llvm-project/polly/test/ForwardOpTree/forward_load_tripleuse.ll

160 lines
5.9 KiB
LLVM

; RUN: opt %loadPolly -polly-stmt-granularity=bb -polly-print-optree -polly-codegen -disable-output < %s | FileCheck %s -match-full-lines
;
; %val1 is used three times: Twice by its own operand tree of %val2 and once
; more by the store in %bodyB.
; Verify that we can handle multiple uses by the same instruction and uses
; in multiple statements as well.
; The result processing may depend on the order in which the values are used,
; hence we check both orderings.
;
; for (int j = 0; j < n; j += 1) {
; bodyA:
; double val1 = A[j];
; double val2 = val1 + val1;
;
; bodyB:
; B[j] = val1;
; C[j] = val2;
; }
;
define void @func1(i32 %n, double* noalias nonnull %A, double* noalias nonnull %B, double* noalias nonnull %C) {
entry:
br label %for
for:
%j = phi i32 [0, %entry], [%j.inc, %inc]
%j.cmp = icmp slt i32 %j, %n
br i1 %j.cmp, label %bodyA, label %exit
bodyA:
%A_idx = getelementptr inbounds double, double* %A, i32 %j
%val1 = load double, double* %A_idx
%val2 = fadd double %val1, %val1
br label %bodyB
bodyB:
%B_idx = getelementptr inbounds double, double* %B, i32 %j
store double %val1, double* %B_idx
%C_idx = getelementptr inbounds double, double* %C, i32 %j
store double %val2, double* %C_idx
br label %inc
inc:
%j.inc = add nuw nsw i32 %j, 1
br label %for
exit:
br label %return
return:
ret void
}
; CHECK: Statistics {
; CHECK: Instructions copied: 1
; CHECK: Known loads forwarded: 2
; CHECK: Operand trees forwarded: 2
; CHECK: Statements with forwarded operand trees: 1
; CHECK: }
; CHECK: After statements {
; CHECK-NEXT: Stmt_bodyA
; CHECK-NEXT: ReadAccess := [Reduction Type: NONE] [Scalar: 0]
; CHECK-NEXT: [n] -> { Stmt_bodyA[i0] -> MemRef_A[i0] };
; CHECK-NEXT: MustWriteAccess := [Reduction Type: NONE] [Scalar: 1]
; CHECK-NEXT: [n] -> { Stmt_bodyA[i0] -> MemRef_val1[] };
; CHECK-NEXT: MustWriteAccess := [Reduction Type: NONE] [Scalar: 1]
; CHECK-NEXT: [n] -> { Stmt_bodyA[i0] -> MemRef_val2[] };
; CHECK-NEXT: Instructions {
; CHECK-NEXT: %val1 = load double, double* %A_idx, align 8
; CHECK-NEXT: %val2 = fadd double %val1, %val1
; CHECK-NEXT: }
; CHECK-NEXT: Stmt_bodyB
; CHECK-NEXT: ReadAccess := [Reduction Type: NONE] [Scalar: 0]
; CHECK-NEXT: ;
; CHECK-NEXT: new: [n] -> { Stmt_bodyB[i0] -> MemRef_A[i0] };
; CHECK-NEXT: MustWriteAccess := [Reduction Type: NONE] [Scalar: 0]
; CHECK-NEXT: [n] -> { Stmt_bodyB[i0] -> MemRef_B[i0] };
; CHECK-NEXT: MustWriteAccess := [Reduction Type: NONE] [Scalar: 0]
; CHECK-NEXT: [n] -> { Stmt_bodyB[i0] -> MemRef_C[i0] };
; CHECK-NEXT: Instructions {
; CHECK-NEXT: %val1 = load double, double* %A_idx, align 8
; CHECK-NEXT: %val2 = fadd double %val1, %val1
; CHECK-NEXT: %val1 = load double, double* %A_idx, align 8
; CHECK-NEXT: store double %val1, double* %B_idx, align 8
; CHECK-NEXT: store double %val2, double* %C_idx, align 8
; CHECK-NEXT: }
; CHECK-NEXT: }
define void @func2(i32 %n, double* noalias nonnull %A, double* noalias nonnull %B, double* noalias nonnull %C) {
entry:
br label %for
for:
%j = phi i32 [0, %entry], [%j.inc, %inc]
%j.cmp = icmp slt i32 %j, %n
br i1 %j.cmp, label %bodyA, label %exit
bodyA:
%A_idx = getelementptr inbounds double, double* %A, i32 %j
%val1 = load double, double* %A_idx
%val2 = fadd double %val1, %val1
br label %bodyB
bodyB:
%B_idx = getelementptr inbounds double, double* %B, i32 %j
store double %val2, double* %B_idx
%C_idx = getelementptr inbounds double, double* %C, i32 %j
store double %val1, double* %C_idx
br label %inc
inc:
%j.inc = add nuw nsw i32 %j, 1
br label %for
exit:
br label %return
return:
ret void
}
; CHECK: Statistics {
; CHECK: Instructions copied: 1
; CHECK: Known loads forwarded: 2
; CHECK: Operand trees forwarded: 2
; CHECK: Statements with forwarded operand trees: 1
; CHECK: }
; CHECK: After statements {
; CHECK-NEXT: Stmt_bodyA
; CHECK-NEXT: ReadAccess := [Reduction Type: NONE] [Scalar: 0]
; CHECK-NEXT: [n] -> { Stmt_bodyA[i0] -> MemRef_A[i0] };
; CHECK-NEXT: MustWriteAccess := [Reduction Type: NONE] [Scalar: 1]
; CHECK-NEXT: [n] -> { Stmt_bodyA[i0] -> MemRef_val2[] };
; CHECK-NEXT: MustWriteAccess := [Reduction Type: NONE] [Scalar: 1]
; CHECK-NEXT: [n] -> { Stmt_bodyA[i0] -> MemRef_val1[] };
; CHECK-NEXT: Instructions {
; CHECK-NEXT: %val1 = load double, double* %A_idx, align 8
; CHECK-NEXT: %val2 = fadd double %val1, %val1
; CHECK-NEXT: }
; CHECK-NEXT: Stmt_bodyB
; CHECK-NEXT: ReadAccess := [Reduction Type: NONE] [Scalar: 0]
; CHECK-NEXT: ;
; CHECK-NEXT: new: [n] -> { Stmt_bodyB[i0] -> MemRef_A[i0] };
; CHECK-NEXT: MustWriteAccess := [Reduction Type: NONE] [Scalar: 0]
; CHECK-NEXT: [n] -> { Stmt_bodyB[i0] -> MemRef_B[i0] };
; CHECK-NEXT: MustWriteAccess := [Reduction Type: NONE] [Scalar: 0]
; CHECK-NEXT: [n] -> { Stmt_bodyB[i0] -> MemRef_C[i0] };
; CHECK-NEXT: Instructions {
; CHECK-NEXT: %val1 = load double, double* %A_idx, align 8
; CHECK-NEXT: %val1 = load double, double* %A_idx, align 8
; CHECK-NEXT: %val2 = fadd double %val1, %val1
; CHECK-NEXT: store double %val2, double* %B_idx, align 8
; CHECK-NEXT: store double %val1, double* %C_idx, align 8
; CHECK-NEXT: }
; CHECK-NEXT: }