test/CodeGen/X86/urem-seteq.ll - llvm-project/llvm - Git at Google

 ; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py
 ; RUN: llc -mtriple=i686-unknown-linux-gnu < %s | FileCheck %s --check-prefixes=CHECK,X86
 ; RUN: llc -mtriple=x86_64-unknown-linux-gnu < %s | FileCheck %s --check-prefixes=CHECK,X64

 ;------------------------------------------------------------------------------;
 ; Odd divisors
 ;------------------------------------------------------------------------------;

 define i32 @test_urem_odd(i32 %X) nounwind {
 ; X86-LABEL: test_urem_odd:
 ; X86:       # %bb.0:
 ; X86-NEXT:    imull $-858993459, {{[0-9]+}}(%esp), %ecx # imm = 0xCCCCCCCD
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    cmpl $858993460, %ecx # imm = 0x33333334
 ; X86-NEXT:    setb %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_odd:
 ; X64:       # %bb.0:
 ; X64-NEXT:    imull $-858993459, %edi, %ecx # imm = 0xCCCCCCCD
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    cmpl $858993460, %ecx # imm = 0x33333334
 ; X64-NEXT:    setb %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, 5
   %cmp = icmp eq i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }

 define i32 @test_urem_odd_25(i32 %X) nounwind {
 ; X86-LABEL: test_urem_odd_25:
 ; X86:       # %bb.0:
 ; X86-NEXT:    imull $-1030792151, {{[0-9]+}}(%esp), %ecx # imm = 0xC28F5C29
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    cmpl $171798692, %ecx # imm = 0xA3D70A4
 ; X86-NEXT:    setb %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_odd_25:
 ; X64:       # %bb.0:
 ; X64-NEXT:    imull $-1030792151, %edi, %ecx # imm = 0xC28F5C29
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    cmpl $171798692, %ecx # imm = 0xA3D70A4
 ; X64-NEXT:    setb %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, 25
   %cmp = icmp eq i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }

 ; This is like test_urem_odd, except the divisor has bit 30 set.
 define i32 @test_urem_odd_bit30(i32 %X) nounwind {
 ; X86-LABEL: test_urem_odd_bit30:
 ; X86:       # %bb.0:
 ; X86-NEXT:    imull $1789569707, {{[0-9]+}}(%esp), %ecx # imm = 0x6AAAAAAB
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    cmpl $4, %ecx
 ; X86-NEXT:    setb %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_odd_bit30:
 ; X64:       # %bb.0:
 ; X64-NEXT:    imull $1789569707, %edi, %ecx # imm = 0x6AAAAAAB
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    cmpl $4, %ecx
 ; X64-NEXT:    setb %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, 1073741827
   %cmp = icmp eq i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }

 ; This is like test_urem_odd, except the divisor has bit 31 set.
 define i32 @test_urem_odd_bit31(i32 %X) nounwind {
 ; X86-LABEL: test_urem_odd_bit31:
 ; X86:       # %bb.0:
 ; X86-NEXT:    imull $715827883, {{[0-9]+}}(%esp), %ecx # imm = 0x2AAAAAAB
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    cmpl $2, %ecx
 ; X86-NEXT:    setb %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_odd_bit31:
 ; X64:       # %bb.0:
 ; X64-NEXT:    imull $715827883, %edi, %ecx # imm = 0x2AAAAAAB
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    cmpl $2, %ecx
 ; X64-NEXT:    setb %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, 2147483651
   %cmp = icmp eq i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }

 ;------------------------------------------------------------------------------;
 ; Even divisors
 ;------------------------------------------------------------------------------;

