llvm-mirror/test/Transforms/InstCombine/phi.ll

; This test makes sure that these instructions are properly eliminated.
;
; RUN: opt < %s -instcombine -S | FileCheck %s

target datalayout = "e-p:64:64:64-i1:8:8-i8:8:8-i16:16:16-i32:32:32-i64:64:64-f32:32:32-f64:64:64-v64:64:64-v128:128:128-a0:0:64-s0:64:64-f80:128:128:n8:16:32:64"

define i32 @test1(i32 %A, i1 %b) {
BB0:
        br i1 %b, label %BB1, label %BB2

BB1:
        ; Combine away one argument PHI nodes
        %B = phi i32 [ %A, %BB0 ]               
        ret i32 %B

BB2:
        ret i32 %A
; CHECK: @test1
; CHECK: BB1:
; CHECK-NEXT: ret i32 %A
}

define i32 @test2(i32 %A, i1 %b) {
BB0:
        br i1 %b, label %BB1, label %BB2

BB1:
        br label %BB2

BB2:
        ; Combine away PHI nodes with same values
        %B = phi i32 [ %A, %BB0 ], [ %A, %BB1 ]         
        ret i32 %B
; CHECK: @test2
; CHECK: BB2:
; CHECK-NEXT: ret i32 %A
}

define i32 @test3(i32 %A, i1 %b) {
BB0:
        br label %Loop

Loop:
        ; PHI has same value always.
        %B = phi i32 [ %A, %BB0 ], [ %B, %Loop ]
        br i1 %b, label %Loop, label %Exit

Exit:
        ret i32 %B
; CHECK: @test3
; CHECK: Exit:
; CHECK-NEXT: ret i32 %A
}

define i32 @test4(i1 %b) {
BB0:
        ; Loop is unreachable
        ret i32 7

Loop:           ; preds = %L2, %Loop
        ; PHI has same value always.
        %B = phi i32 [ %B, %L2 ], [ %B, %Loop ]         
        br i1 %b, label %L2, label %Loop

L2:             ; preds = %Loop
        br label %Loop
; CHECK: @test4
; CHECK: Loop:
; CHECK-NEXT: br i1 %b
}

define i32 @test5(i32 %A, i1 %b) {
BB0:
        br label %Loop

Loop:           ; preds = %Loop, %BB0
        ; PHI has same value always.
        %B = phi i32 [ %A, %BB0 ], [ undef, %Loop ]             
        br i1 %b, label %Loop, label %Exit

Exit:           ; preds = %Loop
        ret i32 %B
; CHECK: @test5
; CHECK: Loop:
; CHECK-NEXT: br i1 %b
; CHECK: Exit:
; CHECK-NEXT: ret i32 %A
}

define i32 @test6(i16 %A, i1 %b) {
BB0:
        %X = zext i16 %A to i32              
        br i1 %b, label %BB1, label %BB2

BB1:           
        %Y = zext i16 %A to i32              
        br label %BB2

BB2:           
        ;; Suck casts into phi
        %B = phi i32 [ %X, %BB0 ], [ %Y, %BB1 ]         
        ret i32 %B
; CHECK: @test6
; CHECK: BB2:
; CHECK: zext i16 %A to i32
; CHECK-NEXT: ret i32
}

define i32 @test7(i32 %A, i1 %b) {
BB0:
        br label %Loop

Loop:           ; preds = %Loop, %BB0
        ; PHI is dead.
        %B = phi i32 [ %A, %BB0 ], [ %C, %Loop ]                
        %C = add i32 %B, 123            
        br i1 %b, label %Loop, label %Exit

Exit:           ; preds = %Loop
        ret i32 0
; CHECK: @test7
; CHECK: Loop:
; CHECK-NEXT: br i1 %b
}

define i32* @test8({ i32, i32 } *%A, i1 %b) {
BB0:
        %X = getelementptr { i32, i32 } *%A, i32 0, i32 1
        br i1 %b, label %BB1, label %BB2

BB1:
        %Y = getelementptr { i32, i32 } *%A, i32 0, i32 1
        br label %BB2

