mlir/test/Dialect/Linalg/comprehensive-module-bufferize-invalid.mlir - llvm-project - Git at Google

 // RUN: mlir-opt %s -allow-unregistered-dialect -linalg-comprehensive-module-bufferize -split-input-file -verify-diagnostics

 func private @foo() -> tensor<?xf32>

 func @bar() -> tensor<?xf32> {
   %foo = constant @foo : () -> (tensor<?xf32>)
 // expected-error @+1 {{expected a CallOp}}
   %res = call_indirect %foo() : () -> (tensor<?xf32>)
   return %res : tensor<?xf32>
 }

 // -----

 // expected-error @+1 {{cannot bufferize bodiless function that returns a tensor}}
 func private @foo() -> tensor<?xf32>

 // -----

 // expected-error @+1 {{cannot bufferize a FuncOp with tensors and without a unique ReturnOp}}
 func @swappy(%cond1 : i1, %cond2 : i1, %t1 : tensor<f32>, %t2 : tensor<f32>)
     -> (tensor<f32>, tensor<f32>)
 {
   cond_br %cond1, ^bb1, ^bb2

   ^bb1:
     %T:2 = scf.if %cond2 -> (tensor<f32>, tensor<f32>) {
       scf.yield %t1, %t2 : tensor<f32>, tensor<f32>
     } else {
       scf.yield %t2, %t1 : tensor<f32>, tensor<f32>
     }
     return %T#0, %T#1 : tensor<f32>, tensor<f32>
   ^bb2:
     return %t2, %t1 : tensor<f32>, tensor<f32>
 }

 // -----

 func @scf_if_not_equivalent(
     %cond: i1, %t1: tensor<?xf32> {linalg.inplaceable = true},
     %idx: index) -> tensor<?xf32> {
   // expected-error @+1 {{result buffer is ambiguous}}
   %r = scf.if %cond -> (tensor<?xf32>) {
     scf.yield %t1 : tensor<?xf32>
   } else {
     // This buffer aliases, but is not equivalent.
     %t2 = tensor.extract_slice %t1 [%idx] [%idx] [1] : tensor<?xf32> to tensor<?xf32>
     scf.yield %t2 : tensor<?xf32>
   }
   return %r : tensor<?xf32>
 }

 // -----

 // expected-error @-3 {{expected callgraph to be free of circular dependencies}}

 func @foo() {
   call @bar() : () -> ()
   return
 }

 func @bar() {
   call @foo() : () -> ()
   return
 }

 // -----

 func @scf_for(%A : tensor<?xf32>,
               %B : tensor<?xf32> {linalg.inplaceable = true},
               %C : tensor<4xf32>,
               %lb : index, %ub : index, %step : index)
   -> (tensor<?xf32>, tensor<?xf32>)
 {
   %r0:2 = scf.for %i = %lb to %ub step %step iter_args(%tA = %A, %tB = %B)
       -> (tensor<?xf32>, tensor<?xf32>)
   {
     %ttA = tensor.insert_slice %C into %tA[0][4][1] : tensor<4xf32> into tensor<?xf32>
     %ttB = tensor.insert_slice %C into %tB[0][4][1] : tensor<4xf32> into tensor<?xf32>

     // Throw a wrench in the system by swapping yielded values: this result in a
     // ping-pong of values at each iteration on which we currently want to fail.

     // expected-error @+1 {{Yield operand #0 does not bufferize to an equivalent buffer}}
     scf.yield %ttB, %ttA : tensor<?xf32>, tensor<?xf32>
   }

   return %r0#0, %r0#1: tensor<?xf32>, tensor<?xf32>
 }

 // -----

 func private @fun_with_side_effects(%A: tensor<?xf32> {linalg.inplaceable = true})

 func @foo(%A: tensor<?xf32> {linalg.inplaceable = true}) -> (tensor<?xf32>) {
   call @fun_with_side_effects(%A) : (tensor<?xf32>) -> ()
   return %A: tensor<?xf32>
 }

 func @scf_yield_needs_copy(%A : tensor<?xf32> {linalg.inplaceable = true}, %iters : index) {
   %c0 = arith.constant 0 : index
   %c1 = arith.constant 1 : index
   %res = scf.for %arg0 = %c0 to %iters step %c1 iter_args(%bbarg = %A) -> (tensor<?xf32>) {
     %r = call @foo(%A) : (tensor<?xf32>) -> (tensor<?xf32>)
     // expected-error @+1 {{Yield operand #0 does not bufferize to an equivalent buffer}}
     scf.yield %r : tensor<?xf32>
   }
   call @fun_with_side_effects(%res) : (tensor<?xf32>) -> ()
   return
 }

