polly/test/ScopInfo/multidim_single_and_multidim_array.ll - llvm-project - Git at Google

 ; RUN: opt %loadPolly -polly-scops -polly-delinearize=false -analyze < %s | FileCheck %s
 ; RUN: opt %loadPolly -polly-scops -polly-delinearize=false -polly-allow-nonaffine -analyze < %s | FileCheck %s --check-prefix=NONAFFINE
 ; RUN: opt %loadPolly -polly-scops -analyze < %s | FileCheck %s --check-prefix=DELIN
 ; RUN: opt %loadPolly -polly-scops -polly-allow-nonaffine -analyze < %s | FileCheck %s --check-prefix=DELIN
 ; RUN: opt %loadPolly -polly-function-scops -polly-delinearize=false -analyze < %s | FileCheck %s
 ; RUN: opt %loadPolly -polly-function-scops -polly-delinearize=false -polly-allow-nonaffine -analyze < %s | FileCheck %s --check-prefix=NONAFFINE
 ; RUN: opt %loadPolly -polly-function-scops -analyze < %s | FileCheck %s --check-prefix=DELIN
 ; RUN: opt %loadPolly -polly-function-scops -polly-allow-nonaffine -analyze < %s | FileCheck %s --check-prefix=DELIN

 target datalayout = "e-m:e-i64:64-f80:128-n8:16:32:64-S128"

 ; void single-and-multi-dimensional-array(long n,float X[n][n]) {
 ;  for (long i1 = 0; i1 < n; i1++)
 ;    X[i1][0] = 1;
 ;
 ;  for (long i2 = 0; i2 < n; i2++)
 ;    X[n-1][i2] = 1;
 ; }
 ;
 ; In previous versions of Polly, the second access was detected as single
 ; dimensional access whereas the first one was detected as multi-dimensional.
 ; This test case checks that we now consistently delinearize the array accesses.

 ; CHECK-NOT: Stmt_for_i_1

 ; NONAFFINE:      p0: %n
 ; NONAFFINE-NEXT: p1: ((-1 + %n) * %n)
 ;
 ; NONAFFINE:      Statements {
 ; NONAFFINE-NEXT:     Stmt_for_i_1
 ; NONAFFINE-NEXT:         Domain :=
 ; NONAFFINE-NEXT:             [n, p_1] -> { Stmt_for_i_1[i0] : 0 <= i0 < n };
 ; NONAFFINE-NEXT:         Schedule :=
 ; NONAFFINE-NEXT:             [n, p_1] -> { Stmt_for_i_1[i0] -> [0, i0] };
 ; NONAFFINE-NEXT:         MayWriteAccess :=    [Reduction Type: NONE] [Scalar: 0]
 ; NONAFFINE-NEXT:             [n, p_1] -> { Stmt_for_i_1[i0] -> MemRef_X[o0] };
 ; NONAFFINE-NEXT:     Stmt_for_i_2
 ; NONAFFINE-NEXT:         Domain :=
 ; NONAFFINE-NEXT:             [n, p_1] -> { Stmt_for_i_2[i0] : 0 <= i0 < n };
 ; NONAFFINE-NEXT:         Schedule :=
 ; NONAFFINE-NEXT:             [n, p_1] -> { Stmt_for_i_2[i0] -> [1, i0] };
 ; NONAFFINE-NEXT:         MustWriteAccess :=    [Reduction Type: NONE] [Scalar: 0]
 ; NONAFFINE-NEXT:             [n, p_1] -> { Stmt_for_i_2[i0] -> MemRef_X[p_1 + i0] };
 ; NONAFFINE-NEXT: }