BB2:
        ;; Suck GEPs into phi
        %B = phi i32* [ %X, %BB0 ], [ %Y, %BB1 ]
        ret i32* %B
; CHECK: @test8
; CHECK-NOT: phi
; CHECK: BB2:
; CHECK-NEXT: %B = getelementptr 
; CHECK-NEXT: ret i32* %B
}

define i32 @test9(i32* %A, i32* %B) {
entry:
  %c = icmp eq i32* %A, null
  br i1 %c, label %bb1, label %bb

bb:
  %C = load i32* %B, align 1
  br label %bb2

bb1:
  %D = load i32* %A, align 1
  br label %bb2

bb2:
  %E = phi i32 [ %C, %bb ], [ %D, %bb1 ]
  ret i32 %E
; CHECK: @test9
; CHECK:       bb2:
; CHECK-NEXT:        phi i32* [ %B, %bb ], [ %A, %bb1 ]
; CHECK-NEXT:   %E = load i32* %{{[^,]*}}, align 1
; CHECK-NEXT:   ret i32 %E

}

define i32 @test10(i32* %A, i32* %B) {
entry:
  %c = icmp eq i32* %A, null
  br i1 %c, label %bb1, label %bb

bb:
  %C = load i32* %B, align 16
  br label %bb2

bb1:
  %D = load i32* %A, align 32
  br label %bb2

bb2:
  %E = phi i32 [ %C, %bb ], [ %D, %bb1 ]
  ret i32 %E
; CHECK: @test10
; CHECK:       bb2:
; CHECK-NEXT:        phi i32* [ %B, %bb ], [ %A, %bb1 ]
; CHECK-NEXT:   %E = load i32* %{{[^,]*}}, align 16
; CHECK-NEXT:   ret i32 %E
}


; PR1777
declare i1 @test11a()

define i1 @test11() {
entry:
  %a = alloca i32
  %i = ptrtoint i32* %a to i32
  %b = call i1 @test11a()
  br i1 %b, label %one, label %two

one:
  %x = phi i32 [%i, %entry], [%y, %two]
  %c = call i1 @test11a()
  br i1 %c, label %two, label %end

two:
  %y = phi i32 [%i, %entry], [%x, %one]
  %d = call i1 @test11a()
  br i1 %d, label %one, label %end

end:
  %f = phi i32 [ %x, %one], [%y, %two]
  ; Change the %f to %i, and the optimizer suddenly becomes a lot smarter
  ; even though %f must equal %i at this point
  %g = inttoptr i32 %f to i32*
  store i32 10, i32* %g
  %z = call i1 @test11a()
  ret i1 %z
; CHECK: @test11
; CHECK-NOT: phi i32
; CHECK: ret i1 %z
}


define i64 @test12(i1 %cond, i8* %Ptr, i64 %Val) {
entry:
  %tmp41 = ptrtoint i8* %Ptr to i64
  %tmp42 = zext i64 %tmp41 to i128
  br i1 %cond, label %end, label %two

two:
  %tmp36 = zext i64 %Val to i128            ; <i128> [#uses=1]
  %tmp37 = shl i128 %tmp36, 64                    ; <i128> [#uses=1]
  %ins39 = or i128 %tmp42, %tmp37                 ; <i128> [#uses=1]
  br label %end

end:
  %tmp869.0 = phi i128 [ %tmp42, %entry ], [ %ins39, %two ]
  %tmp32 = trunc i128 %tmp869.0 to i64            ; <i64> [#uses=1]
  %tmp29 = lshr i128 %tmp869.0, 64                ; <i128> [#uses=1]
  %tmp30 = trunc i128 %tmp29 to i64               ; <i64> [#uses=1]

  %tmp2 = add i64 %tmp32, %tmp30
  ret i64 %tmp2
; CHECK: @test12
; CHECK-NOT: zext
; CHECK: end:
; CHECK-NEXT: phi i64 [ 0, %entry ], [ %Val, %two ]
; CHECK-NOT: phi
; CHECK: ret i64
}

declare void @test13f(double, i32)

define void @test13(i1 %cond, i32 %V1, double %Vald) {
entry:
  %tmp42 = zext i32 %V1 to i128
  br i1 %cond, label %end, label %two

two:
  %Val = bitcast double %Vald to i64
  %tmp36 = zext i64 %Val to i128            ; <i128> [#uses=1]
  %tmp37 = shl i128 %tmp36, 64                    ; <i128> [#uses=1]
  %ins39 = or i128 %tmp42, %tmp37                 ; <i128> [#uses=1]
  br label %end