 // -----

 func @extract_slice_fun(%A : tensor<?xf32> {linalg.inplaceable = true})
   ->  tensor<4xf32>
 {
   // This bufferizes to a pattern that the cross-function boundary pass needs to
   // convert into a new memref argument at all call site; this may be either:
   //   - an externally created aliasing subview (if we want to allow aliasing
   //     function arguments).
   //   - a new alloc + copy (more expensive but does not create new function
   //     argument aliasing).
   %r0 = tensor.extract_slice %A[0][4][1] : tensor<?xf32> to tensor<4xf32>

   // expected-error @+1 {{buffer result #0 not produced by an alloc}}
   return %r0: tensor<4xf32>
 }

 // -----

 func @scf_yield(%b : i1, %A : tensor<4xf32>, %B : tensor<4xf32>) -> tensor<4xf32>
 {
   // expected-error @+1 {{result buffer is ambiguous}}
   %r = scf.if %b -> (tensor<4xf32>) {
     scf.yield %A : tensor<4xf32>
   } else {
     scf.yield %B : tensor<4xf32>
   }
   return %r: tensor<4xf32>
 }

 // -----

 func @unknown_op(%A : tensor<4xf32>) -> tensor<4xf32>
 {
   // expected-error @+1 {{unsupported op with tensors}}
   %r = "marklar"(%A) : (tensor<4xf32>) -> (tensor<4xf32>)
   return %r: tensor<4xf32>
 }

 // -----

 // expected-error @+1 {{memref return type is unsupported}}
 func @mini_test_case1() -> tensor<10x20xf32> {
   %f0 = arith.constant 0.0 : f32
   %t = linalg.init_tensor [10, 20] : tensor<10x20xf32>
   %r = linalg.fill(%f0, %t) : f32, tensor<10x20xf32> -> tensor<10x20xf32>
   return %r : tensor<10x20xf32>
 }

 // -----

 func @main() -> tensor<4xi32> {
   // expected-error @+1 {{scf.execute_region with tensor result not supported}}
   %r = scf.execute_region -> tensor<4xi32> {
     %A = arith.constant dense<[1, 2, 3, 4]> : tensor<4xi32>
     scf.yield %A: tensor<4xi32>
   }
   return %r: tensor<4xi32>
 }
	// RUN: mlir-opt %s -allow-unregistered-dialect -linalg-comprehensive-module-bufferize -split-input-file -verify-diagnostics

	func private @foo() -> tensor<?xf32>

	func @bar() -> tensor<?xf32> {
	%foo = constant @foo : () -> (tensor<?xf32>)
	// expected-error @+1 {{expected a CallOp}}
	%res = call_indirect %foo() : () -> (tensor<?xf32>)
	return %res : tensor<?xf32>
	}

	// -----

	// expected-error @+1 {{cannot bufferize bodiless function that returns a tensor}}
	func private @foo() -> tensor<?xf32>

	// -----

	// expected-error @+1 {{cannot bufferize a FuncOp with tensors and without a unique ReturnOp}}
	func @swappy(%cond1 : i1, %cond2 : i1, %t1 : tensor<f32>, %t2 : tensor<f32>)
	-> (tensor<f32>, tensor<f32>)
	{
	cond_br %cond1, ^bb1, ^bb2

	^bb1:
	%T:2 = scf.if %cond2 -> (tensor<f32>, tensor<f32>) {
	scf.yield %t1, %t2 : tensor<f32>, tensor<f32>
	} else {
	scf.yield %t2, %t1 : tensor<f32>, tensor<f32>
	}
	return %T#0, %T#1 : tensor<f32>, tensor<f32>
	^bb2:
	return %t2, %t1 : tensor<f32>, tensor<f32>
	}

	// -----

	func @scf_if_not_equivalent(
	%cond: i1, %t1: tensor<?xf32> {linalg.inplaceable = true},
	%idx: index) -> tensor<?xf32> {
	// expected-error @+1 {{result buffer is ambiguous}}
	%r = scf.if %cond -> (tensor<?xf32>) {
	scf.yield %t1 : tensor<?xf32>
	} else {
	// This buffer aliases, but is not equivalent.
	%t2 = tensor.extract_slice %t1 [%idx] [%idx] [1] : tensor<?xf32> to tensor<?xf32>
	scf.yield %t2 : tensor<?xf32>
	}
	return %r : tensor<?xf32>
	}

