polly/test/GPGPU/double-parallel-loop.ll - llvm-project - Git at Google

 ; RUN: opt %loadPolly -polly-scops -analyze < %s | FileCheck %s
 ; RUN: opt %loadPolly -polly-codegen-ppcg -polly-acc-dump-schedule \
 ; RUN: -disable-output < %s | \
 ; RUN: FileCheck -check-prefix=SCHED %s

 ; RUN: opt %loadPolly -polly-codegen-ppcg -polly-acc-dump-code \
 ; RUN: -disable-output < %s | \
 ; RUN: FileCheck -check-prefix=CODE %s

 ; RUN: opt %loadPolly -polly-codegen-ppcg -S < %s | \
 ; RUN: FileCheck %s -check-prefix=IR

 ; RUN: opt %loadPolly -polly-codegen-ppcg -polly-acc-dump-kernel-ir \
 ; RUN: -disable-output < %s | \
 ; RUN: FileCheck %s -check-prefix=KERNEL-IR

 ; RUN: opt %loadPolly -polly-codegen-ppcg -polly-acc-dump-kernel-asm \
 ; RUN: -disable-output < %s | \
 ; RUN: FileCheck %s -check-prefix=KERNEL-ASM

 ; REQUIRES: pollyacc,nvptx

 ; CHECK: Stmt_bb5
 ; CHECK-NEXT:       Domain :=
 ; CHECK-NEXT:           { Stmt_bb5[i0, i1] : 0 <= i0 <= 1023 and 0 <= i1 <= 1023 };
 ; CHECK-NEXT:       Schedule :=
 ; CHECK-NEXT:           { Stmt_bb5[i0, i1] -> [i0, i1] };
 ; CHECK-NEXT:       ReadAccess :=       [Reduction Type: NONE] [Scalar: 0]
 ; CHECK-NEXT:           { Stmt_bb5[i0, i1] -> MemRef_A[i0, i1] };
 ; CHECK-NEXT:       MustWriteAccess :=  [Reduction Type: NONE] [Scalar: 0]
 ; CHECK-NEXT:           { Stmt_bb5[i0, i1] -> MemRef_A[i0, i1] };

 ; SCHED: domain: "{ Stmt_bb5[i0, i1] : 0 <= i0 <= 1023 and 0 <= i1 <= 1023 }"
 ; SCHED-NEXT: child:
 ; SCHED-NEXT:   context: "{ [] }"
 ; SCHED-NEXT:   child:
 ; SCHED-NEXT:     extension: "{ [] -> from_device_MemRef_A[]; [] -> to_device_MemRef_A[] }"
 ; SCHED-NEXT:     child:
 ; SCHED-NEXT:       sequence:
 ; SCHED-NEXT:       - filter: "{ to_device_MemRef_A[] }"
 ; SCHED-NEXT:         child:
 ; SCHED-NEXT:           set:
 ; SCHED-NEXT:           - filter: "{ to_device_MemRef_A[] }"
 ; SCHED-NEXT:             child:
 ; SCHED-NEXT:               guard: "{ [] }"
 ; SCHED-NEXT:       - filter: "{ Stmt_bb5[i0, i1] }"
 ; SCHED-NEXT:         child:
 ; SCHED-NEXT:           guard: "{ [] }"
 ; SCHED-NEXT:           child:
 ; SCHED-NEXT:             mark: "kernel"
 ; SCHED-NEXT:             child:
 ; SCHED-NEXT:               context: "[b0, b1, t0, t1] -> { [] : 0 <= b0 <= 31 and 0 <= b1 <= 31 and 0 <= t0 <= 31 and 0 <= t1 <= 15 }"
 ; SCHED-NEXT:               child:
 ; SCHED-NEXT:                 filter: "[b0, b1] -> { Stmt_bb5[i0, i1] : -31 - 32b0 + i0 <= 8192*floor((i0)/8192) <= -32b0 + i0 and -31 - 32b1 + i1 <= 8192*floor((i1)/8192) <= -32b1 + i1 }"
 ; SCHED-NEXT:                 child:
 ; SCHED-NEXT:                   schedule: "[{ Stmt_bb5[i0, i1] -> [(floor((i0)/8192))] }, { Stmt_bb5[i0, i1] -> [(floor((i1)/8192))] }]"
 ; SCHED-NEXT:                   permutable: 1
 ; SCHED-NEXT:                   coincident: [ 1, 1 ]
 ; SCHED-NEXT:                   child:
 ; SCHED-NEXT:                     filter: "[t0, t1] -> { Stmt_bb5[i0, i1] : 32*floor((-t0 + i0)/32) = -t0 + i0 and 16*floor((-t1 + i1)/16) = -t1 + i1 and 0 <= t0 <= 31 and 0 <= t1 <= 15 }"
 ; SCHED-NEXT:                     child:
 ; SCHED-NEXT:                       schedule: "[{ Stmt_bb5[i0, i1] -> [(0)] }, { Stmt_bb5[i0, i1] -> [(floor((i1)/16) - 2*floor((i1)/32))] }]"
 ; SCHED-NEXT:                       permutable: 1
 ; SCHED-NEXT:                       coincident: [ 1, 1 ]
 ; SCHED-NEXT:       - filter: "{ from_device_MemRef_A[] }"
 ; SCHED-NEXT:         child:
 ; SCHED-NEXT:           set:
 ; SCHED-NEXT:           - filter: "{ from_device_MemRef_A[] }"
 ; SCHED-NEXT:             child:
 ; SCHED-NEXT:               guard: "{ [] }"