 define i16 @test_urem_even(i16 %X) nounwind {
 ; X86-LABEL: test_urem_even:
 ; X86:       # %bb.0:
 ; X86-NEXT:    imull $28087, {{[0-9]+}}(%esp), %eax # imm = 0x6DB7
 ; X86-NEXT:    rorw %ax
 ; X86-NEXT:    movzwl %ax, %ecx
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    cmpl $4681, %ecx # imm = 0x1249
 ; X86-NEXT:    seta %al
 ; X86-NEXT:    # kill: def $ax killed $ax killed $eax
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_even:
 ; X64:       # %bb.0:
 ; X64-NEXT:    imull $28087, %edi, %eax # imm = 0x6DB7
 ; X64-NEXT:    rorw %ax
 ; X64-NEXT:    movzwl %ax, %ecx
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    cmpl $4681, %ecx # imm = 0x1249
 ; X64-NEXT:    seta %al
 ; X64-NEXT:    # kill: def $ax killed $ax killed $eax
 ; X64-NEXT:    retq
   %urem = urem i16 %X, 14
   %cmp = icmp ne i16 %urem, 0
   %ret = zext i1 %cmp to i16
   ret i16 %ret
 }

 define i32 @test_urem_even_100(i32 %X) nounwind {
 ; X86-LABEL: test_urem_even_100:
 ; X86:       # %bb.0:
 ; X86-NEXT:    imull $-1030792151, {{[0-9]+}}(%esp), %ecx # imm = 0xC28F5C29
 ; X86-NEXT:    rorl $2, %ecx
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    cmpl $42949673, %ecx # imm = 0x28F5C29
 ; X86-NEXT:    setb %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_even_100:
 ; X64:       # %bb.0:
 ; X64-NEXT:    imull $-1030792151, %edi, %ecx # imm = 0xC28F5C29
 ; X64-NEXT:    rorl $2, %ecx
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    cmpl $42949673, %ecx # imm = 0x28F5C29
 ; X64-NEXT:    setb %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, 100
   %cmp = icmp eq i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }

 ; This is like test_urem_even, except the divisor has bit 30 set.
 define i32 @test_urem_even_bit30(i32 %X) nounwind {
 ; X86-LABEL: test_urem_even_bit30:
 ; X86:       # %bb.0:
 ; X86-NEXT:    imull $-51622203, {{[0-9]+}}(%esp), %ecx # imm = 0xFCEC4EC5
 ; X86-NEXT:    rorl $3, %ecx
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    cmpl $4, %ecx
 ; X86-NEXT:    setb %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_even_bit30:
 ; X64:       # %bb.0:
 ; X64-NEXT:    imull $-51622203, %edi, %ecx # imm = 0xFCEC4EC5
 ; X64-NEXT:    rorl $3, %ecx
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    cmpl $4, %ecx
 ; X64-NEXT:    setb %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, 1073741928
   %cmp = icmp eq i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }

 ; This is like test_urem_odd, except the divisor has bit 31 set.
 define i32 @test_urem_even_bit31(i32 %X) nounwind {
 ; X86-LABEL: test_urem_even_bit31:
 ; X86:       # %bb.0:
 ; X86-NEXT:    imull $-1157956869, {{[0-9]+}}(%esp), %ecx # imm = 0xBAFAFAFB
 ; X86-NEXT:    rorl %ecx
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    cmpl $2, %ecx
 ; X86-NEXT:    setb %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_even_bit31:
 ; X64:       # %bb.0:
 ; X64-NEXT:    imull $-1157956869, %edi, %ecx # imm = 0xBAFAFAFB
 ; X64-NEXT:    rorl %ecx
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    cmpl $2, %ecx
 ; X64-NEXT:    setb %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, 2147483750
   %cmp = icmp eq i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }

 ;------------------------------------------------------------------------------;
 ; Special case
 ;------------------------------------------------------------------------------;

 ; 'NE' predicate is fine too.
 define i32 @test_urem_odd_setne(i32 %X) nounwind {
 ; X86-LABEL: test_urem_odd_setne:
 ; X86:       # %bb.0:
 ; X86-NEXT:    imull $-858993459, {{[0-9]+}}(%esp), %ecx # imm = 0xCCCCCCCD
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    cmpl $858993459, %ecx # imm = 0x33333333
 ; X86-NEXT:    seta %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_odd_setne:
 ; X64:       # %bb.0:
 ; X64-NEXT:    imull $-858993459, %edi, %ecx # imm = 0xCCCCCCCD
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    cmpl $858993459, %ecx # imm = 0x33333333
 ; X64-NEXT:    seta %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, 5
   %cmp = icmp ne i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }

