test/Transforms/SeparateConstOffsetFromGEP/NVPTX/split-gep.ll - llvm - Git at Google

 ; RUN: opt < %s -separate-const-offset-from-gep -reassociate-geps-verify-no-dead-code -S | FileCheck %s

 ; Several unit tests for -separate-const-offset-from-gep. The transformation
 ; heavily relies on TargetTransformInfo, so we put these tests under
 ; target-specific folders.

 target datalayout = "e-m:e-i64:64-f80:128-n8:16:32:64-S128"
 ; target triple is necessary; otherwise TargetTransformInfo rejects any
 ; addressing mode.
 target triple = "nvptx64-unknown-unknown"

 %struct.S = type { float, double }

 @struct_array = global [1024 x %struct.S] zeroinitializer, align 16
 @float_2d_array = global [32 x [32 x float]] zeroinitializer, align 4

 ; We should not extract any struct field indices, because fields in a struct
 ; may have different types.
 define double* @struct(i32 %i) {
 entry:
   %add = add nsw i32 %i, 5
   %idxprom = sext i32 %add to i64
   %p = getelementptr inbounds [1024 x %struct.S], [1024 x %struct.S]* @struct_array, i64 0, i64 %idxprom, i32 1
   ret double* %p
 }
 ; CHECK-LABEL: @struct(
 ; CHECK: getelementptr [1024 x %struct.S], [1024 x %struct.S]* @struct_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i32 1

 ; We should be able to trace into sext(a + b) if a + b is non-negative
 ; (e.g., used as an index of an inbounds GEP) and one of a and b is
 ; non-negative.
 define float* @sext_add(i32 %i, i32 %j) {
 entry:
   %0 = add i32 %i, 1
   %1 = sext i32 %0 to i64  ; inbound sext(i + 1) = sext(i) + 1
   %2 = add i32 %j, -2
   ; However, inbound sext(j + -2) != sext(j) + -2, e.g., j = INT_MIN
   %3 = sext i32 %2 to i64
   %p = getelementptr inbounds [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %1, i64 %3
   ret float* %p
 }
 ; CHECK-LABEL: @sext_add(
 ; CHECK-NOT: = add
 ; CHECK: add i32 %j, -2
 ; CHECK: sext
 ; CHECK: getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i64 %{{[a-zA-Z0-9]+}}
 ; CHECK: getelementptr inbounds float, float* %{{[a-zA-Z0-9]+}}, i64 32

 ; We should be able to trace into sext/zext if it can be distributed to both
 ; operands, e.g., sext (add nsw a, b) == add nsw (sext a), (sext b)
 ;
 ; This test verifies we can transform
 ;   gep base, a + sext(b +nsw 1), c + zext(d +nuw 1)
 ; to
 ;   gep base, a + sext(b), c + zext(d); gep ..., 1 * 32 + 1
 define float* @ext_add_no_overflow(i64 %a, i32 %b, i64 %c, i32 %d) {
   %b1 = add nsw i32 %b, 1
   %b2 = sext i32 %b1 to i64
   %i = add i64 %a, %b2       ; i = a + sext(b +nsw 1)
   %d1 = add nuw i32 %d, 1
   %d2 = zext i32 %d1 to i64
   %j = add i64 %c, %d2       ; j = c + zext(d +nuw 1)
   %p = getelementptr inbounds [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %i, i64 %j
   ret float* %p
 }
 ; CHECK-LABEL: @ext_add_no_overflow(
 ; CHECK: [[BASE_PTR:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i64 %{{[a-zA-Z0-9]+}}
 ; CHECK: getelementptr inbounds float, float* [[BASE_PTR]], i64 33