 ; DELIN:      Statements {
 ; DELIN-NEXT:     Stmt_for_i_1
 ; DELIN-NEXT:         Domain :=
 ; DELIN-NEXT:             [n] -> { Stmt_for_i_1[i0] : 0 <= i0 < n };
 ; DELIN-NEXT:         Schedule :=
 ; DELIN-NEXT:             [n] -> { Stmt_for_i_1[i0] -> [0, i0] };
 ; DELIN-NEXT:         MustWriteAccess :=    [Reduction Type: NONE] [Scalar: 0]
 ; DELIN-NEXT:             [n] -> { Stmt_for_i_1[i0] -> MemRef_X[i0, 0] };
 ; DELIN-NEXT:     Stmt_for_i_2
 ; DELIN-NEXT:         Domain :=
 ; DELIN-NEXT:             [n] -> { Stmt_for_i_2[i0] : 0 <= i0 < n };
 ; DELIN-NEXT:         Schedule :=
 ; DELIN-NEXT:             [n] -> { Stmt_for_i_2[i0] -> [1, i0] };
 ; DELIN-NEXT:         MustWriteAccess :=    [Reduction Type: NONE] [Scalar: 0]
 ; DELIN-NEXT:             [n] -> { Stmt_for_i_2[i0] -> MemRef_X[-1 + n, i0] };
 ; DELIN-NEXT: }

 define void @single-and-multi-dimensional-array(i64 %n, float* %X) {
 entry:
   br label %for.i.1

 for.i.1:
   %indvar.1 = phi i64 [ 0, %entry ], [ %indvar.next.1, %for.i.1 ]
   %offset.1 = mul i64 %n, %indvar.1
   %arrayidx.1 = getelementptr float, float* %X, i64 %offset.1
   store float 1.000000e+00, float* %arrayidx.1
   %indvar.next.1 = add nsw i64 %indvar.1, 1
   %exitcond.1 = icmp ne i64 %indvar.next.1, %n
   br i1 %exitcond.1, label %for.i.1, label %next

 next:
   br label %for.i.2

 for.i.2:
   %indvar.2 = phi i64 [ 0, %next ], [ %indvar.next.2, %for.i.2 ]
   %offset.2.a = add i64 %n, -1
   %offset.2.b = mul i64 %n, %offset.2.a
   %offset.2.c = add i64 %offset.2.b, %indvar.2
   %arrayidx.2 = getelementptr float, float* %X, i64 %offset.2.c
   store float 1.000000e+00, float* %arrayidx.2
   %indvar.next.2 = add nsw i64 %indvar.2, 1
   %exitcond.2 = icmp ne i64 %indvar.next.2, %n
   br i1 %exitcond.2, label %for.i.2, label %exit

 exit:
   ret void
 }
	; RUN: opt %loadPolly -polly-scops -polly-delinearize=false -analyze < %s \| FileCheck %s
	; RUN: opt %loadPolly -polly-scops -polly-delinearize=false -polly-allow-nonaffine -analyze < %s \| FileCheck %s --check-prefix=NONAFFINE
	; RUN: opt %loadPolly -polly-scops -analyze < %s \| FileCheck %s --check-prefix=DELIN
	; RUN: opt %loadPolly -polly-scops -polly-allow-nonaffine -analyze < %s \| FileCheck %s --check-prefix=DELIN
	; RUN: opt %loadPolly -polly-function-scops -polly-delinearize=false -analyze < %s \| FileCheck %s
	; RUN: opt %loadPolly -polly-function-scops -polly-delinearize=false -polly-allow-nonaffine -analyze < %s \| FileCheck %s --check-prefix=NONAFFINE
	; RUN: opt %loadPolly -polly-function-scops -analyze < %s \| FileCheck %s --check-prefix=DELIN
	; RUN: opt %loadPolly -polly-function-scops -polly-allow-nonaffine -analyze < %s \| FileCheck %s --check-prefix=DELIN

	target datalayout = "e-m:e-i64:64-f80:128-n8:16:32:64-S128"

	; void single-and-multi-dimensional-array(long n,float X[n][n]) {
	; for (long i1 = 0; i1 < n; i1++)
	; X[i1][0] = 1;
	;
	; for (long i2 = 0; i2 < n; i2++)
	; X[n-1][i2] = 1;
	; }
	;
	; In previous versions of Polly, the second access was detected as single
	; dimensional access whereas the first one was detected as multi-dimensional.
	; This test case checks that we now consistently delinearize the array accesses.