 ; CODE: Code
 ; CODE-NEXT: ====
 ; CODE-NEXT: # host
 ; CODE-NEXT: {
 ; CODE-NEXT:   cudaCheckReturn(cudaMemcpy(dev_MemRef_A, MemRef_A, (1024) * (1024) * sizeof(float), cudaMemcpyHostToDevice));
 ; CODE-NEXT:   {
 ; CODE-NEXT:     dim3 k0_dimBlock(16, 32);
 ; CODE-NEXT:     dim3 k0_dimGrid(32, 32);
 ; CODE-NEXT:     kernel0 <<<k0_dimGrid, k0_dimBlock>>> (dev_MemRef_A);
 ; CODE-NEXT:     cudaCheckKernel();
 ; CODE-NEXT:   }

 ; CODE:   cudaCheckReturn(cudaMemcpy(MemRef_A, dev_MemRef_A, (1024) * (1024) * sizeof(float), cudaMemcpyDeviceToHost));
 ; CODE-NEXT: }

 ; CODE: # kernel0
 ; CODE-NEXT: for (int c3 = 0; c3 <= 1; c3 += 1)
 ; CODE-NEXT:   Stmt_bb5(32 * b0 + t0, 32 * b1 + t1 + 16 * c3);

 ; IR: polly.split_new_and_old:
 ; IR-NEXT:   %0 = call { i64, i1 } @llvm.smul.with.overflow.i64(i64 1, i64 1024)
 ; IR-NEXT:   %.obit = extractvalue { i64, i1 } %0, 1
 ; IR-NEXT:   %polly.overflow.state = or i1 false, %.obit
 ; IR-NEXT:   %.res = extractvalue { i64, i1 } %0, 0
 ; IR-NEXT:   %1 = call { i64, i1 } @llvm.smul.with.overflow.i64(i64 %.res, i64 1024)
 ; IR-NEXT:   %.obit1 = extractvalue { i64, i1 } %1, 1
 ; IR-NEXT:   %polly.overflow.state2 = or i1 %polly.overflow.state, %.obit1
 ; IR-NEXT:   %.res3 = extractvalue { i64, i1 } %1, 0
 ; IR-NEXT:   %2 = call { i64, i1 } @llvm.smul.with.overflow.i64(i64 7, i64 %.res3)
 ; IR-NEXT:   %.obit4 = extractvalue { i64, i1 } %2, 1
 ; IR-NEXT:   %polly.overflow.state5 = or i1 %polly.overflow.state2, %.obit4
 ; IR-NEXT:   %.res6 = extractvalue { i64, i1 } %2, 0
 ; IR-NEXT:   %3 = call { i64, i1 } @llvm.sadd.with.overflow.i64(i64 0, i64 %.res6)
 ; IR-NEXT:   %.obit7 = extractvalue { i64, i1 } %3, 1
 ; IR-NEXT:   %polly.overflow.state8 = or i1 %polly.overflow.state5, %.obit7
 ; IR-NEXT:   %.res9 = extractvalue { i64, i1 } %3, 0
 ; IR-NEXT:   %4 = icmp sge i64 %.res9, 2621440
 ; IR-NEXT:   %5 = and i1 true, %4
 ; IR-NEXT:   %polly.rtc.overflown = xor i1 %polly.overflow.state8, true
 ; IR-NEXT:   %polly.rtc.result = and i1 %5, %polly.rtc.overflown
 ; IR-NEXT:   br i1 %polly.rtc.result, label %polly.start, label %bb2

