#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace torch { namespace jit { namespace { Node* findNode(std::shared_ptr& g, Symbol k) { DepthFirstGraphNodeIterator graph_it(g); for (auto node = graph_it.next(); node != nullptr; node = graph_it.next()) { if (node->kind() == k) { return node; } } TORCH_INTERNAL_ASSERT(false, "Couldn't find node"); } } // namespace TEST(ShapeAnalysisTest, DynamicShapesFusion) { // Test Generalizing shapes to symbolic dimensions, guarding those symbolic // dimensions and passing in runtime computed symbolic dimensions via inlined // shape functions std::shared_ptr subgraph = std::make_shared(); const auto graph_string = R"IR( graph(%x.1 : Tensor, %y.1 : Tensor, %z: Tensor): %11 : int = prim::Constant[value=0]() %3 : Tensor = aten::tanh(%x.1) %out1.1 : Tensor = aten::erf(%3) %out2.1 : Tensor = aten::relu(%y.1) %10 : Tensor[] = prim::ListConstruct(%out1.1, %out2.1) %25 : Tensor = aten::cat(%10, %11) %28 : Tensor = aten::hardswish(%25) %29 : Tensor = aten::mul(%28, %z) return (%28))IR"; torch::jit::parseIR(graph_string, subgraph.get()); /* set up fused TensorExprGroup */ std::shared_ptr g = std::make_shared(); auto x_inp = g->addInput("x_inp"); auto y_inp = g->addInput("y_inp"); auto z_inp = g->addInput("z_inp"); auto x_type = TensorType::create(at::rand({10, 5})); auto y_type = TensorType::create(at::rand({4, 5})); auto z_type = TensorType::create(at::rand({1, 1})); x_inp->setType(x_type); y_inp->setType(y_type); z_inp->setType(z_type); subgraph->inputs().at(0)->setType(x_type); subgraph->inputs().at(1)->setType(y_type); subgraph->inputs().at(2)->setType(z_type); subgraph->outputs().at(0)->setType(TensorType::create(at::rand({14, 5}))); auto output = g->insertNode(g->create(prim::TensorExprGroup))->output(); subgraph->outputs().at(0)->setType(TensorType::create(at::rand({14, 5}))); output->node()->addInput(x_inp); output->node()->addInput(y_inp); output->node()->addInput(z_inp); output->node()->g_(attr::Subgraph, subgraph); auto success = GenerateGuard(output->node()); TORCH_INTERNAL_ASSERT(success); testing::FileCheck() .check("TensorExprDynamicGuard") ->check_next("prim::If") ->check("aten::add") ->check("TensorExprGroup") ->check_same("symbolic_shape_inputs") ->check("block1") ->check("aten::cat") ->run(*g); // clang-format off /* Graph Should Look Something like: (note: strides not yet handled) graph(%x_inp : Float(10, 5, strides=[5, 1], requires_grad=0, device=cpu), %y_inp : Float(4, 5, strides=[5, 1], requires_grad=0, device=cpu), %z_inp : Float(1, 1, strides=[1, 1], requires_grad=0, device=cpu)): %4 : bool = prim::TensorExprDynamicGuard[types=[Float(SS(-2), SS(-3), strides=[5, 1], requires_grad=0, device=cpu), Float(SS(-4), SS(-3), strides=[5, 1], requires_grad=0, device=cpu), Float(1, 1, strides=[1, 1], requires_grad=0, device=cpu)]](%x_inp, %y_inp, %z_inp) %5 : Tensor = prim::If(%4) block0(): %15 : int[] = aten::size(%x_inp) %16 : int[] = aten::size(%y_inp) %17 : int = prim::Constant[value=1]() %18 : int = prim::Constant[value=0]() %elem.3 : int = aten::__getitem__(%15, %18) # :40:10 %elem.5 : int = aten::__getitem__(%15, %17) # :40:10 %elem.11 : int = aten::__getitem__(%16, %18) # :40:10 %cat_dim_size.48 : int = aten::add(%elem.3, %elem.11) # :321:29 %3 : Tensor = prim::TensorExprGroup_0[symbolic_shape_inputs=[-5, -4, -3, -2]](%x_inp, %y_inp, %z_inp, %cat_dim_size.48, %elem.11, %elem.5, %elem.3) -> (%3) block1(): // FallbackGraph is inlined %14 : Tensor = prim::FallbackGraph_1(%x_inp, %y_inp, %z_inp) -> (%14) return () with prim::TensorExprGroup_0 = graph(%x.1 : Float(SS(-2), SS(-3), strides=[5, 1], requires_grad=0, device=cpu), %y.1 : Float(SS(-4), SS(-3), strides=[5, 1], requires_grad=0, device=cpu), %z : Float(1, 1, strides=[1, 1], requires_grad=0, device=cpu), %SS_5 : int, %SS_4 : int, %SS_3 : int, %SS_2 : int): %3 : int = prim::Constant[value=0]() %4 : Tensor(SS(-2), SS(-3)) = aten::tanh(%x.1) %5 : Tensor(SS(-2), SS(-3)) = aten::erf(%4) %6 : Tensor(SS(-4), SS(-3)) = aten::relu(%y.1) %7 : Tensor[] = prim::ListConstruct(%5, %6) %8 : Tensor(SS(-5), SS(-3)) = aten::cat(%7, %3) %9 : Tensor(SS(-5), SS(-3)) = aten::hardswish(%8) %10 : Tensor(SS(-5), SS(-3)) = aten::mul(%9, %z) return (%9) */ // clang-format on DepthFirstGraphNodeIterator graph_it(g); Node* te_group = findNode(g, prim::TensorExprGroup); /* Test that input to the kernel - (10, 5), (4, 5), (1, 1) - are correctly generalized to sym dimensions, and that the output - (10 + 4, 5) correctly preserves non-catted dim as sym shape and catted dim as new sym shape */ auto tensorexpr_graph = te_group->g(attr::Subgraph); auto inp1 = tensorexpr_graph->inputs().at(0)->type()->expect(); auto inp2 = tensorexpr_graph->inputs().at(1)->type()->expect(); auto inp3 = tensorexpr_graph->inputs().at(2)->type()->expect(); auto out = tensorexpr_graph->outputs().at(0)->type()->expect(); // 1 dims are preserved auto inp3_sizes = inp3->sizes().concrete_sizes(); TORCH_INTERNAL_ASSERT(inp3_sizes); TORCH_INTERNAL_ASSERT( inp3_sizes->size() == 2 && inp3_sizes->at(0) == 1 && inp3_sizes->at(1) == 1); // 5 made into sym shape ASSERT_EQ( inp1->symbolic_sizes()[1].value(), inp2->symbolic_sizes()[1].value()); ASSERT_EQ( out->symbolic_sizes()[1].value(), inp2->symbolic_sizes()[1].value()); // 4, 10, 14 are different sym shapes ASSERT_NE( inp1->symbolic_sizes()[0].value(), inp2->symbolic_sizes()[0].value()); ASSERT_NE( out->symbolic_sizes()[0].value(), inp1->symbolic_sizes()[0].value()); ASSERT_NE( out->symbolic_sizes()[0].value(), inp2->symbolic_sizes()[0].value()); /* Test guard behaves correctly at runtime and symbolic shapes are computed correctly. As we don't have TE Kernel support for dynamic shapes we're going to return all of the computed runtime symbolic dimensions as outputs of the graph on guard success, and return None on guard failure */ // Setting up guard to return sym shapes on guard success and None on failure Node* if_node = findNode(g, prim::If); IfView if_v(if_node); if_node->eraseOutput(0); if_v.thenBlock()->eraseOutput(0); if_v.elseBlock()->eraseOutput(0); WithInsertPoint guard(if_node); auto none_val = g->insertConstant(IValue()); auto sym_shapes = te_group->is(Symbol::attr("symbolic_shape_inputs")); auto offset = te_group->inputs().size() - sym_shapes.size(); for (size_t i = 0; i < sym_shapes.size(); ++i) { if_v.thenBlock()->insertOutput(i, te_group->inputs().at(offset + i)); if_v.elseBlock()->insertOutput(i, none_val); if_node->insertOutput(i)->setType(OptionalType::create(IntType::get())); } auto new_outputs = g->createTuple(if_node->outputs())->insertAfter(if_node); g->registerOutput(new_outputs->output()); te_group->destroy(); findNode(g, prim::FallbackGraph)->destroy(); // Testing bad inputs auto first_inp = at::rand({2, 5}); std::vector> second_inps = { {at::rand({3, 4}), at::rand({1, 1})}, // sym shape mismatch {at::rand({5, 2}).transpose(0, 1), at::rand({1, 1})}, // discontiguous {at::zeros({2, 5}).to(at::ScalarType::Int), at::rand({1, 1})}, // wrong dtype {at::rand({2, 5, 1}), at::rand({1, 1})}, // wrong # dims {at::rand({2, 5}).requires_grad_(true), at::rand({1, 1})}, // requires grad {at::rand({2, 5}), at::rand({1, 12})}, // concrete dim mismatch (1) }; if (torch::cuda::is_available()) { second_inps.push_back({at::rand({2, 5}).cuda(), at::rand({1, 1})}); } for (const auto& last_inps : second_inps) { // todo - reusing interpreter across iters gave error Code code(g, ""); InterpreterState