	// -----

	// expected-error @-3 {{expected callgraph to be free of circular dependencies}}

	func @foo() {
	call @bar() : () -> ()
	return
	}

	func @bar() {
	call @foo() : () -> ()
	return
	}

	// -----

	func @scf_for(%A : tensor<?xf32>,
	%B : tensor<?xf32> {linalg.inplaceable = true},
	%C : tensor<4xf32>,
	%lb : index, %ub : index, %step : index)
	-> (tensor<?xf32>, tensor<?xf32>)
	{
	%r0:2 = scf.for %i = %lb to %ub step %step iter_args(%tA = %A, %tB = %B)
	-> (tensor<?xf32>, tensor<?xf32>)
	{
	%ttA = tensor.insert_slice %C into %tA[0][4][1] : tensor<4xf32> into tensor<?xf32>
	%ttB = tensor.insert_slice %C into %tB[0][4][1] : tensor<4xf32> into tensor<?xf32>

	// Throw a wrench in the system by swapping yielded values: this result in a
	// ping-pong of values at each iteration on which we currently want to fail.

	// expected-error @+1 {{Yield operand #0 does not bufferize to an equivalent buffer}}
	scf.yield %ttB, %ttA : tensor<?xf32>, tensor<?xf32>
	}

	return %r0#0, %r0#1: tensor<?xf32>, tensor<?xf32>
	}

	// -----

	func private @fun_with_side_effects(%A: tensor<?xf32> {linalg.inplaceable = true})

	func @foo(%A: tensor<?xf32> {linalg.inplaceable = true}) -> (tensor<?xf32>) {
	call @fun_with_side_effects(%A) : (tensor<?xf32>) -> ()
	return %A: tensor<?xf32>
	}

	func @scf_yield_needs_copy(%A : tensor<?xf32> {linalg.inplaceable = true}, %iters : index) {
	%c0 = arith.constant 0 : index
	%c1 = arith.constant 1 : index
	%res = scf.for %arg0 = %c0 to %iters step %c1 iter_args(%bbarg = %A) -> (tensor<?xf32>) {
	%r = call @foo(%A) : (tensor<?xf32>) -> (tensor<?xf32>)
	// expected-error @+1 {{Yield operand #0 does not bufferize to an equivalent buffer}}
	scf.yield %r : tensor<?xf32>
	}
	call @fun_with_side_effects(%res) : (tensor<?xf32>) -> ()
	return
	}

	// -----

	func @extract_slice_fun(%A : tensor<?xf32> {linalg.inplaceable = true})
	-> tensor<4xf32>
	{
	// This bufferizes to a pattern that the cross-function boundary pass needs to
	// convert into a new memref argument at all call site; this may be either:
	// - an externally created aliasing subview (if we want to allow aliasing
	// function arguments).
	// - a new alloc + copy (more expensive but does not create new function
	// argument aliasing).
	%r0 = tensor.extract_slice %A[0][4][1] : tensor<?xf32> to tensor<4xf32>

	// expected-error @+1 {{buffer result #0 not produced by an alloc}}
	return %r0: tensor<4xf32>
	}

	// -----

	func @scf_yield(%b : i1, %A : tensor<4xf32>, %B : tensor<4xf32>) -> tensor<4xf32>
	{
	// expected-error @+1 {{result buffer is ambiguous}}
	%r = scf.if %b -> (tensor<4xf32>) {
	scf.yield %A : tensor<4xf32>
	} else {
	scf.yield %B : tensor<4xf32>
	}
	return %r: tensor<4xf32>
	}

	// -----

	func @unknown_op(%A : tensor<4xf32>) -> tensor<4xf32>
	{
	// expected-error @+1 {{unsupported op with tensors}}
	%r = "marklar"(%A) : (tensor<4xf32>) -> (tensor<4xf32>)
	return %r: tensor<4xf32>
	}

	// -----

	// expected-error @+1 {{memref return type is unsupported}}
	func @mini_test_case1() -> tensor<10x20xf32> {
	%f0 = arith.constant 0.0 : f32
	%t = linalg.init_tensor [10, 20] : tensor<10x20xf32>
	%r = linalg.fill(%f0, %t) : f32, tensor<10x20xf32> -> tensor<10x20xf32>
	return %r : tensor<10x20xf32>
	}

	// -----

	func @main() -> tensor<4xi32> {
	// expected-error @+1 {{scf.execute_region with tensor result not supported}}
	%r = scf.execute_region -> tensor<4xi32> {
	%A = arith.constant dense<[1, 2, 3, 4]> : tensor<4xi32>
	scf.yield %A: tensor<4xi32>
	}
	return %r: tensor<4xi32>
	}