 ; IR: polly.start:
 ; IR-NEXT: br label %polly.acc.initialize

 ; IR: polly.acc.initialize:
 ; IR-NEXT:    [[GPUContext:%.*]] = call i8* @polly_initContext()
 ; IR-NEXT:    %p_dev_array_MemRef_A = call i8* @polly_allocateMemoryForDevice(i64 4194304)
 ; IR-NEXT:    [[HostPtr:%.*]] = bitcast [1024 x float]* %A to i8*
 ; IR-NEXT:    call void @polly_copyFromHostToDevice(i8* [[HostPtr]], i8* %p_dev_array_MemRef_A, i64 4194304)
 ; IR-NEXT:    [[DevPtr:%.*]]  = call i8* @polly_getDevicePtr(i8* %p_dev_array_MemRef_A)
 ; IR-NEXT:    [[ParamSlot:%.*]] = getelementptr [1 x i8*], [1 x i8*]* %polly_launch_0_params, i64 0, i64 0
 ; IR-NEXT:    store i8* [[DevPtr]], i8** %polly_launch_0_param_0
 ; IR-NEXT:    [[ParamTyped:%.*]] = bitcast i8** %polly_launch_0_param_0 to i8*
 ; IR-NEXT:    store i8* [[ParamTyped]], i8** [[ParamSlot]]
 ; IR-NEXT:    call i8* @polly_getKernel
 ; IR-NEXT:    call void @polly_launchKernel(i8* %11, i32 32, i32 32, i32 32, i32 16, i32 1, i8* %polly_launch_0_params_i8ptr)
 ; IR-NEXT:    call void @polly_freeKernel
 ; IR-NEXT:    [[HostPtr2:%.*]] = bitcast [1024 x float]* %A to i8*
 ; IR-NEXT:    call void @polly_copyFromDeviceToHost(i8* %p_dev_array_MemRef_A, i8* [[HostPtr2]], i64 4194304)
 ; IR-NEXT:    call void @polly_freeDeviceMemory(i8* %p_dev_array_MemRef_A)
 ; IR-NEXT:    call void @polly_freeContext(i8* [[GPUContext]])
 ; IR-NEXT:    br label %polly.exiting

 ; IR: polly.exiting:
 ; IR-NEXT:    br label %polly.merge_new_and_old

 ; KERNEL-IR-LABEL: define ptx_kernel void @kernel_0(i8* %MemRef_A) #0 {
 ; KERNEL-IR-NEXT: entry:
 ; KERNEL-IR-NEXT:   %0 = call i32 @llvm.nvvm.read.ptx.sreg.ctaid.x()
 ; KERNEL-IR-NEXT:   %b0 = zext i32 %0 to i64
 ; KERNEL-IR-NEXT:   %1 = call i32 @llvm.nvvm.read.ptx.sreg.ctaid.y()
 ; KERNEL-IR-NEXT:   %b1 = zext i32 %1 to i64
 ; KERNEL-IR-NEXT:   %2 = call i32 @llvm.nvvm.read.ptx.sreg.tid.x()
 ; KERNEL-IR-NEXT:   %t0 = zext i32 %2 to i64
 ; KERNEL-IR-NEXT:   %3 = call i32 @llvm.nvvm.read.ptx.sreg.tid.y()
 ; KERNEL-IR-NEXT:   %t1 = zext i32 %3 to i64
 ; KERNEL-IR-NEXT:   br label %polly.loop_preheader

 ; KERNEL-IR-LABEL: polly.loop_exit:                                  ; preds = %polly.stmt.bb5
 ; KERNEL-IR-NEXT:   ret void

 ; KERNEL-IR-LABEL: polly.loop_header:                                ; preds = %polly.stmt.bb5, %polly.loop_preheader
 ; KERNEL-IR-NEXT:   %polly.indvar = phi i64 [ 0, %polly.loop_preheader ], [ %polly.indvar_next, %polly.stmt.bb5 ]
 ; KERNEL-IR-NEXT:   %4 = mul nsw i64 32, %b0
 ; KERNEL-IR-NEXT:   %5 = add nsw i64 %4, %t0
 ; KERNEL-IR-NEXT:   %6 = mul nsw i64 32, %b1
 ; KERNEL-IR-NEXT:   %7 = add nsw i64 %6, %t1
 ; KERNEL-IR-NEXT:   %8 = mul nsw i64 16, %polly.indvar
 ; KERNEL-IR-NEXT:   %9 = add nsw i64 %7, %8
 ; KERNEL-IR-NEXT:   br label %polly.stmt.bb5