 ; The fold is only valid for positive divisors, negative-ones should be negated.
 define i32 @test_urem_negative_odd(i32 %X) nounwind {
 ; X86-LABEL: test_urem_negative_odd:
 ; X86:       # %bb.0:
 ; X86-NEXT:    imull $858993459, {{[0-9]+}}(%esp), %ecx # imm = 0x33333333
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    cmpl $1, %ecx
 ; X86-NEXT:    seta %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_negative_odd:
 ; X64:       # %bb.0:
 ; X64-NEXT:    imull $858993459, %edi, %ecx # imm = 0x33333333
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    cmpl $1, %ecx
 ; X64-NEXT:    seta %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, -5
   %cmp = icmp ne i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }
 define i32 @test_urem_negative_even(i32 %X) nounwind {
 ; X86-LABEL: test_urem_negative_even:
 ; X86:       # %bb.0:
 ; X86-NEXT:    imull $-920350135, {{[0-9]+}}(%esp), %ecx # imm = 0xC9249249
 ; X86-NEXT:    rorl %ecx
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    cmpl $1, %ecx
 ; X86-NEXT:    seta %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_negative_even:
 ; X64:       # %bb.0:
 ; X64-NEXT:    imull $-920350135, %edi, %ecx # imm = 0xC9249249
 ; X64-NEXT:    rorl %ecx
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    cmpl $1, %ecx
 ; X64-NEXT:    seta %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, -14
   %cmp = icmp ne i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }

 ;------------------------------------------------------------------------------;
 ; Negative tests
 ;------------------------------------------------------------------------------;

 ; We can lower remainder of division by one much better elsewhere.
 define i32 @test_urem_one(i32 %X) nounwind {
 ; CHECK-LABEL: test_urem_one:
 ; CHECK:       # %bb.0:
 ; CHECK-NEXT:    movl $1, %eax
 ; CHECK-NEXT:    ret{{[l|q]}}
   %urem = urem i32 %X, 1
   %cmp = icmp eq i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }

 ; We can lower remainder of division by powers of two much better elsewhere.
 define i32 @test_urem_pow2(i32 %X) nounwind {
 ; X86-LABEL: test_urem_pow2:
 ; X86:       # %bb.0:
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    testb $15, {{[0-9]+}}(%esp)
 ; X86-NEXT:    sete %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_pow2:
 ; X64:       # %bb.0:
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    testb $15, %dil
 ; X64-NEXT:    sete %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, 16
   %cmp = icmp eq i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }

 ; The fold is only valid for positive divisors, and we can't negate INT_MIN.
 define i32 @test_urem_int_min(i32 %X) nounwind {
 ; X86-LABEL: test_urem_int_min:
 ; X86:       # %bb.0:
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    testl $2147483647, {{[0-9]+}}(%esp) # imm = 0x7FFFFFFF
 ; X86-NEXT:    sete %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_int_min:
 ; X64:       # %bb.0:
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    testl $2147483647, %edi # imm = 0x7FFFFFFF
 ; X64-NEXT:    sete %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, 2147483648
   %cmp = icmp eq i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }

 ; We can lower remainder of division by all-ones much better elsewhere.
 define i32 @test_urem_allones(i32 %X) nounwind {
 ; X86-LABEL: test_urem_allones:
 ; X86:       # %bb.0:
 ; X86-NEXT:    xorl %ecx, %ecx
 ; X86-NEXT:    subl {{[0-9]+}}(%esp), %ecx
 ; X86-NEXT:    xorl %eax, %eax
 ; X86-NEXT:    cmpl $2, %ecx
 ; X86-NEXT:    setb %al
 ; X86-NEXT:    retl
 ;
 ; X64-LABEL: test_urem_allones:
 ; X64:       # %bb.0:
 ; X64-NEXT:    negl %edi
 ; X64-NEXT:    xorl %eax, %eax
 ; X64-NEXT:    cmpl $2, %edi
 ; X64-NEXT:    setb %al
 ; X64-NEXT:    retq
   %urem = urem i32 %X, 4294967295
   %cmp = icmp eq i32 %urem, 0
   %ret = zext i1 %cmp to i32
   ret i32 %ret
 }
	; NOTE: Assertions have been autogenerated by utils/update_llc_test_checks.py
	; RUN: llc -mtriple=i686-unknown-linux-gnu < %s \| FileCheck %s --check-prefixes=CHECK,X86
	; RUN: llc -mtriple=x86_64-unknown-linux-gnu < %s \| FileCheck %s --check-prefixes=CHECK,X64