interp(code); auto stack = createStack({at::rand({2, 5}), last_inps[0], last_inps[1]}); interp.run(stack); TORCH_INTERNAL_ASSERT(pop(stack).toTuple()->elements().at(0).isNone()); } // Test good inputs Code code(g, ""); InterpreterState interp(code); std::vector inps = { at::rand({2, 5}), at::rand({4, 5}), at::rand({1, 1})}; Stack stack(inps.begin(), inps.end()); interp.run(stack); auto tuple = pop(stack).toTuple(); TORCH_INTERNAL_ASSERT(tuple->elements().at(0).isInt()); // Testing that the sym shape calculation was correct for (size_t i = 0; i < sym_shapes.size(); ++i) { auto sym_shape = sym_shapes[i]; auto computed_value = tuple->elements().at(i).toInt(); if (sym_shape == inp1->symbolic_sizes().at(0).value()) { ASSERT_EQ(computed_value, 2); } else if (sym_shape == inp1->symbolic_sizes().at(1).value()) { ASSERT_EQ(computed_value, 5); } else if (sym_shape == inp2->symbolic_sizes().at(0).value()) { ASSERT_EQ(computed_value, 4); } else if (sym_shape == out->symbolic_sizes().at(0).value()) { ASSERT_EQ(computed_value, 6); } else { TORCH_INTERNAL_ASSERT(false); } } } TEST(ShapeAnalysisTest, MovingConstantOutOfFusionGroups) { std::shared_ptr subgraph = std::make_shared(); const auto graph_string = R"IR( graph(%x.1 : Tensor): %none : NoneType = prim::Constant() %size1 : int = prim::Constant[value=1]() %size10 : int = prim::Constant[value=10]() %sizes : int[] = prim::ListConstruct(%size10, %size1) %device : Device = prim::Constant[value="cpu"]() %10 : Tensor = aten::ones(%sizes, %none, %none, %device, %none) %3 : Tensor = aten::tanh(%x.1) %29 : Tensor = aten::mul(%3, %10) return (%29))IR"; torch::jit::parseIR(graph_string, subgraph.get()); ConstantPropagation(subgraph); std::shared_ptr g = std::make_shared(); auto x_inp = g->addInput("x_inp"); auto x_type = TensorType::create(at::rand({10, 5})); x_inp->setType(x_type); subgraph->inputs().at(0)->setType(x_type); subgraph->outputs().at(0)->setType(x_type); auto output = g->insertNode(g->create(prim::TensorExprGroup))->output(); output->node()->addInput(x_inp); output->node()->g_(attr::Subgraph, subgraph); auto success = GenerateGuard(output->node()); TORCH_INTERNAL_ASSERT(success); // Check that the constants have been moved out of the fused graph. // This should result in not have any conditionals other than the one // checking the result of TensorExprDynamicGuard. testing::FileCheck() .check("TensorExprDynamicGuard") ->check_next("prim::If") ->check_not("prim::If") // no other IFs due to constants. ->check("TensorExprGroup") ->check("block1") ->check("FallbackGraph") ->run(*g); } namespace { std::optional sym_dim = std::nullopt; // NOLINTNEXTLINE(bugprone-easily-swappable-parameters) void assertShapeEqual(c10::SymbolicShape& a, c10::SymbolicShape& e) { auto a_canonical = CanonicalizedSymbolicShape(a); auto e_canonical = CanonicalizedSymbolicShape(e); EXPECT_EQ(a_canonical, e_canonical); } void assertShapeEqual( std::optional>& actual, std::vector> expected) { ASSERT_TRUE(actual.has_value()); ASSERT_EQ(actual->size(), 1); auto symb_expected = c10::SymbolicShape(expected); assertShapeEqual(actual->at(0), symb_expected); } const FunctionSchema* getSchema(const char* name) { return &(getOperatorForLiteral(name)->schema()); } } // namespace TEST(ShapeAnalysisTest, SymbolicShapeAPI) { // Figure out how to fetch a function schema // Ask someone else how to create a function schema / operator in C++ auto schema = getSchema( "aten::sub.Tensor(Tensor self, Tensor other, *, Scalar alpha=1) -> Tensor"); c10::IValue const_size_1 = std::vector{64, 56, 56}; c10::IValue const_size_2 = std::vector{1, 56, 56}; // Check vector initializer list syntax c10::SymbolicShape ss_concrete = std::vector>{1, 56, 