 ; KERNEL-IR-LABEL: polly.stmt.bb5:                                   ; preds = %polly.loop_header
 ; KERNEL-IR-NEXT:   %10 = mul i64 %5, %9
 ; KERNEL-IR-NEXT:   %p_tmp6 = sitofp i64 %10 to float
 ; KERNEL-IR-NEXT:   %polly.access.cast.MemRef_A = bitcast i8* %MemRef_A to float*
 ; KERNEL-IR-NEXT:   %11 = mul nsw i64 32, %b0
 ; KERNEL-IR-NEXT:   %12 = add nsw i64 %11, %t0
 ; KERNEL-IR-NEXT:   %polly.access.mul.MemRef_A = mul nsw i64 %12, 1024
 ; KERNEL-IR-NEXT:   %13 = mul nsw i64 32, %b1
 ; KERNEL-IR-NEXT:   %14 = add nsw i64 %13, %t1
 ; KERNEL-IR-NEXT:   %15 = mul nsw i64 16, %polly.indvar
 ; KERNEL-IR-NEXT:   %16 = add nsw i64 %14, %15
 ; KERNEL-IR-NEXT:   %polly.access.add.MemRef_A = add nsw i64 %polly.access.mul.MemRef_A, %16
 ; KERNEL-IR-NEXT:   %polly.access.MemRef_A = getelementptr float, float* %polly.access.cast.MemRef_A, i64 %polly.access.add.MemRef_A
 ; KERNEL-IR-NEXT:   %tmp8_p_scalar_ = load float, float* %polly.access.MemRef_A, align 4
 ; KERNEL-IR-NEXT:   %p_tmp9 = fadd float %tmp8_p_scalar_, %p_tmp6
 ; KERNEL-IR-NEXT:   %polly.access.cast.MemRef_A1 = bitcast i8* %MemRef_A to float*
 ; KERNEL-IR-NEXT:   %17 = mul nsw i64 32, %b0
 ; KERNEL-IR-NEXT:   %18 = add nsw i64 %17, %t0
 ; KERNEL-IR-NEXT:   %polly.access.mul.MemRef_A2 = mul nsw i64 %18, 1024
 ; KERNEL-IR-NEXT:   %19 = mul nsw i64 32, %b1
 ; KERNEL-IR-NEXT:   %20 = add nsw i64 %19, %t1
 ; KERNEL-IR-NEXT:   %21 = mul nsw i64 16, %polly.indvar
 ; KERNEL-IR-NEXT:   %22 = add nsw i64 %20, %21
 ; KERNEL-IR-NEXT:   %polly.access.add.MemRef_A3 = add nsw i64 %polly.access.mul.MemRef_A2, %22
 ; KERNEL-IR-NEXT:   %polly.access.MemRef_A4 = getelementptr float, float* %polly.access.cast.MemRef_A1, i64 %polly.access.add.MemRef_A3
 ; KERNEL-IR-NEXT:   store float %p_tmp9, float* %polly.access.MemRef_A4, align 4
 ; KERNEL-IR-NEXT:   %polly.indvar_next = add nsw i64 %polly.indvar, 1
 ; KERNEL-IR-NEXT:   %polly.loop_cond = icmp sle i64 %polly.indvar, 0
 ; KERNEL-IR-NEXT:   br i1 %polly.loop_cond, label %polly.loop_header, label %polly.loop_exit

 ; KERNEL-IR-LABEL: polly.loop_preheader:                             ; preds = %entry
 ; KERNEL-IR-NEXT:   br label %polly.loop_header

 ; KERNEL-IR: attributes #0 = { "polly.skip.fn" }

 ; KERNEL-ASM: .version 3.2
 ; KERNEL-ASM-NEXT: .target sm_30
 ; KERNEL-ASM-NEXT: .address_size 64

 ; KERNEL-ASM:   // .globl     kernel_0

 ; KERNEL-ASM: .visible .entry kernel_0(
 ; KERNEL-ASM-NEXT:   .param .u64 kernel_0_param_0
 ; KERNEL-ASM-NEXT: )

 ;    void double_parallel_loop(float A[][1024]) {
 ;      for (long i = 0; i < 1024; i++)
 ;        for (long j = 0; j < 1024; j++)
 ;          A[i][j] += i * j;
 ;    }
 ;
 target datalayout = "e-m:e-i64:64-f80:128-n8:16:32:64-S128"

 define void @double_parallel_loop([1024 x float]* %A) {
 bb:
   br label %bb2

 bb2:                                              ; preds = %bb13, %bb
   %i.0 = phi i64 [ 0, %bb ], [ %tmp14, %bb13 ]
   %exitcond1 = icmp ne i64 %i.0, 1024
   br i1 %exitcond1, label %bb3, label %bb15

 bb3:                                              ; preds = %bb2
   br label %bb4

 bb4:                                              ; preds = %bb10, %bb3
   %j.0 = phi i64 [ 0, %bb3 ], [ %tmp11, %bb10 ]
   %exitcond = icmp ne i64 %j.0, 1024
   br i1 %exitcond, label %bb5, label %bb12

 bb5:                                              ; preds = %bb4
   %tmp = mul nuw nsw i64 %i.0, %j.0
   %tmp6 = sitofp i64 %tmp to float
   %tmp7 = getelementptr inbounds [1024 x float], [1024 x float]* %A, i64 %i.0, i64 %j.0
   %tmp8 = load float, float* %tmp7, align 4
   %tmp9 = fadd float %tmp8, %tmp6
   store float %tmp9, float* %tmp7, align 4
   br label %bb10