	;------------------------------------------------------------------------------;
	; Odd divisors
	;------------------------------------------------------------------------------;

	define i32 @test_urem_odd(i32 %X) nounwind {
	; X86-LABEL: test_urem_odd:
	; X86: # %bb.0:
	; X86-NEXT: imull $-858993459, {{[0-9]+}}(%esp), %ecx # imm = 0xCCCCCCCD
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: cmpl $858993460, %ecx # imm = 0x33333334
	; X86-NEXT: setb %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_odd:
	; X64: # %bb.0:
	; X64-NEXT: imull $-858993459, %edi, %ecx # imm = 0xCCCCCCCD
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: cmpl $858993460, %ecx # imm = 0x33333334
	; X64-NEXT: setb %al
	; X64-NEXT: retq
	%urem = urem i32 %X, 5
	%cmp = icmp eq i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}

	define i32 @test_urem_odd_25(i32 %X) nounwind {
	; X86-LABEL: test_urem_odd_25:
	; X86: # %bb.0:
	; X86-NEXT: imull $-1030792151, {{[0-9]+}}(%esp), %ecx # imm = 0xC28F5C29
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: cmpl $171798692, %ecx # imm = 0xA3D70A4
	; X86-NEXT: setb %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_odd_25:
	; X64: # %bb.0:
	; X64-NEXT: imull $-1030792151, %edi, %ecx # imm = 0xC28F5C29
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: cmpl $171798692, %ecx # imm = 0xA3D70A4
	; X64-NEXT: setb %al
	; X64-NEXT: retq
	%urem = urem i32 %X, 25
	%cmp = icmp eq i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}

	; This is like test_urem_odd, except the divisor has bit 30 set.
	define i32 @test_urem_odd_bit30(i32 %X) nounwind {
	; X86-LABEL: test_urem_odd_bit30:
	; X86: # %bb.0:
	; X86-NEXT: imull $1789569707, {{[0-9]+}}(%esp), %ecx # imm = 0x6AAAAAAB
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: cmpl $4, %ecx
	; X86-NEXT: setb %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_odd_bit30:
	; X64: # %bb.0:
	; X64-NEXT: imull $1789569707, %edi, %ecx # imm = 0x6AAAAAAB
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: cmpl $4, %ecx
	; X64-NEXT: setb %al
	; X64-NEXT: retq
	%urem = urem i32 %X, 1073741827
	%cmp = icmp eq i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}

	; This is like test_urem_odd, except the divisor has bit 31 set.
	define i32 @test_urem_odd_bit31(i32 %X) nounwind {
	; X86-LABEL: test_urem_odd_bit31:
	; X86: # %bb.0:
	; X86-NEXT: imull $715827883, {{[0-9]+}}(%esp), %ecx # imm = 0x2AAAAAAB
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: cmpl $2, %ecx
	; X86-NEXT: setb %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_odd_bit31:
	; X64: # %bb.0:
	; X64-NEXT: imull $715827883, %edi, %ecx # imm = 0x2AAAAAAB
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: cmpl $2, %ecx
	; X64-NEXT: setb %al
	; X64-NEXT: retq
	%urem = urem i32 %X, 2147483651
	%cmp = icmp eq i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}

	;------------------------------------------------------------------------------;
	; Even divisors
	;------------------------------------------------------------------------------;