	; CHECK-NOT: Stmt_for_i_1

	; NONAFFINE: p0: %n
	; NONAFFINE-NEXT: p1: ((-1 + %n) * %n)
	;
	; NONAFFINE: Statements {
	; NONAFFINE-NEXT: Stmt_for_i_1
	; NONAFFINE-NEXT: Domain :=
	; NONAFFINE-NEXT: [n, p_1] -> { Stmt_for_i_1[i0] : 0 <= i0 < n };
	; NONAFFINE-NEXT: Schedule :=
	; NONAFFINE-NEXT: [n, p_1] -> { Stmt_for_i_1[i0] -> [0, i0] };
	; NONAFFINE-NEXT: MayWriteAccess := [Reduction Type: NONE] [Scalar: 0]
	; NONAFFINE-NEXT: [n, p_1] -> { Stmt_for_i_1[i0] -> MemRef_X[o0] };
	; NONAFFINE-NEXT: Stmt_for_i_2
	; NONAFFINE-NEXT: Domain :=
	; NONAFFINE-NEXT: [n, p_1] -> { Stmt_for_i_2[i0] : 0 <= i0 < n };
	; NONAFFINE-NEXT: Schedule :=
	; NONAFFINE-NEXT: [n, p_1] -> { Stmt_for_i_2[i0] -> [1, i0] };
	; NONAFFINE-NEXT: MustWriteAccess := [Reduction Type: NONE] [Scalar: 0]
	; NONAFFINE-NEXT: [n, p_1] -> { Stmt_for_i_2[i0] -> MemRef_X[p_1 + i0] };
	; NONAFFINE-NEXT: }

	; DELIN: Statements {
	; DELIN-NEXT: Stmt_for_i_1
	; DELIN-NEXT: Domain :=
	; DELIN-NEXT: [n] -> { Stmt_for_i_1[i0] : 0 <= i0 < n };
	; DELIN-NEXT: Schedule :=
	; DELIN-NEXT: [n] -> { Stmt_for_i_1[i0] -> [0, i0] };
	; DELIN-NEXT: MustWriteAccess := [Reduction Type: NONE] [Scalar: 0]
	; DELIN-NEXT: [n] -> { Stmt_for_i_1[i0] -> MemRef_X[i0, 0] };
	; DELIN-NEXT: Stmt_for_i_2
	; DELIN-NEXT: Domain :=
	; DELIN-NEXT: [n] -> { Stmt_for_i_2[i0] : 0 <= i0 < n };
	; DELIN-NEXT: Schedule :=
	; DELIN-NEXT: [n] -> { Stmt_for_i_2[i0] -> [1, i0] };
	; DELIN-NEXT: MustWriteAccess := [Reduction Type: NONE] [Scalar: 0]
	; DELIN-NEXT: [n] -> { Stmt_for_i_2[i0] -> MemRef_X[-1 + n, i0] };
	; DELIN-NEXT: }

	define void @single-and-multi-dimensional-array(i64 %n, float* %X) {
	entry:
	br label %for.i.1

	for.i.1:
	%indvar.1 = phi i64 [ 0, %entry ], [ %indvar.next.1, %for.i.1 ]
	%offset.1 = mul i64 %n, %indvar.1
	%arrayidx.1 = getelementptr float, float* %X, i64 %offset.1
	store float 1.000000e+00, float* %arrayidx.1
	%indvar.next.1 = add nsw i64 %indvar.1, 1
	%exitcond.1 = icmp ne i64 %indvar.next.1, %n
	br i1 %exitcond.1, label %for.i.1, label %next

	next:
	br label %for.i.2

	for.i.2:
	%indvar.2 = phi i64 [ 0, %next ], [ %indvar.next.2, %for.i.2 ]
	%offset.2.a = add i64 %n, -1
	%offset.2.b = mul i64 %n, %offset.2.a
	%offset.2.c = add i64 %offset.2.b, %indvar.2
	%arrayidx.2 = getelementptr float, float* %X, i64 %offset.2.c
	store float 1.000000e+00, float* %arrayidx.2
	%indvar.next.2 = add nsw i64 %indvar.2, 1
	%exitcond.2 = icmp ne i64 %indvar.next.2, %n
	br i1 %exitcond.2, label %for.i.2, label %exit

	exit:
	ret void
	}