 bb10:                                             ; preds = %bb5
   %tmp11 = add nuw nsw i64 %j.0, 1
   br label %bb4

 bb12:                                             ; preds = %bb4
   br label %bb13

 bb13:                                             ; preds = %bb12
   %tmp14 = add nuw nsw i64 %i.0, 1
   br label %bb2

 bb15:                                             ; preds = %bb2
   ret void
 }
	; RUN: opt %loadPolly -polly-scops -analyze < %s \| FileCheck %s
	; RUN: opt %loadPolly -polly-codegen-ppcg -polly-acc-dump-schedule \
	; RUN: -disable-output < %s \| \
	; RUN: FileCheck -check-prefix=SCHED %s

	; RUN: opt %loadPolly -polly-codegen-ppcg -polly-acc-dump-code \
	; RUN: -disable-output < %s \| \
	; RUN: FileCheck -check-prefix=CODE %s

	; RUN: opt %loadPolly -polly-codegen-ppcg -S < %s \| \
	; RUN: FileCheck %s -check-prefix=IR

	; RUN: opt %loadPolly -polly-codegen-ppcg -polly-acc-dump-kernel-ir \
	; RUN: -disable-output < %s \| \
	; RUN: FileCheck %s -check-prefix=KERNEL-IR

	; RUN: opt %loadPolly -polly-codegen-ppcg -polly-acc-dump-kernel-asm \
	; RUN: -disable-output < %s \| \
	; RUN: FileCheck %s -check-prefix=KERNEL-ASM

	; REQUIRES: pollyacc,nvptx

	; CHECK: Stmt_bb5
	; CHECK-NEXT: Domain :=
	; CHECK-NEXT: { Stmt_bb5[i0, i1] : 0 <= i0 <= 1023 and 0 <= i1 <= 1023 };
	; CHECK-NEXT: Schedule :=
	; CHECK-NEXT: { Stmt_bb5[i0, i1] -> [i0, i1] };
	; CHECK-NEXT: ReadAccess := [Reduction Type: NONE] [Scalar: 0]
	; CHECK-NEXT: { Stmt_bb5[i0, i1] -> MemRef_A[i0, i1] };
	; CHECK-NEXT: MustWriteAccess := [Reduction Type: NONE] [Scalar: 0]
	; CHECK-NEXT: { Stmt_bb5[i0, i1] -> MemRef_A[i0, i1] };

	; SCHED: domain: "{ Stmt_bb5[i0, i1] : 0 <= i0 <= 1023 and 0 <= i1 <= 1023 }"
	; SCHED-NEXT: child:
	; SCHED-NEXT: context: "{ [] }"
	; SCHED-NEXT: child:
	; SCHED-NEXT: extension: "{ [] -> from_device_MemRef_A[]; [] -> to_device_MemRef_A[] }"
	; SCHED-NEXT: child:
	; SCHED-NEXT: sequence:
	; SCHED-NEXT: - filter: "{ to_device_MemRef_A[] }"
	; SCHED-NEXT: child:
	; SCHED-NEXT: set:
	; SCHED-NEXT: - filter: "{ to_device_MemRef_A[] }"
	; SCHED-NEXT: child:
	; SCHED-NEXT: guard: "{ [] }"
	; SCHED-NEXT: - filter: "{ Stmt_bb5[i0, i1] }"
	; SCHED-NEXT: child:
	; SCHED-NEXT: guard: "{ [] }"
	; SCHED-NEXT: child:
	; SCHED-NEXT: mark: "kernel"
	; SCHED-NEXT: child:
	; SCHED-NEXT: context: "[b0, b1, t0, t1] -> { [] : 0 <= b0 <= 31 and 0 <= b1 <= 31 and 0 <= t0 <= 31 and 0 <= t1 <= 15 }"
	; SCHED-NEXT: child:
	; SCHED-NEXT: filter: "[b0, b1] -> { Stmt_bb5[i0, i1] : -31 - 32b0 + i0 <= 8192floor((i0)/8192) <= -32b0 + i0 and -31 - 32b1 + i1 <= 8192floor((i1)/8192) <= -32b1 + i1 }"
	; SCHED-NEXT: child:
	; SCHED-NEXT: schedule: "[{ Stmt_bb5[i0, i1] -> [(floor((i0)/8192))] }, { Stmt_bb5[i0, i1] -> [(floor((i1)/8192))] }]"
	; SCHED-NEXT: permutable: 1
	; SCHED-NEXT: coincident: [ 1, 1 ]
	; SCHED-NEXT: child:
	; SCHED-NEXT: filter: "[t0, t1] -> { Stmt_bb5[i0, i1] : 32floor((-t0 + i0)/32) = -t0 + i0 and 16floor((-t1 + i1)/16) = -t1 + i1 and 0 <= t0 <= 31 and 0 <= t1 <= 15 }"
	; SCHED-NEXT: child:
	; SCHED-NEXT: schedule: "[{ Stmt_bb5[i0, i1] -> [(0)] }, { Stmt_bb5[i0, i1] -> [(floor((i1)/16) - 2*floor((i1)/32))] }]"
	; SCHED-NEXT: permutable: 1
	; SCHED-NEXT: coincident: [ 1, 1 ]
	; SCHED-NEXT: - filter: "{ from_device_MemRef_A[] }"
	; SCHED-NEXT: child:
	; SCHED-NEXT: set:
	; SCHED-NEXT: - filter: "{ from_device_MemRef_A[] }"
	; SCHED-NEXT: child:
	; SCHED-NEXT: guard: "{ [] }"