	define i16 @test_urem_even(i16 %X) nounwind {
	; X86-LABEL: test_urem_even:
	; X86: # %bb.0:
	; X86-NEXT: imull $28087, {{[0-9]+}}(%esp), %eax # imm = 0x6DB7
	; X86-NEXT: rorw %ax
	; X86-NEXT: movzwl %ax, %ecx
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: cmpl $4681, %ecx # imm = 0x1249
	; X86-NEXT: seta %al
	; X86-NEXT: # kill: def $ax killed $ax killed $eax
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_even:
	; X64: # %bb.0:
	; X64-NEXT: imull $28087, %edi, %eax # imm = 0x6DB7
	; X64-NEXT: rorw %ax
	; X64-NEXT: movzwl %ax, %ecx
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: cmpl $4681, %ecx # imm = 0x1249
	; X64-NEXT: seta %al
	; X64-NEXT: # kill: def $ax killed $ax killed $eax
	; X64-NEXT: retq
	%urem = urem i16 %X, 14
	%cmp = icmp ne i16 %urem, 0
	%ret = zext i1 %cmp to i16
	ret i16 %ret
	}

	define i32 @test_urem_even_100(i32 %X) nounwind {
	; X86-LABEL: test_urem_even_100:
	; X86: # %bb.0:
	; X86-NEXT: imull $-1030792151, {{[0-9]+}}(%esp), %ecx # imm = 0xC28F5C29
	; X86-NEXT: rorl $2, %ecx
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: cmpl $42949673, %ecx # imm = 0x28F5C29
	; X86-NEXT: setb %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_even_100:
	; X64: # %bb.0:
	; X64-NEXT: imull $-1030792151, %edi, %ecx # imm = 0xC28F5C29
	; X64-NEXT: rorl $2, %ecx
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: cmpl $42949673, %ecx # imm = 0x28F5C29
	; X64-NEXT: setb %al
	; X64-NEXT: retq
	%urem = urem i32 %X, 100
	%cmp = icmp eq i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}

	; This is like test_urem_even, except the divisor has bit 30 set.
	define i32 @test_urem_even_bit30(i32 %X) nounwind {
	; X86-LABEL: test_urem_even_bit30:
	; X86: # %bb.0:
	; X86-NEXT: imull $-51622203, {{[0-9]+}}(%esp), %ecx # imm = 0xFCEC4EC5
	; X86-NEXT: rorl $3, %ecx
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: cmpl $4, %ecx
	; X86-NEXT: setb %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_even_bit30:
	; X64: # %bb.0:
	; X64-NEXT: imull $-51622203, %edi, %ecx # imm = 0xFCEC4EC5
	; X64-NEXT: rorl $3, %ecx
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: cmpl $4, %ecx
	; X64-NEXT: setb %al
	; X64-NEXT: retq
	%urem = urem i32 %X, 1073741928
	%cmp = icmp eq i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}

	; This is like test_urem_odd, except the divisor has bit 31 set.
	define i32 @test_urem_even_bit31(i32 %X) nounwind {
	; X86-LABEL: test_urem_even_bit31:
	; X86: # %bb.0:
	; X86-NEXT: imull $-1157956869, {{[0-9]+}}(%esp), %ecx # imm = 0xBAFAFAFB
	; X86-NEXT: rorl %ecx
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: cmpl $2, %ecx
	; X86-NEXT: setb %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_even_bit31:
	; X64: # %bb.0:
	; X64-NEXT: imull $-1157956869, %edi, %ecx # imm = 0xBAFAFAFB
	; X64-NEXT: rorl %ecx
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: cmpl $2, %ecx
	; X64-NEXT: setb %al
	; X64-NEXT: retq
	%urem = urem i32 %X, 2147483750
	%cmp = icmp eq i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}

	;------------------------------------------------------------------------------;
	; Special case
	;------------------------------------------------------------------------------;

	; 'NE' predicate is fine too.
	define i32 @test_urem_odd_setne(i32 %X) nounwind {
	; X86-LABEL: test_urem_odd_setne:
	; X86: # %bb.0:
	; X86-NEXT: imull $-858993459, {{[0-9]+}}(%esp), %ecx # imm = 0xCCCCCCCD
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: cmpl $858993459, %ecx # imm = 0x33333333
	; X86-NEXT: seta %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_odd_setne:
	; X64: # %bb.0:
	; X64-NEXT: imull $-858993459, %edi, %ecx # imm = 0xCCCCCCCD
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: cmpl $858993459, %ecx # imm = 0x33333333
	; X64-NEXT: seta %al
	; X64-NEXT: retq
	%urem = urem i32 %X, 5
	%cmp = icmp ne i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}