 ; Verifies we handle nested sext/zext correctly.
 define void @sext_zext(i32 %a, i32 %b, float** %out1, float** %out2) {
 entry:
   %0 = add nsw nuw i32 %a, 1
   %1 = sext i32 %0 to i48
   %2 = zext i48 %1 to i64    ; zext(sext(a +nsw nuw 1)) = zext(sext(a)) + 1
   %3 = add nsw i32 %b, 2
   %4 = sext i32 %3 to i48
   %5 = zext i48 %4 to i64    ; zext(sext(b +nsw 2)) != zext(sext(b)) + 2
   %p1 = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %2, i64 %5
   store float* %p1, float** %out1
   %6 = add nuw i32 %a, 3
   %7 = zext i32 %6 to i48
   %8 = sext i48 %7 to i64 ; sext(zext(a +nuw 3)) = zext(a +nuw 3) = zext(a) + 3
   %9 = add nsw i32 %b, 4
   %10 = zext i32 %9 to i48
   %11 = sext i48 %10 to i64  ; sext(zext(b +nsw 4)) != zext(b) + 4
   %p2 = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %8, i64 %11
   store float* %p2, float** %out2
   ret void
 }
 ; CHECK-LABEL: @sext_zext(
 ; CHECK: [[BASE_PTR_1:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i64 %{{[a-zA-Z0-9]+}}
 ; CHECK: getelementptr float, float* [[BASE_PTR_1]], i64 32
 ; CHECK: [[BASE_PTR_2:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i64 %{{[a-zA-Z0-9]+}}
 ; CHECK: getelementptr float, float* [[BASE_PTR_2]], i64 96

 ; Similar to @ext_add_no_overflow, we should be able to trace into s/zext if
 ; its operand is an OR and the two operands of the OR have no common bits.
 define float* @sext_or(i64 %a, i32 %b) {
 entry:
   %b1 = shl i32 %b, 2
   %b2 = or i32 %b1, 1 ; (b << 2) and 1 have no common bits
   %b3 = or i32 %b1, 4 ; (b << 2) and 4 may have common bits
   %b2.ext = zext i32 %b2 to i64
   %b3.ext = sext i32 %b3 to i64
   %i = add i64 %a, %b2.ext
   %j = add i64 %a, %b3.ext
   %p = getelementptr inbounds [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %i, i64 %j
   ret float* %p
 }
 ; CHECK-LABEL: @sext_or(
 ; CHECK: [[BASE_PTR:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i64 %{{[a-zA-Z0-9]+}}
 ; CHECK: getelementptr inbounds float, float* [[BASE_PTR]], i64 32

 ; The subexpression (b + 5) is used in both "i = a + (b + 5)" and "*out = b +
 ; 5". When extracting the constant offset 5, make sure "*out = b + 5" isn't
 ; affected.
 define float* @expr(i64 %a, i64 %b, i64* %out) {
 entry:
   %b5 = add i64 %b, 5
   %i = add i64 %b5, %a
   %p = getelementptr inbounds [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %i, i64 0
   store i64 %b5, i64* %out
   ret float* %p
 }
 ; CHECK-LABEL: @expr(
 ; CHECK: [[BASE_PTR:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i64 0
 ; CHECK: getelementptr inbounds float, float* [[BASE_PTR]], i64 160
 ; CHECK: store i64 %b5, i64* %out

 ; d + sext(a +nsw (b +nsw (c +nsw 8))) => (d + sext(a) + sext(b) + sext(c)) + 8
 define float* @sext_expr(i32 %a, i32 %b, i32 %c, i64 %d) {
 entry:
   %0 = add nsw i32 %c, 8
   %1 = add nsw i32 %b, %0
   %2 = add nsw i32 %a, %1
   %3 = sext i32 %2 to i64
   %i = add i64 %d, %3
   %p = getelementptr inbounds [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %i
   ret float* %p
 }
 ; CHECK-LABEL: @sext_expr(
 ; CHECK: sext i32
 ; CHECK: sext i32
 ; CHECK: sext i32
 ; CHECK: getelementptr inbounds float, float* %{{[a-zA-Z0-9]+}}, i64 8

 ; Verifies we handle "sub" correctly.
 define float* @sub(i64 %i, i64 %j) {
   %i2 = sub i64 %i, 5 ; i - 5
   %j2 = sub i64 5, %j ; 5 - i
   %p = getelementptr inbounds [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %i2, i64 %j2
   ret float* %p
 }
 ; CHECK-LABEL: @sub(
 ; CHECK: %[[j2:[a-zA-Z0-9]+]] = sub i64 0, %j
 ; CHECK: [[BASE_PTR:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %i, i64 %[[j2]]
 ; CHECK: getelementptr inbounds float, float* [[BASE_PTR]], i64 -155