	; CODE: Code
	; CODE-NEXT: ====
	; CODE-NEXT: # host
	; CODE-NEXT: {
	; CODE-NEXT: cudaCheckReturn(cudaMemcpy(dev_MemRef_A, MemRef_A, (1024) * (1024) * sizeof(float), cudaMemcpyHostToDevice));
	; CODE-NEXT: {
	; CODE-NEXT: dim3 k0_dimBlock(16, 32);
	; CODE-NEXT: dim3 k0_dimGrid(32, 32);
	; CODE-NEXT: kernel0 <<<k0_dimGrid, k0_dimBlock>>> (dev_MemRef_A);
	; CODE-NEXT: cudaCheckKernel();
	; CODE-NEXT: }

	; CODE: cudaCheckReturn(cudaMemcpy(MemRef_A, dev_MemRef_A, (1024) * (1024) * sizeof(float), cudaMemcpyDeviceToHost));
	; CODE-NEXT: }

	; CODE: # kernel0
	; CODE-NEXT: for (int c3 = 0; c3 <= 1; c3 += 1)
	; CODE-NEXT: Stmt_bb5(32 * b0 + t0, 32 * b1 + t1 + 16 * c3);

	; IR: polly.split_new_and_old:
	; IR-NEXT: %0 = call { i64, i1 } @llvm.smul.with.overflow.i64(i64 1, i64 1024)
	; IR-NEXT: %.obit = extractvalue { i64, i1 } %0, 1
	; IR-NEXT: %polly.overflow.state = or i1 false, %.obit
	; IR-NEXT: %.res = extractvalue { i64, i1 } %0, 0
	; IR-NEXT: %1 = call { i64, i1 } @llvm.smul.with.overflow.i64(i64 %.res, i64 1024)
	; IR-NEXT: %.obit1 = extractvalue { i64, i1 } %1, 1
	; IR-NEXT: %polly.overflow.state2 = or i1 %polly.overflow.state, %.obit1
	; IR-NEXT: %.res3 = extractvalue { i64, i1 } %1, 0
	; IR-NEXT: %2 = call { i64, i1 } @llvm.smul.with.overflow.i64(i64 7, i64 %.res3)
	; IR-NEXT: %.obit4 = extractvalue { i64, i1 } %2, 1
	; IR-NEXT: %polly.overflow.state5 = or i1 %polly.overflow.state2, %.obit4
	; IR-NEXT: %.res6 = extractvalue { i64, i1 } %2, 0
	; IR-NEXT: %3 = call { i64, i1 } @llvm.sadd.with.overflow.i64(i64 0, i64 %.res6)
	; IR-NEXT: %.obit7 = extractvalue { i64, i1 } %3, 1
	; IR-NEXT: %polly.overflow.state8 = or i1 %polly.overflow.state5, %.obit7
	; IR-NEXT: %.res9 = extractvalue { i64, i1 } %3, 0
	; IR-NEXT: %4 = icmp sge i64 %.res9, 2621440
	; IR-NEXT: %5 = and i1 true, %4
	; IR-NEXT: %polly.rtc.overflown = xor i1 %polly.overflow.state8, true
	; IR-NEXT: %polly.rtc.result = and i1 %5, %polly.rtc.overflown
	; IR-NEXT: br i1 %polly.rtc.result, label %polly.start, label %bb2