	; The fold is only valid for positive divisors, negative-ones should be negated.
	define i32 @test_urem_negative_odd(i32 %X) nounwind {
	; X86-LABEL: test_urem_negative_odd:
	; X86: # %bb.0:
	; X86-NEXT: imull $858993459, {{[0-9]+}}(%esp), %ecx # imm = 0x33333333
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: cmpl $1, %ecx
	; X86-NEXT: seta %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_negative_odd:
	; X64: # %bb.0:
	; X64-NEXT: imull $858993459, %edi, %ecx # imm = 0x33333333
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: cmpl $1, %ecx
	; X64-NEXT: seta %al
	; X64-NEXT: retq
	%urem = urem i32 %X, -5
	%cmp = icmp ne i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}
	define i32 @test_urem_negative_even(i32 %X) nounwind {
	; X86-LABEL: test_urem_negative_even:
	; X86: # %bb.0:
	; X86-NEXT: imull $-920350135, {{[0-9]+}}(%esp), %ecx # imm = 0xC9249249
	; X86-NEXT: rorl %ecx
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: cmpl $1, %ecx
	; X86-NEXT: seta %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_negative_even:
	; X64: # %bb.0:
	; X64-NEXT: imull $-920350135, %edi, %ecx # imm = 0xC9249249
	; X64-NEXT: rorl %ecx
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: cmpl $1, %ecx
	; X64-NEXT: seta %al
	; X64-NEXT: retq
	%urem = urem i32 %X, -14
	%cmp = icmp ne i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}

	;------------------------------------------------------------------------------;
	; Negative tests
	;------------------------------------------------------------------------------;

	; We can lower remainder of division by one much better elsewhere.
	define i32 @test_urem_one(i32 %X) nounwind {
	; CHECK-LABEL: test_urem_one:
	; CHECK: # %bb.0:
	; CHECK-NEXT: movl $1, %eax
	; CHECK-NEXT: ret{{[l\|q]}}
	%urem = urem i32 %X, 1
	%cmp = icmp eq i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}

	; We can lower remainder of division by powers of two much better elsewhere.
	define i32 @test_urem_pow2(i32 %X) nounwind {
	; X86-LABEL: test_urem_pow2:
	; X86: # %bb.0:
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: testb $15, {{[0-9]+}}(%esp)
	; X86-NEXT: sete %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_pow2:
	; X64: # %bb.0:
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: testb $15, %dil
	; X64-NEXT: sete %al
	; X64-NEXT: retq
	%urem = urem i32 %X, 16
	%cmp = icmp eq i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}

	; The fold is only valid for positive divisors, and we can't negate INT_MIN.
	define i32 @test_urem_int_min(i32 %X) nounwind {
	; X86-LABEL: test_urem_int_min:
	; X86: # %bb.0:
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: testl $2147483647, {{[0-9]+}}(%esp) # imm = 0x7FFFFFFF
	; X86-NEXT: sete %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_int_min:
	; X64: # %bb.0:
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: testl $2147483647, %edi # imm = 0x7FFFFFFF
	; X64-NEXT: sete %al
	; X64-NEXT: retq
	%urem = urem i32 %X, 2147483648
	%cmp = icmp eq i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}

	; We can lower remainder of division by all-ones much better elsewhere.
	define i32 @test_urem_allones(i32 %X) nounwind {
	; X86-LABEL: test_urem_allones:
	; X86: # %bb.0:
	; X86-NEXT: xorl %ecx, %ecx
	; X86-NEXT: subl {{[0-9]+}}(%esp), %ecx
	; X86-NEXT: xorl %eax, %eax
	; X86-NEXT: cmpl $2, %ecx
	; X86-NEXT: setb %al
	; X86-NEXT: retl
	;
	; X64-LABEL: test_urem_allones:
	; X64: # %bb.0:
	; X64-NEXT: negl %edi
	; X64-NEXT: xorl %eax, %eax
	; X64-NEXT: cmpl $2, %edi
	; X64-NEXT: setb %al
	; X64-NEXT: retq
	%urem = urem i32 %X, 4294967295
	%cmp = icmp eq i32 %urem, 0
	%ret = zext i1 %cmp to i32
	ret i32 %ret
	}