 %struct.Packed = type <{ [3 x i32], [8 x i64] }> ; <> means packed

 ; Verifies we can emit correct uglygep if the address is not natually aligned.
 define i64* @packed_struct(i32 %i, i32 %j) {
 entry:
   %s = alloca [1024 x %struct.Packed], align 16
   %add = add nsw i32 %j, 3
   %idxprom = sext i32 %add to i64
   %add1 = add nsw i32 %i, 1
   %idxprom2 = sext i32 %add1 to i64
   %arrayidx3 = getelementptr inbounds [1024 x %struct.Packed], [1024 x %struct.Packed]* %s, i64 0, i64 %idxprom2, i32 1, i64 %idxprom
   ret i64* %arrayidx3
 }
 ; CHECK-LABEL: @packed_struct(
 ; CHECK: [[BASE_PTR:%[a-zA-Z0-9]+]] = getelementptr [1024 x %struct.Packed], [1024 x %struct.Packed]* %s, i64 0, i64 %{{[a-zA-Z0-9]+}}, i32 1, i64 %{{[a-zA-Z0-9]+}}
 ; CHECK: [[CASTED_PTR:%[a-zA-Z0-9]+]] = bitcast i64* [[BASE_PTR]] to i8*
 ; CHECK: %uglygep = getelementptr inbounds i8, i8* [[CASTED_PTR]], i64 100
 ; CHECK: bitcast i8* %uglygep to i64*

 ; We shouldn't be able to extract the 8 from "zext(a +nuw (b + 8))",
 ; because "zext(b + 8) != zext(b) + 8"
 define float* @zext_expr(i32 %a, i32 %b) {
 entry:
   %0 = add i32 %b, 8
   %1 = add nuw i32 %a, %0
   %i = zext i32 %1 to i64
   %p = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %i
   ret float* %p
 }
 ; CHECK-LABEL: zext_expr(
 ; CHECK: getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %i

 ; Per http://llvm.org/docs/LangRef.html#id181, the indices of a off-bound gep
 ; should be considered sign-extended to the pointer size. Therefore,
 ;   gep base, (add i32 a, b) != gep (gep base, i32 a), i32 b
 ; because
 ;   sext(a + b) != sext(a) + sext(b)
 ;
 ; This test verifies we do not illegitimately extract the 8 from
 ;   gep base, (i32 a + 8)
 define float* @i32_add(i32 %a) {
 entry:
   %i = add i32 %a, 8
   %p = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i32 %i
   ret float* %p
 }
 ; CHECK-LABEL: @i32_add(
 ; CHECK: getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %{{[a-zA-Z0-9]+}}
 ; CHECK-NOT: getelementptr

 ; Verifies that we compute the correct constant offset when the index is
 ; sign-extended and then zero-extended. The old version of our code failed to
 ; handle this case because it simply computed the constant offset as the
 ; sign-extended value of the constant part of the GEP index.
 define float* @apint(i1 %a) {
 entry:
   %0 = add nsw nuw i1 %a, 1
   %1 = sext i1 %0 to i4
   %2 = zext i4 %1 to i64         ; zext (sext i1 1 to i4) to i64 = 15
   %p = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %2
   ret float* %p
 }
 ; CHECK-LABEL: @apint(
 ; CHECK: [[BASE_PTR:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %{{[a-zA-Z0-9]+}}
 ; CHECK: getelementptr float, float* [[BASE_PTR]], i64 15

 ; Do not trace into binary operators other than ADD, SUB, and OR.
 define float* @and(i64 %a) {
 entry:
   %0 = shl i64 %a, 2
   %1 = and i64 %0, 1
   %p = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %1
   ret float* %p
 }
 ; CHECK-LABEL: @and(
 ; CHECK: getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array
 ; CHECK-NOT: getelementptr