	; IR: polly.start:
	; IR-NEXT: br label %polly.acc.initialize

	; IR: polly.acc.initialize:
	; IR-NEXT: [[GPUContext:%.]] = call i8 @polly_initContext()
	; IR-NEXT: %p_dev_array_MemRef_A = call i8* @polly_allocateMemoryForDevice(i64 4194304)
	; IR-NEXT: [[HostPtr:%.]] = bitcast [1024 x float] %A to i8*
	; IR-NEXT: call void @polly_copyFromHostToDevice(i8* [[HostPtr]], i8* %p_dev_array_MemRef_A, i64 4194304)
	; IR-NEXT: [[DevPtr:%.]] = call i8 @polly_getDevicePtr(i8* %p_dev_array_MemRef_A)
	; IR-NEXT: [[ParamSlot:%.]] = getelementptr [1 x i8], [1 x i8] %polly_launch_0_params, i64 0, i64 0
	; IR-NEXT: store i8* [[DevPtr]], i8** %polly_launch_0_param_0
	; IR-NEXT: [[ParamTyped:%.]] = bitcast i8* %polly_launch_0_param_0 to i8*
	; IR-NEXT: store i8* [[ParamTyped]], i8** [[ParamSlot]]
	; IR-NEXT: call i8* @polly_getKernel
	; IR-NEXT: call void @polly_launchKernel(i8* %11, i32 32, i32 32, i32 32, i32 16, i32 1, i8* %polly_launch_0_params_i8ptr)
	; IR-NEXT: call void @polly_freeKernel
	; IR-NEXT: [[HostPtr2:%.]] = bitcast [1024 x float] %A to i8*
	; IR-NEXT: call void @polly_copyFromDeviceToHost(i8* %p_dev_array_MemRef_A, i8* [[HostPtr2]], i64 4194304)
	; IR-NEXT: call void @polly_freeDeviceMemory(i8* %p_dev_array_MemRef_A)
	; IR-NEXT: call void @polly_freeContext(i8* [[GPUContext]])
	; IR-NEXT: br label %polly.exiting

	; IR: polly.exiting:
	; IR-NEXT: br label %polly.merge_new_and_old

	; KERNEL-IR-LABEL: define ptx_kernel void @kernel_0(i8* %MemRef_A) #0 {
	; KERNEL-IR-NEXT: entry:
	; KERNEL-IR-NEXT: %0 = call i32 @llvm.nvvm.read.ptx.sreg.ctaid.x()
	; KERNEL-IR-NEXT: %b0 = zext i32 %0 to i64
	; KERNEL-IR-NEXT: %1 = call i32 @llvm.nvvm.read.ptx.sreg.ctaid.y()
	; KERNEL-IR-NEXT: %b1 = zext i32 %1 to i64
	; KERNEL-IR-NEXT: %2 = call i32 @llvm.nvvm.read.ptx.sreg.tid.x()
	; KERNEL-IR-NEXT: %t0 = zext i32 %2 to i64
	; KERNEL-IR-NEXT: %3 = call i32 @llvm.nvvm.read.ptx.sreg.tid.y()
	; KERNEL-IR-NEXT: %t1 = zext i32 %3 to i64
	; KERNEL-IR-NEXT: br label %polly.loop_preheader

	; KERNEL-IR-LABEL: polly.loop_exit: ; preds = %polly.stmt.bb5
	; KERNEL-IR-NEXT: ret void

	; KERNEL-IR-LABEL: polly.loop_header: ; preds = %polly.stmt.bb5, %polly.loop_preheader
	; KERNEL-IR-NEXT: %polly.indvar = phi i64 [ 0, %polly.loop_preheader ], [ %polly.indvar_next, %polly.stmt.bb5 ]
	; KERNEL-IR-NEXT: %4 = mul nsw i64 32, %b0
	; KERNEL-IR-NEXT: %5 = add nsw i64 %4, %t0
	; KERNEL-IR-NEXT: %6 = mul nsw i64 32, %b1
	; KERNEL-IR-NEXT: %7 = add nsw i64 %6, %t1
	; KERNEL-IR-NEXT: %8 = mul nsw i64 16, %polly.indvar
	; KERNEL-IR-NEXT: %9 = add nsw i64 %7, %8
	; KERNEL-IR-NEXT: br label %polly.stmt.bb5