end:
  %tmp869.0 = phi i128 [ %tmp42, %entry ], [ %ins39, %two ]
  %tmp32 = trunc i128 %tmp869.0 to i32
  %tmp29 = lshr i128 %tmp869.0, 64                ; <i128> [#uses=1]
  %tmp30 = trunc i128 %tmp29 to i64               ; <i64> [#uses=1]
  %tmp31 = bitcast i64 %tmp30 to double
  
  call void @test13f(double %tmp31, i32 %tmp32)
  ret void
; CHECK: @test13
; CHECK-NOT: zext
; CHECK: end:
; CHECK-NEXT: phi double [ 0.000000e+00, %entry ], [ %Vald, %two ]
; CHECK-NEXT: call void @test13f(double {{[^,]*}}, i32 %V1)
; CHECK: ret void
}

define i640 @test14a(i320 %A, i320 %B, i1 %b1) {
BB0:
        %a = zext i320 %A to i640
        %b = zext i320 %B to i640
        br label %Loop

Loop:
        %C = phi i640 [ %a, %BB0 ], [ %b, %Loop ]             
        br i1 %b1, label %Loop, label %Exit

Exit:           ; preds = %Loop
        ret i640 %C
; CHECK: @test14a
; CHECK: Loop:
; CHECK-NEXT: phi i320
}

define i160 @test14b(i320 %A, i320 %B, i1 %b1) {
BB0:
        %a = trunc i320 %A to i160
        %b = trunc i320 %B to i160
        br label %Loop

Loop:
        %C = phi i160 [ %a, %BB0 ], [ %b, %Loop ]             
        br i1 %b1, label %Loop, label %Exit

Exit:           ; preds = %Loop
        ret i160 %C
; CHECK: @test14b
; CHECK: Loop:
; CHECK-NEXT: phi i160
}

declare i64 @test15a(i64)

define i64 @test15b(i64 %A, i1 %b) {
; CHECK: @test15b
entry:
  %i0 = zext i64 %A to i128
  %i1 = shl i128 %i0, 64
  %i = or i128 %i1, %i0
  br i1 %b, label %one, label %two
; CHECK: entry:
; CHECK-NEXT: br i1 %b

one:
  %x = phi i128 [%i, %entry], [%y, %two]
  %x1 = lshr i128 %x, 64
  %x2 = trunc i128 %x1 to i64
  %c = call i64 @test15a(i64 %x2)
  %c1 = zext i64 %c to i128
  br label %two

; CHECK: one:
; CHECK-NEXT: phi i64
; CHECK-NEXT: %c = call i64 @test15a

two:
  %y = phi i128 [%i, %entry], [%c1, %one]
  %y1 = lshr i128 %y, 64
  %y2 = trunc i128 %y1 to i64
  %d = call i64 @test15a(i64 %y2)
  %d1 = trunc i64 %d to i1
  br i1 %d1, label %one, label %end

; CHECK: two:
; CHECK-NEXT: phi i64
; CHECK-NEXT: phi i64
; CHECK-NEXT: %d = call i64 @test15a

end:
  %g = trunc i128 %y to i64
  ret i64 %g
; CHECK: end: 
; CHECK-NEXT: ret i64
}
New testcase for PHI folding llvm-svn: 2495 2002-05-06 19:43:38 +02:00			`; This test makes sure that these instructions are properly eliminated.`
			`;`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`; RUN: opt < %s -instcombine -S \| FileCheck %s`
New testcase for PHI folding llvm-svn: 2495 2002-05-06 19:43:38 +02:00
reapply r8644[3-5] with only the scary part (SliceUpIllegalIntegerPHI) disabled. llvm-svn: 86480 2009-11-08 20:23:30 +01:00			`target datalayout = "e-p:64:64:64-i1:8:8-i8:8:8-i16:16:16-i32:32:32-i64:64:64-f32:32:32-f64:64:64-v64:64:64-v128:128:128-a0:0:64-s0:64:64-f80:128:128:n8:16:32:64"`

Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`define i32 @test1(i32 %A, i1 %b) {`
			`BB0:`
			`br i1 %b, label %BB1, label %BB2`

convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`BB1:`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`; Combine away one argument PHI nodes`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`%B = phi i32 [ %A, %BB0 ]`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`ret i32 %B`
New testcase for PHI folding llvm-svn: 2495 2002-05-06 19:43:38 +02:00
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`BB2:`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`ret i32 %A`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`; CHECK: @test1`
			`; CHECK: BB1:`
			`; CHECK-NEXT: ret i32 %A`
New testcase for PHI folding llvm-svn: 2495 2002-05-06 19:43:38 +02:00			`}`

Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`define i32 @test2(i32 %A, i1 %b) {`
			`BB0:`
			`br i1 %b, label %BB1, label %BB2`

convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`BB1:`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`br label %BB2`

convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`BB2:`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`; Combine away PHI nodes with same values`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`%B = phi i32 [ %A, %BB0 ], [ %A, %BB1 ]`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`ret i32 %B`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`; CHECK: @test2`
			`; CHECK: BB2:`
			`; CHECK-NEXT: ret i32 %A`
New testcase for instcombine llvm-svn: 3396 2002-08-20 17:27:45 +02:00			`}`

Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`define i32 @test3(i32 %A, i1 %b) {`
			`BB0:`
			`br label %Loop`

convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`Loop:`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`; PHI has same value always.`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`%B = phi i32 [ %A, %BB0 ], [ %B, %Loop ]`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`br i1 %b, label %Loop, label %Exit`
Add new testcases for instcombine llvm-svn: 3477 2002-08-22 23:26:15 +02:00
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`Exit:`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`ret i32 %B`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`; CHECK: @test3`
			`; CHECK: Exit:`
			`; CHECK-NEXT: ret i32 %A`
Add new testcases for instcombine llvm-svn: 3477 2002-08-22 23:26:15 +02:00			`}`

Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`define i32 @test4(i1 %b) {`
			`BB0:`
			`; Loop is unreachable`
			`ret i32 7`
Add new testcases for instcombine llvm-svn: 3477 2002-08-22 23:26:15 +02:00
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`Loop: ; preds = %L2, %Loop`
			`; PHI has same value always.`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`%B = phi i32 [ %B, %L2 ], [ %B, %Loop ]`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`br i1 %b, label %L2, label %Loop`

			`L2: ; preds = %Loop`
			`br label %Loop`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`; CHECK: @test4`
			`; CHECK: Loop:`
			`; CHECK-NEXT: br i1 %b`
Add new testcases for instcombine llvm-svn: 3477 2002-08-22 23:26:15 +02:00			`}`

Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`define i32 @test5(i32 %A, i1 %b) {`
			`BB0:`
			`br label %Loop`

			`Loop: ; preds = %Loop, %BB0`
			`; PHI has same value always.`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`%B = phi i32 [ %A, %BB0 ], [ undef, %Loop ]`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`br i1 %b, label %Loop, label %Exit`
add a testcase, which we already handle llvm-svn: 17737 2004-11-14 18:54:27 +01:00
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`Exit: ; preds = %Loop`
			`ret i32 %B`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`; CHECK: @test5`
			`; CHECK: Loop:`
			`; CHECK-NEXT: br i1 %b`
			`; CHECK: Exit:`
			`; CHECK-NEXT: ret i32 %A`
add a testcase, which we already handle llvm-svn: 17737 2004-11-14 18:54:27 +01:00			`}`

convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`define i32 @test6(i16 %A, i1 %b) {`
New testcase: the phi can be eliminated if the casts are sucked into it. Note that this reduces code size anyway (as well as making further optimizations simpler) so it's always a win. llvm-svn: 17739 2004-11-14 20:12:17 +01:00			`BB0:`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`%X = zext i16 %A to i32`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`br i1 %b, label %BB1, label %BB2`

convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`BB1:`
			`%Y = zext i16 %A to i32`
New testcase: the phi can be eliminated if the casts are sucked into it. Note that this reduces code size anyway (as well as making further optimizations simpler) so it's always a win. llvm-svn: 17739 2004-11-14 20:12:17 +01:00			`br label %BB2`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`BB2:`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`;; Suck casts into phi`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`%B = phi i32 [ %X, %BB0 ], [ %Y, %BB1 ]`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`ret i32 %B`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`; CHECK: @test6`
			`; CHECK: BB2:`
			`; CHECK: zext i16 %A to i32`
			`; CHECK-NEXT: ret i32`
New testcase: the phi can be eliminated if the casts are sucked into it. Note that this reduces code size anyway (as well as making further optimizations simpler) so it's always a win. llvm-svn: 17739 2004-11-14 20:12:17 +01:00			`}`

Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`define i32 @test7(i32 %A, i1 %b) {`
			`BB0:`
			`br label %Loop`

			`Loop: ; preds = %Loop, %BB0`
			`; PHI is dead.`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`%B = phi i32 [ %A, %BB0 ], [ %C, %Loop ]`
			`%C = add i32 %B, 123`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`br i1 %b, label %Loop, label %Exit`
new testcase llvm-svn: 33233 2007-01-15 08:29:29 +01:00
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00			`Exit: ; preds = %Loop`
			`ret i32 0`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`; CHECK: @test7`
			`; CHECK: Loop:`
			`; CHECK-NEXT: br i1 %b`
new testcase llvm-svn: 33233 2007-01-15 08:29:29 +01:00			`}`

Teach inst combine to merge GEPs through PHIs. This is really important because it is sinking the loads using the GEPs, but not the GEPs themselves. This triggers 647 times on 403.gcc and makes the .s file much much nicer. For example before: je LBB1_87 ## bb78 LBB1_62: ## bb77 leal 84(%esi), %eax LBB1_63: ## bb79 movl (%eax), %eax ... LBB1_87: ## bb78 movl $0, 4(%esp) movl %esi, (%esp) call L_make_decl_rtl$stub jmp LBB1_62 ## bb77 after: jne LBB1_63 ## bb79 LBB1_62: ## bb78 movl $0, 4(%esp) movl %esi, (%esp) call L_make_decl_rtl$stub LBB1_63: ## bb79 movl 84(%esi), %eax The input code was (and the GEPs are merged and the PHI is now eliminated by instcombine): br i1 %tmp233, label %bb78, label %bb77 bb77: %tmp234 = getelementptr %struct.tree_node* %t_addr.3, i32 0, i32 0, i32 22 br label %bb79 bb78: call void @make_decl_rtl(%struct.tree_node* %t_addr.3, i8* null) nounwind %tmp235 = getelementptr %struct.tree_node* %t_addr.3, i32 0, i32 0, i32 22 br label %bb79 bb79: %iftmp.12.0.in = phi %struct.rtx_def [ %tmp235, %bb78 ], [ %tmp234, %bb77 ] %iftmp.12.0 = load %struct.rtx_def %iftmp.12.0.in llvm-svn: 60322 2008-12-01 03:34:36 +01:00			`define i32* @test8({ i32, i32 } *%A, i1 %b) {`
			`BB0:`
			`%X = getelementptr { i32, i32 } *%A, i32 0, i32 1`
			`br i1 %b, label %BB1, label %BB2`

			`BB1:`
			`%Y = getelementptr { i32, i32 } *%A, i32 0, i32 1`
			`br label %BB2`

			`BB2:`
			`;; Suck GEPs into phi`
			`%B = phi i32* [ %X, %BB0 ], [ %Y, %BB1 ]`
			`ret i32* %B`
convert to filecheck. llvm-svn: 85734 2009-11-01 20:22:20 +01:00			`; CHECK: @test8`
			`; CHECK-NOT: phi`
			`; CHECK: BB2:`
			`; CHECK-NEXT: %B = getelementptr`
			`; CHECK-NEXT: ret i32* %B`
Teach inst combine to merge GEPs through PHIs. This is really important because it is sinking the loads using the GEPs, but not the GEPs themselves. This triggers 647 times on 403.gcc and makes the .s file much much nicer. For example before: je LBB1_87 ## bb78 LBB1_62: ## bb77 leal 84(%esi), %eax LBB1_63: ## bb79 movl (%eax), %eax ... LBB1_87: ## bb78 movl $0, 4(%esp) movl %esi, (%esp) call L_make_decl_rtl$stub jmp LBB1_62 ## bb77 after: jne LBB1_63 ## bb79 LBB1_62: ## bb78 movl $0, 4(%esp) movl %esi, (%esp) call L_make_decl_rtl$stub LBB1_63: ## bb79 movl 84(%esi), %eax The input code was (and the GEPs are merged and the PHI is now eliminated by instcombine): br i1 %tmp233, label %bb78, label %bb77 bb77: %tmp234 = getelementptr %struct.tree_node* %t_addr.3, i32 0, i32 0, i32 22 br label %bb79 bb78: call void @make_decl_rtl(%struct.tree_node* %t_addr.3, i8* null) nounwind %tmp235 = getelementptr %struct.tree_node* %t_addr.3, i32 0, i32 0, i32 22 br label %bb79 bb79: %iftmp.12.0.in = phi %struct.rtx_def [ %tmp235, %bb78 ], [ %tmp234, %bb77 ] %iftmp.12.0 = load %struct.rtx_def %iftmp.12.0.in llvm-svn: 60322 2008-12-01 03:34:36 +01:00			`}`