 ; The code that rebuilds an OR expression used to be buggy, and failed on this
 ; test.
 define float* @shl_add_or(i64 %a, float* %ptr) {
 ; CHECK-LABEL: @shl_add_or(
 entry:
   %shl = shl i64 %a, 2
   %add = add i64 %shl, 12
   %or = or i64 %add, 1
 ; CHECK: [[OR:%or[0-9]*]] = add i64 %shl, 1
   ; ((a << 2) + 12) and 1 have no common bits. Therefore,
   ; SeparateConstOffsetFromGEP is able to extract the 12.
   ; TODO(jingyue): We could reassociate the expression to combine 12 and 1.
   %p = getelementptr float, float* %ptr, i64 %or
 ; CHECK: [[PTR:%[a-zA-Z0-9]+]] = getelementptr float, float* %ptr, i64 [[OR]]
 ; CHECK: getelementptr float, float* [[PTR]], i64 12
   ret float* %p
 ; CHECK-NEXT: ret
 }

 ; The source code used to be buggy in checking
 ; (AccumulativeByteOffset % ElementTypeSizeOfGEP == 0)
 ; where AccumulativeByteOffset is signed but ElementTypeSizeOfGEP is unsigned.
 ; The compiler would promote AccumulativeByteOffset to unsigned, causing
 ; unexpected results. For example, while -64 % (int64_t)24 != 0,
 ; -64 % (uint64_t)24 == 0.
 %struct3 = type { i64, i32 }
 %struct2 = type { %struct3, i32 }
 %struct1 = type { i64, %struct2 }
 %struct0 = type { i32, i32, i64*, [100 x %struct1] }
 define %struct2* @sign_mod_unsign(%struct0* %ptr, i64 %idx) {
 ; CHECK-LABEL: @sign_mod_unsign(
 entry:
   %arrayidx = add nsw i64 %idx, -2
 ; CHECK-NOT: add
   %ptr2 = getelementptr inbounds %struct0, %struct0* %ptr, i64 0, i32 3, i64 %arrayidx, i32 1
 ; CHECK: [[PTR:%[a-zA-Z0-9]+]] = getelementptr %struct0, %struct0* %ptr, i64 0, i32 3, i64 %idx, i32 1
 ; CHECK: [[PTR1:%[a-zA-Z0-9]+]] = bitcast %struct2* [[PTR]] to i8*
 ; CHECK: getelementptr inbounds i8, i8* [[PTR1]], i64 -64
 ; CHECK: bitcast
   ret %struct2* %ptr2
 ; CHECK-NEXT: ret
 }
	; RUN: opt < %s -separate-const-offset-from-gep -reassociate-geps-verify-no-dead-code -S \| FileCheck %s

	; Several unit tests for -separate-const-offset-from-gep. The transformation
	; heavily relies on TargetTransformInfo, so we put these tests under
	; target-specific folders.

	target datalayout = "e-m:e-i64:64-f80:128-n8:16:32:64-S128"
	; target triple is necessary; otherwise TargetTransformInfo rejects any
	; addressing mode.
	target triple = "nvptx64-unknown-unknown"

	%struct.S = type { float, double }

	@struct_array = global [1024 x %struct.S] zeroinitializer, align 16
	@float_2d_array = global [32 x [32 x float]] zeroinitializer, align 4

	; We should not extract any struct field indices, because fields in a struct
	; may have different types.
	define double* @struct(i32 %i) {
	entry:
	%add = add nsw i32 %i, 5
	%idxprom = sext i32 %add to i64
	%p = getelementptr inbounds [1024 x %struct.S], [1024 x %struct.S]* @struct_array, i64 0, i64 %idxprom, i32 1
	ret double* %p
	}
	; CHECK-LABEL: @struct(
	; CHECK: getelementptr [1024 x %struct.S], [1024 x %struct.S]* @struct_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i32 1

	; We should be able to trace into sext(a + b) if a + b is non-negative
	; (e.g., used as an index of an inbounds GEP) and one of a and b is
	; non-negative.
	define float* @sext_add(i32 %i, i32 %j) {
	entry:
	%0 = add i32 %i, 1
	%1 = sext i32 %0 to i64 ; inbound sext(i + 1) = sext(i) + 1
	%2 = add i32 %j, -2
	; However, inbound sext(j + -2) != sext(j) + -2, e.g., j = INT_MIN
	%3 = sext i32 %2 to i64
	%p = getelementptr inbounds [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %1, i64 %3
	ret float* %p
	}
	; CHECK-LABEL: @sext_add(
	; CHECK-NOT: = add
	; CHECK: add i32 %j, -2
	; CHECK: sext
	; CHECK: getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i64 %{{[a-zA-Z0-9]+}}
	; CHECK: getelementptr inbounds float, float* %{{[a-zA-Z0-9]+}}, i64 32