	; KERNEL-IR-LABEL: polly.stmt.bb5: ; preds = %polly.loop_header
	; KERNEL-IR-NEXT: %10 = mul i64 %5, %9
	; KERNEL-IR-NEXT: %p_tmp6 = sitofp i64 %10 to float
	; KERNEL-IR-NEXT: %polly.access.cast.MemRef_A = bitcast i8* %MemRef_A to float*
	; KERNEL-IR-NEXT: %11 = mul nsw i64 32, %b0
	; KERNEL-IR-NEXT: %12 = add nsw i64 %11, %t0
	; KERNEL-IR-NEXT: %polly.access.mul.MemRef_A = mul nsw i64 %12, 1024
	; KERNEL-IR-NEXT: %13 = mul nsw i64 32, %b1
	; KERNEL-IR-NEXT: %14 = add nsw i64 %13, %t1
	; KERNEL-IR-NEXT: %15 = mul nsw i64 16, %polly.indvar
	; KERNEL-IR-NEXT: %16 = add nsw i64 %14, %15
	; KERNEL-IR-NEXT: %polly.access.add.MemRef_A = add nsw i64 %polly.access.mul.MemRef_A, %16
	; KERNEL-IR-NEXT: %polly.access.MemRef_A = getelementptr float, float* %polly.access.cast.MemRef_A, i64 %polly.access.add.MemRef_A
	; KERNEL-IR-NEXT: %tmp8_p_scalar_ = load float, float* %polly.access.MemRef_A, align 4
	; KERNEL-IR-NEXT: %p_tmp9 = fadd float %tmp8_p_scalar_, %p_tmp6
	; KERNEL-IR-NEXT: %polly.access.cast.MemRef_A1 = bitcast i8* %MemRef_A to float*
	; KERNEL-IR-NEXT: %17 = mul nsw i64 32, %b0
	; KERNEL-IR-NEXT: %18 = add nsw i64 %17, %t0
	; KERNEL-IR-NEXT: %polly.access.mul.MemRef_A2 = mul nsw i64 %18, 1024
	; KERNEL-IR-NEXT: %19 = mul nsw i64 32, %b1
	; KERNEL-IR-NEXT: %20 = add nsw i64 %19, %t1
	; KERNEL-IR-NEXT: %21 = mul nsw i64 16, %polly.indvar
	; KERNEL-IR-NEXT: %22 = add nsw i64 %20, %21
	; KERNEL-IR-NEXT: %polly.access.add.MemRef_A3 = add nsw i64 %polly.access.mul.MemRef_A2, %22
	; KERNEL-IR-NEXT: %polly.access.MemRef_A4 = getelementptr float, float* %polly.access.cast.MemRef_A1, i64 %polly.access.add.MemRef_A3
	; KERNEL-IR-NEXT: store float %p_tmp9, float* %polly.access.MemRef_A4, align 4
	; KERNEL-IR-NEXT: %polly.indvar_next = add nsw i64 %polly.indvar, 1
	; KERNEL-IR-NEXT: %polly.loop_cond = icmp sle i64 %polly.indvar, 0
	; KERNEL-IR-NEXT: br i1 %polly.loop_cond, label %polly.loop_header, label %polly.loop_exit

	; KERNEL-IR-LABEL: polly.loop_preheader: ; preds = %entry
	; KERNEL-IR-NEXT: br label %polly.loop_header

	; KERNEL-IR: attributes #0 = { "polly.skip.fn" }

	; KERNEL-ASM: .version 3.2
	; KERNEL-ASM-NEXT: .target sm_30
	; KERNEL-ASM-NEXT: .address_size 64

	; KERNEL-ASM: // .globl kernel_0

	; KERNEL-ASM: .visible .entry kernel_0(
	; KERNEL-ASM-NEXT: .param .u64 kernel_0_param_0
	; KERNEL-ASM-NEXT: )

	; void double_parallel_loop(float A[][1024]) {
	; for (long i = 0; i < 1024; i++)
	; for (long j = 0; j < 1024; j++)
	; A[i][j] += i * j;
	; }
	;
	target datalayout = "e-m:e-i64:64-f80:128-n8:16:32:64-S128"

	define void @double_parallel_loop([1024 x float]* %A) {
	bb:
	br label %bb2

	bb2: ; preds = %bb13, %bb
	%i.0 = phi i64 [ 0, %bb ], [ %tmp14, %bb13 ]
	%exitcond1 = icmp ne i64 %i.0, 1024
	br i1 %exitcond1, label %bb3, label %bb15

	bb3: ; preds = %bb2
	br label %bb4

	bb4: ; preds = %bb10, %bb3
	%j.0 = phi i64 [ 0, %bb3 ], [ %tmp11, %bb10 ]
	%exitcond = icmp ne i64 %j.0, 1024
	br i1 %exitcond, label %bb5, label %bb12

	bb5: ; preds = %bb4
	%tmp = mul nuw nsw i64 %i.0, %j.0
	%tmp6 = sitofp i64 %tmp to float
	%tmp7 = getelementptr inbounds [1024 x float], [1024 x float]* %A, i64 %i.0, i64 %j.0
	%tmp8 = load float, float* %tmp7, align 4
	%tmp9 = fadd float %tmp8, %tmp6
	store float %tmp9, float* %tmp7, align 4
	br label %bb10

	bb10: ; preds = %bb5
	%tmp11 = add nuw nsw i64 %j.0, 1
	br label %bb4

	bb12: ; preds = %bb4
	br label %bb13

	bb13: ; preds = %bb12
	%tmp14 = add nuw nsw i64 %i.0, 1
	br label %bb2

	bb15: ; preds = %bb2
	ret void
	}