fix a bug noticed by inspection: when instcombine sinks loads through phis, it didn't preserve the alignment of the load. This is a missed optimization of the alignment is high and a miscompilation when the alignment is low. llvm-svn: 85736 2009-11-01 20:50:13 +01:00			`define i32 @test9(i32* %A, i32* %B) {`
			`entry:`
			`%c = icmp eq i32* %A, null`
			`br i1 %c, label %bb1, label %bb`

			`bb:`
			`%C = load i32* %B, align 1`
			`br label %bb2`

			`bb1:`
			`%D = load i32* %A, align 1`
			`br label %bb2`

			`bb2:`
			`%E = phi i32 [ %C, %bb ], [ %D, %bb1 ]`
			`ret i32 %E`
when merging two loads, make sure to take the min of their alignment, not the max. This didn't matter until the previous patch because instcombine would refuse to sink loads with differenting alignments. llvm-svn: 85738 2009-11-01 21:07:07 +01:00			`; CHECK: @test9`
fix a bug noticed by inspection: when instcombine sinks loads through phis, it didn't preserve the alignment of the load. This is a missed optimization of the alignment is high and a miscompilation when the alignment is low. llvm-svn: 85736 2009-11-01 20:50:13 +01:00			`; CHECK: bb2:`
			`; CHECK-NEXT: phi i32* [ %B, %bb ], [ %A, %bb1 ]`
			`; CHECK-NEXT: %E = load i32* %{{[^,]*}}, align 1`
			`; CHECK-NEXT: ret i32 %E`
Remove llvm-upgrade and update test cases. llvm-svn: 47793 2008-03-01 10:15:35 +01:00
fix a bug noticed by inspection: when instcombine sinks loads through phis, it didn't preserve the alignment of the load. This is a missed optimization of the alignment is high and a miscompilation when the alignment is low. llvm-svn: 85736 2009-11-01 20:50:13 +01:00			`}`
when merging two loads, make sure to take the min of their alignment, not the max. This didn't matter until the previous patch because instcombine would refuse to sink loads with differenting alignments. llvm-svn: 85738 2009-11-01 21:07:07 +01:00
			`define i32 @test10(i32* %A, i32* %B) {`
			`entry:`
			`%c = icmp eq i32* %A, null`
			`br i1 %c, label %bb1, label %bb`

			`bb:`
			`%C = load i32* %B, align 16`
			`br label %bb2`

			`bb1:`
			`%D = load i32* %A, align 32`
			`br label %bb2`

			`bb2:`
			`%E = phi i32 [ %C, %bb ], [ %D, %bb1 ]`
			`ret i32 %E`
			`; CHECK: @test10`
			`; CHECK: bb2:`
			`; CHECK-NEXT: phi i32* [ %B, %bb ], [ %A, %bb1 ]`
			`; CHECK-NEXT: %E = load i32* %{{[^,]*}}, align 16`
			`; CHECK-NEXT: ret i32 %E`
merge phi-merge.ll into phi.ll I don't know what Dan wants to do with phi-merge-gep.ll, I'll let him deal with it because instcombine may end up sinking these. llvm-svn: 85739 2009-11-01 21:10:11 +01:00			`}`

when merging two loads, make sure to take the min of their alignment, not the max. This didn't matter until the previous patch because instcombine would refuse to sink loads with differenting alignments. llvm-svn: 85738 2009-11-01 21:07:07 +01:00
merge phi-merge.ll into phi.ll I don't know what Dan wants to do with phi-merge-gep.ll, I'll let him deal with it because instcombine may end up sinking these. llvm-svn: 85739 2009-11-01 21:10:11 +01:00			`; PR1777`
			`declare i1 @test11a()`

