blob: b07ec03d7d67de0102e1debca8b6dfe71f70e8e1 [file] [log] [blame]
; RUN: opt < %s -inline -inline-threshold=20 -S | FileCheck %s
; RUN: opt < %s -passes='cgscc(inline)' -inline-threshold=20 -S | FileCheck %s
define internal i32 @callee1(i32 %A, i32 %B) {
%C = sdiv i32 %A, %B
ret i32 %C
}
define i32 @caller1() {
; CHECK-LABEL: define i32 @caller1(
; CHECK-NEXT: ret i32 3
%X = call i32 @callee1( i32 10, i32 3 )
ret i32 %X
}
define i32 @caller2() {
; Check that we can constant-prop through instructions after inlining callee21
; to get constants in the inlined callsite to callee22.
; FIXME: Currently, the threshold is fixed at 20 because we don't perform
; *recursive* cost analysis to realize that the nested call site will definitely
; inline and be cheap. We should eventually do that and lower the threshold here
; to 1.
;
; CHECK-LABEL: @caller2(
; CHECK-NOT: call void @callee2
; CHECK: ret
%x = call i32 @callee21(i32 42, i32 48)
ret i32 %x
}
define i32 @callee21(i32 %x, i32 %y) {
%sub = sub i32 %y, %x
%result = call i32 @callee22(i32 %sub)
ret i32 %result
}
declare i8* @getptr()
define i32 @callee22(i32 %x) {
%icmp = icmp ugt i32 %x, 42
br i1 %icmp, label %bb.true, label %bb.false
bb.true:
; This block musn't be counted in the inline cost.
%x1 = add i32 %x, 1
%x2 = add i32 %x1, 1
%x3 = add i32 %x2, 1
%x4 = add i32 %x3, 1
%x5 = add i32 %x4, 1
%x6 = add i32 %x5, 1
%x7 = add i32 %x6, 1
%x8 = add i32 %x7, 1
ret i32 %x8
bb.false:
ret i32 %x
}
define i32 @caller3() {
; Check that even if the expensive path is hidden behind several basic blocks,
; it doesn't count toward the inline cost when constant-prop proves those paths
; dead.
;
; CHECK-LABEL: @caller3(
; CHECK-NOT: call
; CHECK: ret i32 6
entry:
%x = call i32 @callee3(i32 42, i32 48)
ret i32 %x
}
define i32 @callee3(i32 %x, i32 %y) {
%sub = sub i32 %y, %x
%icmp = icmp ugt i32 %sub, 42
br i1 %icmp, label %bb.true, label %bb.false
bb.true:
%icmp2 = icmp ult i32 %sub, 64
br i1 %icmp2, label %bb.true.true, label %bb.true.false
bb.true.true:
; This block musn't be counted in the inline cost.
%x1 = add i32 %x, 1
%x2 = add i32 %x1, 1
%x3 = add i32 %x2, 1
%x4 = add i32 %x3, 1
%x5 = add i32 %x4, 1
%x6 = add i32 %x5, 1
%x7 = add i32 %x6, 1
%x8 = add i32 %x7, 1
br label %bb.merge
bb.true.false:
; This block musn't be counted in the inline cost.
%y1 = add i32 %y, 1
%y2 = add i32 %y1, 1
%y3 = add i32 %y2, 1
%y4 = add i32 %y3, 1
%y5 = add i32 %y4, 1
%y6 = add i32 %y5, 1
%y7 = add i32 %y6, 1
%y8 = add i32 %y7, 1
br label %bb.merge
bb.merge:
%result = phi i32 [ %x8, %bb.true.true ], [ %y8, %bb.true.false ]
ret i32 %result
bb.false:
ret i32 %sub
}
declare {i8, i1} @llvm.uadd.with.overflow.i8(i8 %a, i8 %b)
define i8 @caller4(i8 %z) {
; Check that we can constant fold through intrinsics such as the
; overflow-detecting arithmetic instrinsics. These are particularly important
; as they are used heavily in standard library code and generic C++ code where
; the arguments are oftent constant but complete generality is required.
;
; CHECK-LABEL: @caller4(
; CHECK-NOT: call
; CHECK: ret i8 -1
entry:
%x = call i8 @callee4(i8 254, i8 14, i8 %z)
ret i8 %x
}
define i8 @callee4(i8 %x, i8 %y, i8 %z) {
%uadd = call {i8, i1} @llvm.uadd.with.overflow.i8(i8 %x, i8 %y)
%o = extractvalue {i8, i1} %uadd, 1
br i1 %o, label %bb.true, label %bb.false
bb.true:
ret i8 -1
bb.false:
; This block musn't be counted in the inline cost.
%z1 = add i8 %z, 1
%z2 = add i8 %z1, 1
%z3 = add i8 %z2, 1
%z4 = add i8 %z3, 1
%z5 = add i8 %z4, 1
%z6 = add i8 %z5, 1
%z7 = add i8 %z6, 1
%z8 = add i8 %z7, 1
ret i8 %z8
}
define i64 @caller5(i64 %y) {
; Check that we can round trip constants through various kinds of casts etc w/o
; losing track of the constant prop in the inline cost analysis.
