an i32 by making it negative.

 define i64 @lopped64_64to32(i64 %x) {
 ; CHECK-LABEL: lopped64_64to32:
 ; CHECK:       # %bb.0:
 ; CHECK-NEXT:    shrq $4, %rdi # encoding: [0x48,0xc1,0xef,0x04]
 ; CHECK-NEXT:    andq $-983056, %rdi # encoding: [0x48,0x81,0xe7,0xf0,0xff,0xf0,0xff]
 ; CHECK-NEXT:    # imm = 0xFFF0FFF0
 ; CHECK-NEXT:    movq %rdi, %rax # encoding: [0x48,0x89,0xf8]
 ; CHECK-NEXT:    retq # encoding: [0xc3]
   %shr = lshr i64 %x, 4
   %and = and i64 %shr, 1152921504605863920
   ret i64 %and
 }

 ; The transform is not limited to shifts - computeKnownBits() knows the top 4 bits
 ; must be cleared, so 0x0fffff80 can become 0x80 sign-extended.

 define i32 @shrinkAndKnownBits(i32 %x) {
 ; CHECK-LABEL: shrinkAndKnownBits:
 ; CHECK:       # %bb.0:
 ; CHECK-NEXT:    movl %edi, %ecx # encoding: [0x89,0xf9]
 ; CHECK-NEXT:    movl $4042322161, %eax # encoding: [0xb8,0xf1,0xf0,0xf0,0xf0]
 ; CHECK-NEXT:    # imm = 0xF0F0F0F1
 ; CHECK-NEXT:    imulq %rcx, %rax # encoding: [0x48,0x0f,0xaf,0xc1]
 ; CHECK-NEXT:    shrq $36, %rax # encoding: [0x48,0xc1,0xe8,0x24]
 ; CHECK-NEXT:    andl $-128, %eax # encoding: [0x83,0xe0,0x80]
 ; CHECK-NEXT:    # kill: def $eax killed $eax killed $rax
 ; CHECK-NEXT:    retq # encoding: [0xc3]
   %div = udiv i32 %x, 17
   %and = and i32 %div, 268435328
   ret i32 %and
 }
	; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py
	; RUN: llc -mtriple=x86_64-unknown-unknown -show-mc-encoding < %s \| FileCheck %s

	; Test that the direct object emission selects the 'and' variant with 8-bit
	; immediate.
	; We used to get this wrong when using direct object emission, but not when
	; reading assembly.

	define void @f1() nounwind {
	; CHECK-LABEL: f1:
	; CHECK: # %bb.0:
	; CHECK-NEXT: pushq %rbp # encoding: [0x55]
	; CHECK-NEXT: movq %rsp, %rbp # encoding: [0x48,0x89,0xe5]
	; CHECK-NEXT: andq $-32, %rsp # encoding: [0x48,0x83,0xe4,0xe0]
	; CHECK-NEXT: movq %rbp, %rsp # encoding: [0x48,0x89,0xec]
	; CHECK-NEXT: popq %rbp # encoding: [0x5d]
	; CHECK-NEXT: retq # encoding: [0xc3]
	%foo = alloca i8, align 32
	ret void
	}

	define void @f2(i16 %x, i1 *%y) nounwind {
	; CHECK-LABEL: f2:
	; CHECK: # %bb.0:
	; CHECK-NEXT: andl $1, %edi # encoding: [0x83,0xe7,0x01]
	; CHECK-NEXT: movb %dil, (%rsi) # encoding: [0x40,0x88,0x3e]
	; CHECK-NEXT: retq # encoding: [0xc3]
	%c = trunc i16 %x to i1
	store i1 %c, i1* %y
	ret void
	}

	define void @f3(i32 %x, i1 *%y) nounwind {
	; CHECK-LABEL: f3:
	; CHECK: # %bb.0:
	; CHECK-NEXT: andl $1, %edi # encoding: [0x83,0xe7,0x01]
	; CHECK-NEXT: movb %dil, (%rsi) # encoding: [0x40,0x88,0x3e]
	; CHECK-NEXT: retq # encoding: [0xc3]
	%c = trunc i32 %x to i1
	store i1 %c, i1* %y
	ret void
	}

	; The immediate (0x0ffffff0) can be made into an i8 by making it negative.