			`define i1 @test11() {`
			`entry:`
			`%a = alloca i32`
			`%i = ptrtoint i32* %a to i32`
			`%b = call i1 @test11a()`
			`br i1 %b, label %one, label %two`

			`one:`
			`%x = phi i32 [%i, %entry], [%y, %two]`
			`%c = call i1 @test11a()`
			`br i1 %c, label %two, label %end`

			`two:`
			`%y = phi i32 [%i, %entry], [%x, %one]`
			`%d = call i1 @test11a()`
			`br i1 %d, label %one, label %end`

			`end:`
			`%f = phi i32 [ %x, %one], [%y, %two]`
			`; Change the %f to %i, and the optimizer suddenly becomes a lot smarter`
			`; even though %f must equal %i at this point`
			`%g = inttoptr i32 %f to i32*`
			`store i32 10, i32* %g`
			`%z = call i1 @test11a()`
			`ret i1 %z`
			`; CHECK: @test11`
			`; CHECK-NOT: phi i32`
			`; CHECK: ret i1 %z`
when merging two loads, make sure to take the min of their alignment, not the max. This didn't matter until the previous patch because instcombine would refuse to sink loads with differenting alignments. llvm-svn: 85738 2009-11-01 21:07:07 +01:00			`}`

reapply r8644[3-5] with only the scary part (SliceUpIllegalIntegerPHI) disabled. llvm-svn: 86480 2009-11-08 20:23:30 +01:00
			`define i64 @test12(i1 %cond, i8* %Ptr, i64 %Val) {`
			`entry:`
			`%tmp41 = ptrtoint i8* %Ptr to i64`
			`%tmp42 = zext i64 %tmp41 to i128`
			`br i1 %cond, label %end, label %two`

			`two:`
			`%tmp36 = zext i64 %Val to i128 ; <i128> [#uses=1]`
			`%tmp37 = shl i128 %tmp36, 64 ; <i128> [#uses=1]`
			`%ins39 = or i128 %tmp42, %tmp37 ; <i128> [#uses=1]`
			`br label %end`

			`end:`
			`%tmp869.0 = phi i128 [ %tmp42, %entry ], [ %ins39, %two ]`
			`%tmp32 = trunc i128 %tmp869.0 to i64 ; <i64> [#uses=1]`
			`%tmp29 = lshr i128 %tmp869.0, 64 ; <i128> [#uses=1]`
			`%tmp30 = trunc i128 %tmp29 to i64 ; <i64> [#uses=1]`

			`%tmp2 = add i64 %tmp32, %tmp30`
			`ret i64 %tmp2`
Teach an instcombine to not pull trunc instructions through PHI nodes when both the source and dest are illegal types, since it would cause the phi to grow (for example, we shouldn't transform test14b's phi to a phi on i320). This fixes an infinite loop on i686 bootstrap with phi slicing turned on, so turn it back on. llvm-svn: 86483 2009-11-08 22:20:06 +01:00			`; CHECK: @test12`
			`; CHECK-NOT: zext`
			`; CHECK: end:`
			`; CHECK-NEXT: phi i64 [ 0, %entry ], [ %Val, %two ]`
			`; CHECK-NOT: phi`
			`; CHECK: ret i64`
reapply r8644[3-5] with only the scary part (SliceUpIllegalIntegerPHI) disabled. llvm-svn: 86480 2009-11-08 20:23:30 +01:00			`}`

			`declare void @test13f(double, i32)`

			`define void @test13(i1 %cond, i32 %V1, double %Vald) {`
			`entry:`
			`%tmp42 = zext i32 %V1 to i128`
			`br i1 %cond, label %end, label %two`

			`two:`
			`%Val = bitcast double %Vald to i64`
			`%tmp36 = zext i64 %Val to i128 ; <i128> [#uses=1]`
			`%tmp37 = shl i128 %tmp36, 64 ; <i128> [#uses=1]`
			`%ins39 = or i128 %tmp42, %tmp37 ; <i128> [#uses=1]`
			`br label %end`

			`end:`
			`%tmp869.0 = phi i128 [ %tmp42, %entry ], [ %ins39, %two ]`
			`%tmp32 = trunc i128 %tmp869.0 to i32`
			`%tmp29 = lshr i128 %tmp869.0, 64 ; <i128> [#uses=1]`
			`%tmp30 = trunc i128 %tmp29 to i64 ; <i64> [#uses=1]`
			`%tmp31 = bitcast i64 %tmp30 to double`

