; This test makes sure that these instructions are properly eliminated. ; ; RUN: llvm-upgrade < %s | llvm-as | opt -instcombine | llvm-dis | not grep and ; END. implementation int %test1(int %A) { %B = and int %A, 0 ; zero result ret int %B } int %test2(int %A) { %B = and int %A, -1 ; noop ret int %B } bool %test3(bool %A) { %B = and bool %A, false ; always = false ret bool %B } bool %test4(bool %A) { %B = and bool %A, true ; noop ret bool %B } int %test5(int %A) { %B = and int %A, %A ret int %B } bool %test6(bool %A) { %B = and bool %A, %A ret bool %B } int %test7(int %A) { ; A & ~A == 0 %NotA = xor int %A, -1 %B = and int %A, %NotA ret int %B } ubyte %test8(ubyte %A) { ; AND associates %B = and ubyte %A, 3 %C = and ubyte %B, 4 ret ubyte %C } bool %test9(int %A) { %B = and int %A, -2147483648 ; Test of sign bit, convert to setle %A, 0 %C = setne int %B, 0 ret bool %C } bool %test9(uint %A) { %B = and uint %A, 2147483648 ; Test of sign bit, convert to setle %A, 0 %C = setne uint %B, 0 ret bool %C } uint %test10(uint %A) { %B = and uint %A, 12 %C = xor uint %B, 15 %D = and uint %C, 1 ; (X ^ C1) & C2 --> (X & C2) ^ (C1&C2) ret uint %D } uint %test11(uint %A, uint* %P) { %B = or uint %A, 3 %C = xor uint %B, 12 store uint %C, uint* %P ; additional use of C %D = and uint %C, 3 ; %C = and uint %B, 3 --> 3 ret uint %D } bool %test12(uint %A, uint %B) { %C1 = setlt uint %A, %B %C2 = setle uint %A, %B %D = and bool %C1, %C2 ; (A < B) & (A <= B) === (A < B) ret bool %D } bool %test13(uint %A, uint %B) { %C1 = setlt uint %A, %B %C2 = setgt uint %A, %B %D = and bool %C1, %C2 ; (A < B) & (A > B) === false ret bool %D } bool %test14(ubyte %A) { %B = and ubyte %A, 128 %C = setne ubyte %B, 0 ret bool %C } ubyte %test15(ubyte %A) { %B = shr ubyte %A, ubyte 7 %C = and ubyte %B, 2 ; Always equals zero ret ubyte %C } ubyte %test16(ubyte %A) { %B = shl ubyte %A, ubyte 2 %C = and ubyte %B, 3 ret ubyte %C } sbyte %test17(sbyte %X, sbyte %Y) { ;; ~(~X & Y) --> (X | ~Y) %B = xor sbyte %X, -1 %C = and sbyte %B, %Y %D = xor sbyte %C, -1 ret sbyte %D } bool %test18(int %A) { %B = and int %A, -128 %C = setne int %B, 0 ;; C >= 128 ret bool %C } bool %test18a(ubyte %A) { %B = and ubyte %A, 254 %C = seteq ubyte %B, 0 ret bool %C } int %test19(int %A) { %B = shl int %A, ubyte 3 %C = and int %B, -2 ;; Clearing a zero bit ret int %C } ubyte %test20(ubyte %A) { %C = shr ubyte %A, ubyte 7 %D = and ubyte %C, 1 ;; Unneeded ret ubyte %D } bool %test22(int %A) { %B = seteq int %A, 1 %C = setge int %A, 3 %D = and bool %B, %C ;; False ret bool %D } bool %test23(int %A) { %B = setgt int %A, 1 %C = setle int %A, 2 %D = and bool %B, %C ;; A == 2 ret bool %D } bool %test24(int %A) { %B = setgt int %A, 1 %C = setne int %A, 2 %D = and bool %B, %C ;; A > 2 ret bool %D } bool %test25(int %A) { %B = setge int %A, 50 %C = setlt int %A, 100 %D = and bool %B, %C ;; (A-50) 1 ret bool %D } ubyte %test27(ubyte %A) { %B = and ubyte %A, 4 %C = sub ubyte %B, 16 %D = and ubyte %C, 240 ;; 0xF0 %E = add ubyte %D, 16 ret ubyte %E } int %test28(int %X) { ;; This is juse a zero extending shr. %Y = shr int %X, ubyte 24 ;; Sign extend %Z = and int %Y, 255 ;; Mask out sign bits ret int %Z } int %test29(ubyte %X) { %Y = cast ubyte %X to int %Z = and int %Y, 255 ;; Zero extend makes this unneeded. ret int %Z } int %test30(bool %X) { %Y = cast bool %X to int %Z = and int %Y, 1 ret int %Z } uint %test31(bool %X) { %Y = cast bool %X to uint %Z = shl uint %Y, ubyte 4 %A = and uint %Z, 16 ret uint %A } uint %test32(uint %In) { %Y = and uint %In, 16 %Z = shr uint %Y, ubyte 2 %A = and uint %Z, 1 ret uint %A } uint %test33(uint %b) { ;; Code corresponding to one-bit bitfield ^1. %tmp.4.mask = and uint %b, 1 %tmp.10 = xor uint %tmp.4.mask, 1 %tmp.12 = and uint %b, 4294967294 %tmp.13 = or uint %tmp.12, %tmp.10 ret uint %tmp.13 } int %test34(int %A, int %B) { %tmp.2 = or int %B, %A %tmp.4 = and int %tmp.2, %B ret int %tmp.4 }