	define i32 @lopped32_32to8(i32 %x) {
	; CHECK-LABEL: lopped32_32to8:
	; CHECK: # %bb.0:
	; CHECK-NEXT: shrl $4, %edi # encoding: [0xc1,0xef,0x04]
	; CHECK-NEXT: andl $-16, %edi # encoding: [0x83,0xe7,0xf0]
	; CHECK-NEXT: movl %edi, %eax # encoding: [0x89,0xf8]
	; CHECK-NEXT: retq # encoding: [0xc3]
	%shr = lshr i32 %x, 4
	%and = and i32 %shr, 268435440
	ret i32 %and
	}

	; The immediate (0x0ffffff0) can be made into an i8 by making it negative.

	define i64 @lopped64_32to8(i64 %x) {
	; CHECK-LABEL: lopped64_32to8:
	; CHECK: # %bb.0:
	; CHECK-NEXT: shrq $36, %rdi # encoding: [0x48,0xc1,0xef,0x24]
	; CHECK-NEXT: andl $-16, %edi # encoding: [0x83,0xe7,0xf0]
	; CHECK-NEXT: movq %rdi, %rax # encoding: [0x48,0x89,0xf8]
	; CHECK-NEXT: retq # encoding: [0xc3]
	%shr = lshr i64 %x, 36
	%and = and i64 %shr, 268435440
	ret i64 %and
	}

	; The immediate (0x0ffffffffffffff0) can be made into an i8 by making it negative.

	define i64 @lopped64_64to8(i64 %x) {
	; CHECK-LABEL: lopped64_64to8:
	; CHECK: # %bb.0:
	; CHECK-NEXT: shrq $4, %rdi # encoding: [0x48,0xc1,0xef,0x04]
	; CHECK-NEXT: andq $-16, %rdi # encoding: [0x48,0x83,0xe7,0xf0]
	; CHECK-NEXT: movq %rdi, %rax # encoding: [0x48,0x89,0xf8]
	; CHECK-NEXT: retq # encoding: [0xc3]
	%shr = lshr i64 %x, 4
	%and = and i64 %shr, 1152921504606846960
	ret i64 %and
	}

	; The immediate (0x0ffffffffff0fff0) can be made into an i32 by making it negative.

	define i64 @lopped64_64to32(i64 %x) {
	; CHECK-LABEL: lopped64_64to32:
	; CHECK: # %bb.0:
	; CHECK-NEXT: shrq $4, %rdi # encoding: [0x48,0xc1,0xef,0x04]
	; CHECK-NEXT: andq $-983056, %rdi # encoding: [0x48,0x81,0xe7,0xf0,0xff,0xf0,0xff]
	; CHECK-NEXT: # imm = 0xFFF0FFF0
	; CHECK-NEXT: movq %rdi, %rax # encoding: [0x48,0x89,0xf8]
	; CHECK-NEXT: retq # encoding: [0xc3]
	%shr = lshr i64 %x, 4
	%and = and i64 %shr, 1152921504605863920
	ret i64 %and
	}

	; The transform is not limited to shifts - computeKnownBits() knows the top 4 bits
	; must be cleared, so 0x0fffff80 can become 0x80 sign-extended.

	define i32 @shrinkAndKnownBits(i32 %x) {
	; CHECK-LABEL: shrinkAndKnownBits:
	; CHECK: # %bb.0:
	; CHECK-NEXT: movl %edi, %ecx # encoding: [0x89,0xf9]
	; CHECK-NEXT: movl $4042322161, %eax # encoding: [0xb8,0xf1,0xf0,0xf0,0xf0]
	; CHECK-NEXT: # imm = 0xF0F0F0F1
	; CHECK-NEXT: imulq %rcx, %rax # encoding: [0x48,0x0f,0xaf,0xc1]
	; CHECK-NEXT: shrq $36, %rax # encoding: [0x48,0xc1,0xe8,0x24]
	; CHECK-NEXT: andl $-128, %eax # encoding: [0x83,0xe0,0x80]
	; CHECK-NEXT: # kill: def $eax killed $eax killed $rax
	; CHECK-NEXT: retq # encoding: [0xc3]
	%div = udiv i32 %x, 17
	%and = and i32 %div, 268435328
	ret i32 %and
	}