			`call void @test13f(double %tmp31, i32 %tmp32)`
			`ret void`
Teach an instcombine to not pull trunc instructions through PHI nodes when both the source and dest are illegal types, since it would cause the phi to grow (for example, we shouldn't transform test14b's phi to a phi on i320). This fixes an infinite loop on i686 bootstrap with phi slicing turned on, so turn it back on. llvm-svn: 86483 2009-11-08 22:20:06 +01:00			`; CHECK: @test13`
			`; CHECK-NOT: zext`
			`; CHECK: end:`
			`; CHECK-NEXT: phi double [ 0.000000e+00, %entry ], [ %Vald, %two ]`
			`; CHECK-NEXT: call void @test13f(double {{[^,]*}}, i32 %V1)`
			`; CHECK: ret void`
			`}`

			`define i640 @test14a(i320 %A, i320 %B, i1 %b1) {`
			`BB0:`
			`%a = zext i320 %A to i640`
			`%b = zext i320 %B to i640`
			`br label %Loop`

			`Loop:`
			`%C = phi i640 [ %a, %BB0 ], [ %b, %Loop ]`
			`br i1 %b1, label %Loop, label %Exit`

			`Exit: ; preds = %Loop`
			`ret i640 %C`
			`; CHECK: @test14a`
			`; CHECK: Loop:`
			`; CHECK-NEXT: phi i320`
reapply r8644[3-5] with only the scary part (SliceUpIllegalIntegerPHI) disabled. llvm-svn: 86480 2009-11-08 20:23:30 +01:00			`}`

Teach an instcombine to not pull trunc instructions through PHI nodes when both the source and dest are illegal types, since it would cause the phi to grow (for example, we shouldn't transform test14b's phi to a phi on i320). This fixes an infinite loop on i686 bootstrap with phi slicing turned on, so turn it back on. llvm-svn: 86483 2009-11-08 22:20:06 +01:00			`define i160 @test14b(i320 %A, i320 %B, i1 %b1) {`
			`BB0:`
			`%a = trunc i320 %A to i160`
			`%b = trunc i320 %B to i160`
			`br label %Loop`

			`Loop:`
			`%C = phi i160 [ %a, %BB0 ], [ %b, %Loop ]`
			`br i1 %b1, label %Loop, label %Exit`

			`Exit: ; preds = %Loop`
			`ret i160 %C`
			`; CHECK: @test14b`
			`; CHECK: Loop:`
			`; CHECK-NEXT: phi i160`
			`}`
enhance PHI slicing to handle the case when a slicable PHI is begin used by a chain of other PHIs. llvm-svn: 86503 2009-11-09 02:38:00 +01:00
			`declare i64 @test15a(i64)`

			`define i64 @test15b(i64 %A, i1 %b) {`
			`; CHECK: @test15b`
			`entry:`
			`%i0 = zext i64 %A to i128`
			`%i1 = shl i128 %i0, 64`
			`%i = or i128 %i1, %i0`
			`br i1 %b, label %one, label %two`
			`; CHECK: entry:`
			`; CHECK-NEXT: br i1 %b`

			`one:`
			`%x = phi i128 [%i, %entry], [%y, %two]`
			`%x1 = lshr i128 %x, 64`
			`%x2 = trunc i128 %x1 to i64`
			`%c = call i64 @test15a(i64 %x2)`
			`%c1 = zext i64 %c to i128`
			`br label %two`

			`; CHECK: one:`
			`; CHECK-NEXT: phi i64`
			`; CHECK-NEXT: %c = call i64 @test15a`

			`two:`
			`%y = phi i128 [%i, %entry], [%c1, %one]`
			`%y1 = lshr i128 %y, 64`
			`%y2 = trunc i128 %y1 to i64`
			`%d = call i64 @test15a(i64 %y2)`
			`%d1 = trunc i64 %d to i1`
			`br i1 %d1, label %one, label %end`

			`; CHECK: two:`
			`; CHECK-NEXT: phi i64`
			`; CHECK-NEXT: phi i64`
			`; CHECK-NEXT: %d = call i64 @test15a`

			`end:`
			`%g = trunc i128 %y to i64`
			`ret i64 %g`
			`; CHECK: end:`
			`; CHECK-NEXT: ret i64`
			`}`