;
; CHECK-LABEL: @caller5(
; CHECK-NOT: call
; CHECK: ret i64 -1
entry:
%x = call i64 @callee5(i64 42, i64 %y)
ret i64 %x
}
define i64 @callee5(i64 %x, i64 %y) {
%inttoptr = inttoptr i64 %x to i8*
%bitcast = bitcast i8* %inttoptr to i32*
%ptrtoint = ptrtoint i32* %bitcast to i64
%trunc = trunc i64 %ptrtoint to i32
%zext = zext i32 %trunc to i64
%cmp = icmp eq i64 %zext, 42
br i1 %cmp, label %bb.true, label %bb.false
bb.true:
ret i64 -1
bb.false:
; This block musn't be counted in the inline cost.
%y1 = add i64 %y, 1
%y2 = add i64 %y1, 1
%y3 = add i64 %y2, 1
%y4 = add i64 %y3, 1
%y5 = add i64 %y4, 1
%y6 = add i64 %y5, 1
%y7 = add i64 %y6, 1
%y8 = add i64 %y7, 1
ret i64 %y8
}
define float @caller6() {
; Check that we can constant-prop through fcmp instructions
;
; CHECK-LABEL: @caller6(
; CHECK-NOT: call
; CHECK: ret
%x = call float @callee6(float 42.0)
ret float %x
}
define float @callee6(float %x) {
%icmp = fcmp ugt float %x, 42.0
br i1 %icmp, label %bb.true, label %bb.false
bb.true:
; This block musn't be counted in the inline cost.
%x1 = fadd float %x, 1.0
%x2 = fadd float %x1, 1.0
%x3 = fadd float %x2, 1.0
%x4 = fadd float %x3, 1.0
%x5 = fadd float %x4, 1.0
%x6 = fadd float %x5, 1.0
%x7 = fadd float %x6, 1.0
%x8 = fadd float %x7, 1.0
ret float %x8
bb.false:
ret float %x
}
define i32 @PR13412.main() {
; This is a somewhat complicated three layer subprogram that was reported to
; compute the wrong value for a branch due to assuming that an argument
; mid-inline couldn't be equal to another pointer.
;
; After inlining, the branch should point directly to the exit block, not to
; the intermediate block.
; CHECK: @PR13412.main
; CHECK: br i1 true, label %[[TRUE_DEST:.*]], label %[[FALSE_DEST:.*]]
; CHECK: [[FALSE_DEST]]:
; CHECK-NEXT: call void @PR13412.fail()
; CHECK: [[TRUE_DEST]]:
; CHECK-NEXT: ret i32 0
entry:
%i1 = alloca i64
store i64 0, i64* %i1
%arraydecay = bitcast i64* %i1 to i32*
%call = call i1 @PR13412.first(i32* %arraydecay, i32* %arraydecay)
br i1 %call, label %cond.end, label %cond.false
cond.false:
call void @PR13412.fail()
br label %cond.end
cond.end:
ret i32 0
}
define internal i1 @PR13412.first(i32* %a, i32* %b) {
entry:
%call = call i32* @PR13412.second(i32* %a, i32* %b)
%cmp = icmp eq i32* %call, %b
ret i1 %cmp
}
declare void @PR13412.fail()
define internal i32* @PR13412.second(i32* %a, i32* %b) {
entry:
%sub.ptr.lhs.cast = ptrtoint i32* %b to i64
%sub.ptr.rhs.cast = ptrtoint i32* %a to i64
%sub.ptr.sub = sub i64 %sub.ptr.lhs.cast, %sub.ptr.rhs.cast
%sub.ptr.div = ashr exact i64 %sub.ptr.sub, 2
%cmp = icmp ugt i64 %sub.ptr.div, 1
br i1 %cmp, label %if.then, label %if.end3
if.then:
%0 = load i32, i32* %a
%1 = load i32, i32* %b
%cmp1 = icmp eq i32 %0, %1
br i1 %cmp1, label %return, label %if.end3
if.end3:
br label %return
return:
%retval.0 = phi i32* [ %b, %if.end3 ], [ %a, %if.then ]
ret i32* %retval.0
}
declare i32 @PR28802.external(i32 returned %p1)
define internal i32 @PR28802.callee() {
entry:
br label %cont
cont:
%0 = phi i32 [ 0, %entry ]
%call = call i32 @PR28802.external(i32 %0)
ret i32 %call
}
define i32 @PR28802() {
entry:
%call = call i32 @PR28802.callee()
ret i32 %call
}
; CHECK-LABEL: define i32 @PR28802(
; CHECK: %[[call:.*]] = call i32 @PR28802.external(i32 0)
; CHECK: ret i32 %[[call]]
define internal i32 @PR28848.callee(i32 %p2, i1 %c) {
entry:
br i1 %c, label %cond.end, label %cond.true
cond.true:
br label %cond.end
cond.end:
%cond = phi i32 [ 0, %cond.true ], [ %p2, %entry ]
%or = or i32 %cond, %p2
ret i32 %or
}
define i32 @PR28848() {
entry:
%call = call i32 @PR28848.callee(i32 0, i1 false)
ret i32 %call
}
; CHECK-LABEL: define i32 @PR28848(
; CHECK: ret i32 0
define internal void @callee7(i16 %param1, i16 %param2) {
entry:
br label %bb
bb:
%phi = phi i16 [ %param2, %entry ]
%add = add i16 %phi, %param1
ret void
}
declare i16 @caller7.external(i16 returned)
define void @caller7() {
bb1:
%call = call i16 @caller7.external(i16 1)
call void @callee7(i16 0, i16 %call)
ret void
}
; CHECK-LABEL: define void @caller7(
; CHECK: %call = call i16 @caller7.external(i16 1)
; CHECK-NEXT: ret void