	; We should be able to trace into sext/zext if it can be distributed to both
	; operands, e.g., sext (add nsw a, b) == add nsw (sext a), (sext b)
	;
	; This test verifies we can transform
	; gep base, a + sext(b +nsw 1), c + zext(d +nuw 1)
	; to
	; gep base, a + sext(b), c + zext(d); gep ..., 1 * 32 + 1
	define float* @ext_add_no_overflow(i64 %a, i32 %b, i64 %c, i32 %d) {
	%b1 = add nsw i32 %b, 1
	%b2 = sext i32 %b1 to i64
	%i = add i64 %a, %b2 ; i = a + sext(b +nsw 1)
	%d1 = add nuw i32 %d, 1
	%d2 = zext i32 %d1 to i64
	%j = add i64 %c, %d2 ; j = c + zext(d +nuw 1)
	%p = getelementptr inbounds [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %i, i64 %j
	ret float* %p
	}
	; CHECK-LABEL: @ext_add_no_overflow(
	; CHECK: [[BASE_PTR:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i64 %{{[a-zA-Z0-9]+}}
	; CHECK: getelementptr inbounds float, float* [[BASE_PTR]], i64 33

	; Verifies we handle nested sext/zext correctly.
	define void @sext_zext(i32 %a, i32 %b, float %out1, float %out2) {
	entry:
	%0 = add nsw nuw i32 %a, 1
	%1 = sext i32 %0 to i48
	%2 = zext i48 %1 to i64 ; zext(sext(a +nsw nuw 1)) = zext(sext(a)) + 1
	%3 = add nsw i32 %b, 2
	%4 = sext i32 %3 to i48
	%5 = zext i48 %4 to i64 ; zext(sext(b +nsw 2)) != zext(sext(b)) + 2
	%p1 = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %2, i64 %5
	store float* %p1, float** %out1
	%6 = add nuw i32 %a, 3
	%7 = zext i32 %6 to i48
	%8 = sext i48 %7 to i64 ; sext(zext(a +nuw 3)) = zext(a +nuw 3) = zext(a) + 3
	%9 = add nsw i32 %b, 4
	%10 = zext i32 %9 to i48
	%11 = sext i48 %10 to i64 ; sext(zext(b +nsw 4)) != zext(b) + 4
	%p2 = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %8, i64 %11
	store float* %p2, float** %out2
	ret void
	}
	; CHECK-LABEL: @sext_zext(
	; CHECK: [[BASE_PTR_1:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i64 %{{[a-zA-Z0-9]+}}
	; CHECK: getelementptr float, float* [[BASE_PTR_1]], i64 32
	; CHECK: [[BASE_PTR_2:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i64 %{{[a-zA-Z0-9]+}}
	; CHECK: getelementptr float, float* [[BASE_PTR_2]], i64 96

	; Similar to @ext_add_no_overflow, we should be able to trace into s/zext if
	; its operand is an OR and the two operands of the OR have no common bits.
	define float* @sext_or(i64 %a, i32 %b) {
	entry:
	%b1 = shl i32 %b, 2
	%b2 = or i32 %b1, 1 ; (b << 2) and 1 have no common bits
	%b3 = or i32 %b1, 4 ; (b << 2) and 4 may have common bits
	%b2.ext = zext i32 %b2 to i64
	%b3.ext = sext i32 %b3 to i64
	%i = add i64 %a, %b2.ext
	%j = add i64 %a, %b3.ext
	%p = getelementptr inbounds [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %i, i64 %j
	ret float* %p
	}
	; CHECK-LABEL: @sext_or(
	; CHECK: [[BASE_PTR:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i64 %{{[a-zA-Z0-9]+}}
	; CHECK: getelementptr inbounds float, float* [[BASE_PTR]], i64 32

