; RUN: llc < %s -march=r600 -mcpu=redwood -verify-machineinstrs | FileCheck %s ; ; This test checks that the lds input queue will is empty at the end of ; the ALU clause. ; CHECK-LABEL: {{^}}lds_input_queue: ; CHECK: LDS_READ_RET * OQAP ; CHECK-NOT: ALU clause ; CHECK: MOV * T{{[0-9]\.[XYZW]}}, OQAP @local_mem = internal unnamed_addr addrspace(3) global [2 x i32] undef, align 4 define void @lds_input_queue(i32 addrspace(1)* %out, i32 addrspace(1)* %in, i32 %index) { entry: %0 = getelementptr inbounds [2 x i32], [2 x i32] addrspace(3)* @local_mem, i32 0, i32 %index %1 = load i32, i32 addrspace(3)* %0 call void @llvm.AMDGPU.barrier.local() ; This will start a new clause for the vertex fetch %2 = load i32, i32 addrspace(1)* %in %3 = add i32 %1, %2 store i32 %3, i32 addrspace(1)* %out ret void } declare void @llvm.AMDGPU.barrier.local() ; The machine scheduler does not do proper alias analysis and assumes that ; loads from global values (Note that a global value is different that a ; value from global memory. A global value is a value that is declared ; outside of a function, it can reside in any address space) alias with ; all other loads. ; ; This is a problem for scheduling the reads from the local data share (lds). ; These reads are implemented using two instructions. The first copies the ; data from lds into the lds output queue, and the second moves the data from ; the input queue into main memory. These two instructions don't have to be ; scheduled one after the other, but they do need to be scheduled in the same ; clause. The aliasing problem mentioned above causes problems when there is a ; load from global memory which immediately follows a load from a global value that ; has been declared in the local memory space: ; ; %0 = getelementptr inbounds [2 x i32], [2 x i32] addrspace(3)* @local_mem, i32 0, i32 %index ; %1 = load i32, i32 addrspace(3)* %0 ; %2 = load i32, i32 addrspace(1)* %in ; ; The instruction selection phase will generate ISA that looks like this: ; %OQAP = LDS_READ_RET ; %vreg0 = MOV %OQAP ; %vreg1 = VTX_READ_32 ; %vreg2 = ADD_INT %vreg1, %vreg0 ; ; The bottom scheduler will schedule the two ALU instructions first: ; ; UNSCHEDULED: ; %OQAP = LDS_READ_RET ; %vreg1 = VTX_READ_32 ; ; SCHEDULED: ; ; vreg0 = MOV %OQAP ; vreg2 = ADD_INT %vreg1, %vreg2 ; ; The lack of proper aliasing results in the local memory read (LDS_READ_RET) ; to consider the global memory read (VTX_READ_32) has a chain dependency, so ; the global memory read will always be scheduled first. This will give us a ; final program which looks like this: ; ; Alu clause: ; %OQAP = LDS_READ_RET ; VTX clause: ; %vreg1 = VTX_READ_32 ; Alu clause: ; vreg0 = MOV %OQAP ; vreg2 = ADD_INT %vreg1, %vreg2 ; ; This is an illegal program because the OQAP def and use know occur in ; different ALU clauses. ; ; This test checks this scenario and makes sure it doesn't result in an ; illegal program. For now, we have fixed this issue by merging the ; LDS_READ_RET and MOV together during instruction selection and then ; expanding them after scheduling. Once the scheduler has better alias ; analysis, we should be able to keep these instructions sparate before ; scheduling. ; ; CHECK-LABEL: {{^}}local_global_alias: ; CHECK: LDS_READ_RET ; CHECK-NOT: ALU clause ; CHECK: MOV * T{{[0-9]\.[XYZW]}}, OQAP define void @local_global_alias(i32 addrspace(1)* %out, i32 addrspace(1)* %in) { entry: %0 = getelementptr inbounds [2 x i32], [2 x i32] addrspace(3)* @local_mem, i32 0, i32 0 %1 = load i32, i32 addrspace(3)* %0 %2 = load i32, i32 addrspace(1)* %in %3 = add i32 %2, %1 store i32 %3, i32 addrspace(1)* %out ret void }