	; The subexpression (b + 5) is used in both "i = a + (b + 5)" and "*out = b +
	; 5". When extracting the constant offset 5, make sure "*out = b + 5" isn't
	; affected.
	define float* @expr(i64 %a, i64 %b, i64* %out) {
	entry:
	%b5 = add i64 %b, 5
	%i = add i64 %b5, %a
	%p = getelementptr inbounds [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %i, i64 0
	store i64 %b5, i64* %out
	ret float* %p
	}
	; CHECK-LABEL: @expr(
	; CHECK: [[BASE_PTR:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %{{[a-zA-Z0-9]+}}, i64 0
	; CHECK: getelementptr inbounds float, float* [[BASE_PTR]], i64 160
	; CHECK: store i64 %b5, i64* %out

	; d + sext(a +nsw (b +nsw (c +nsw 8))) => (d + sext(a) + sext(b) + sext(c)) + 8
	define float* @sext_expr(i32 %a, i32 %b, i32 %c, i64 %d) {
	entry:
	%0 = add nsw i32 %c, 8
	%1 = add nsw i32 %b, %0
	%2 = add nsw i32 %a, %1
	%3 = sext i32 %2 to i64
	%i = add i64 %d, %3
	%p = getelementptr inbounds [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %i
	ret float* %p
	}
	; CHECK-LABEL: @sext_expr(
	; CHECK: sext i32
	; CHECK: sext i32
	; CHECK: sext i32
	; CHECK: getelementptr inbounds float, float* %{{[a-zA-Z0-9]+}}, i64 8

	; Verifies we handle "sub" correctly.
	define float* @sub(i64 %i, i64 %j) {
	%i2 = sub i64 %i, 5 ; i - 5
	%j2 = sub i64 5, %j ; 5 - i
	%p = getelementptr inbounds [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %i2, i64 %j2
	ret float* %p
	}
	; CHECK-LABEL: @sub(
	; CHECK: %[[j2:[a-zA-Z0-9]+]] = sub i64 0, %j
	; CHECK: [[BASE_PTR:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 %i, i64 %[[j2]]
	; CHECK: getelementptr inbounds float, float* [[BASE_PTR]], i64 -155

	%struct.Packed = type <{ [3 x i32], [8 x i64] }> ; <> means packed

	; Verifies we can emit correct uglygep if the address is not natually aligned.
	define i64* @packed_struct(i32 %i, i32 %j) {
	entry:
	%s = alloca [1024 x %struct.Packed], align 16
	%add = add nsw i32 %j, 3
	%idxprom = sext i32 %add to i64
	%add1 = add nsw i32 %i, 1
	%idxprom2 = sext i32 %add1 to i64
	%arrayidx3 = getelementptr inbounds [1024 x %struct.Packed], [1024 x %struct.Packed]* %s, i64 0, i64 %idxprom2, i32 1, i64 %idxprom
	ret i64* %arrayidx3
	}
	; CHECK-LABEL: @packed_struct(
	; CHECK: [[BASE_PTR:%[a-zA-Z0-9]+]] = getelementptr [1024 x %struct.Packed], [1024 x %struct.Packed]* %s, i64 0, i64 %{{[a-zA-Z0-9]+}}, i32 1, i64 %{{[a-zA-Z0-9]+}}
	; CHECK: [[CASTED_PTR:%[a-zA-Z0-9]+]] = bitcast i64* [[BASE_PTR]] to i8*
	; CHECK: %uglygep = getelementptr inbounds i8, i8* [[CASTED_PTR]], i64 100
	; CHECK: bitcast i8* %uglygep to i64*

	; We shouldn't be able to extract the 8 from "zext(a +nuw (b + 8))",
	; because "zext(b + 8) != zext(b) + 8"
	define float* @zext_expr(i32 %a, i32 %b) {
	entry:
	%0 = add i32 %b, 8
	%1 = add nuw i32 %a, %0
	%i = zext i32 %1 to i64
	%p = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %i
	ret float* %p
	}
	; CHECK-LABEL: zext_expr(
	; CHECK: getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %i

	; Per http://llvm.org/docs/LangRef.html#id181, the indices of a off-bound gep
	; should be considered sign-extended to the pointer size. Therefore,
	; gep base, (add i32 a, b) != gep (gep base, i32 a), i32 b
	; because
	; sext(a + b) != sext(a) + sext(b)
	;
	; This test verifies we do not illegitimately extract the 8 from
	; gep base, (i32 a + 8)
	define float* @i32_add(i32 %a) {
	entry:
	%i = add i32 %a, 8
	%p = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i32 %i
	ret float* %p
	}
	; CHECK-LABEL: @i32_add(
	; CHECK: getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %{{[a-zA-Z0-9]+}}
	; CHECK-NOT: getelementptr

	; Verifies that we compute the correct constant offset when the index is
	; sign-extended and then zero-extended. The old version of our code failed to
	; handle this case because it simply computed the constant offset as the
	; sign-extended value of the constant part of the GEP index.
	define float* @apint(i1 %a) {
	entry:
	%0 = add nsw nuw i1 %a, 1
	%1 = sext i1 %0 to i4
	%2 = zext i4 %1 to i64 ; zext (sext i1 1 to i4) to i64 = 15
	%p = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %2
	ret float* %p
	}
	; CHECK-LABEL: @apint(
	; CHECK: [[BASE_PTR:%[a-zA-Z0-9]+]] = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %{{[a-zA-Z0-9]+}}
	; CHECK: getelementptr float, float* [[BASE_PTR]], i64 15

	; Do not trace into binary operators other than ADD, SUB, and OR.
	define float* @and(i64 %a) {
	entry:
	%0 = shl i64 %a, 2
	%1 = and i64 %0, 1
	%p = getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array, i64 0, i64 0, i64 %1
	ret float* %p
	}
	; CHECK-LABEL: @and(
	; CHECK: getelementptr [32 x [32 x float]], [32 x [32 x float]]* @float_2d_array
	; CHECK-NOT: getelementptr

	; The code that rebuilds an OR expression used to be buggy, and failed on this
	; test.
	define float* @shl_add_or(i64 %a, float* %ptr) {
	; CHECK-LABEL: @shl_add_or(
	entry:
	%shl = shl i64 %a, 2
	%add = add i64 %shl, 12
	%or = or i64 %add, 1
	; CHECK: [[OR:%or[0-9]*]] = add i64 %shl, 1
	; ((a << 2) + 12) and 1 have no common bits. Therefore,
	; SeparateConstOffsetFromGEP is able to extract the 12.
	; TODO(jingyue): We could reassociate the expression to combine 12 and 1.
	%p = getelementptr float, float* %ptr, i64 %or
	; CHECK: [[PTR:%[a-zA-Z0-9]+]] = getelementptr float, float* %ptr, i64 [[OR]]
	; CHECK: getelementptr float, float* [[PTR]], i64 12
	ret float* %p
	; CHECK-NEXT: ret
	}

	; The source code used to be buggy in checking
	; (AccumulativeByteOffset % ElementTypeSizeOfGEP == 0)
	; where AccumulativeByteOffset is signed but ElementTypeSizeOfGEP is unsigned.
	; The compiler would promote AccumulativeByteOffset to unsigned, causing
	; unexpected results. For example, while -64 % (int64_t)24 != 0,
	; -64 % (uint64_t)24 == 0.
	%struct3 = type { i64, i32 }
	%struct2 = type { %struct3, i32 }
	%struct1 = type { i64, %struct2 }
	%struct0 = type { i32, i32, i64*, [100 x %struct1] }
	define %struct2* @sign_mod_unsign(%struct0* %ptr, i64 %idx) {
	; CHECK-LABEL: @sign_mod_unsign(
	entry:
	%arrayidx = add nsw i64 %idx, -2
	; CHECK-NOT: add
	%ptr2 = getelementptr inbounds %struct0, %struct0* %ptr, i64 0, i32 3, i64 %arrayidx, i32 1
	; CHECK: [[PTR:%[a-zA-Z0-9]+]] = getelementptr %struct0, %struct0* %ptr, i64 0, i32 3, i64 %idx, i32 1
	; CHECK: [[PTR1:%[a-zA-Z0-9]+]] = bitcast %struct2* [[PTR]] to i8*
	; CHECK: getelementptr inbounds i8, i8* [[PTR1]], i64 -64
	; CHECK: bitcast
	ret %struct2* %ptr2
	; CHECK-NEXT: ret
	}