56}; c10::SymbolicShape ss1 = std::vector>{sym_dim, 56, 56}; c10::SymbolicShape ss2 = std::vector>{64, sym_dim, sym_dim}; c10::SymbolicShape ss3 = std::vector>{sym_dim, sym_dim, sym_dim, sym_dim}; auto res = calculateSymbolicShapesOnOp( schema, std::vector{const_size_1, const_size_1}); assertShapeEqual(res, {64, 56, 56}); res = calculateSymbolicShapesOnOp( schema, std::vector{const_size_1, const_size_2}); assertShapeEqual(res, {64, 56, 56}); res = calculateSymbolicShapesOnOp( schema, std::vector{const_size_1, ss1}); assertShapeEqual(res, {64, 56, 56}); res = calculateSymbolicShapesOnOp( schema, std::vector{const_size_2, ss1}); assertShapeEqual(res, {sym_dim, 56, 56}); res = calculateSymbolicShapesOnOp( schema, std::vector{ss_concrete, ss2}); assertShapeEqual(res, {64, 56, 56}); res = calculateSymbolicShapesOnOp(schema, std::vector{ss2, ss3}); assertShapeEqual(res, {sym_dim, 64, sym_dim, sym_dim}); } TEST(ShapeAnalysisTest, BoundedSymbolicShapes) { auto schema = getSchema("aten::nonzero(Tensor self) -> (Tensor)"); // Test that we generate symbolic shapes for the output of a nonzero op c10::IValue const_size_1 = std::vector{5, 10}; auto res = calculateSymbolicShapesOnOp(schema, std::vector{const_size_1}); assertShapeEqual(res, {sym_dim, 2}); // Test that nonzero can also create concrete shapes c10::IValue const_size_2 = std::vector({1, 0}); res = calculateSymbolicShapesOnOp(schema, std::vector{const_size_2}); assertShapeEqual(res, {0, 2}); } TEST(ShapeAnalysisTest, SymbolicShapeCaching) { clear_shape_cache(); auto schema = getSchema("aten::mm(Tensor self, Tensor mat2) -> Tensor"); c10::IValue const_size_1 = std::vector{64, 56}; c10::IValue const_size_2 = std::vector{64, 56}; c10::IValue const_size_3 = std::vector{64, 20}; c10::SymbolicShape ss1 = c10::SymbolicShape({sym_dim, 64}); c10::SymbolicShape ss2 = c10::SymbolicShape({sym_dim, 64}); c10::SymbolicShape ss3 = c10::SymbolicShape({sym_dim, sym_dim}); auto res = calculateSymbolicShapesOnOp(schema, {ss1, const_size_1}); assertShapeEqual(res, {sym_dim, 56}); auto res1_val = res->at(0); // The exact same arguments should return the exact same result res = calculateSymbolicShapesOnOp(schema, {ss1, const_size_1}); auto res2_val = res->at(0); EXPECT_EQ(res1_val, res2_val); EXPECT_EQ(get_shape_cache_size(), 1); // Same shape but different symbols should return same shape // but different symbolic indices res = calculateSymbolicShapesOnOp(schema, {ss2, const_size_2}); auto res3_val = res->at(0); assertShapeEqual(res3_val, res2_val); EXPECT_NE(res3_val, res2_val); EXPECT_EQ(get_shape_cache_size(), 1); // Different concrete shape should be cached separately res = calculateSymbolicShapesOnOp(schema, {ss1, const_size_3}); assertShapeEqual(res, {sym_dim, 20}); EXPECT_EQ(get_shape_cache_size(), 2); res = calculateSymbolicShapesOnOp(schema, {ss3, const_size_3}); assertShapeEqual(res, {sym_dim, 20}); EXPECT_EQ(get_shape_cache_size(), 3); res = calculateSymbolicShapesOnOp(schema, {ss3, ss3}); assertShapeEqual(res, {sym_dim, sym_dim}); EXPECT_EQ(get_shape_cache_size(), 4); } TEST(ShapeAnalysisTest, ShapeCacheMultipleFns) { clear_shape_cache(); auto squeeze_op = getSchema("aten::squeeze.dim(Tensor(a) self, int dim) -> Tensor(a)"); auto mul_tensor = getSchema("aten::mul.Tensor(Tensor self, Tensor other) -> Tensor"); auto mul_scalar = getSchema("aten::mul.Scalar(Tensor self, Scalar other) -> Tensor"); auto div_tensor = getSchema("aten::div.Tensor(Tensor self, Tensor other) -> Tensor"); auto matmul = getSchema("aten::mm(Tensor self, Tensor mat2) -> Tensor"); c10::IValue const_int = 1; c10::SymbolicShape ss1 = c10::SymbolicShape({sym_dim, 64}); auto res = calculateSymbolicShapesOnOp(squeeze_op, {ss1, const_int}); assertShapeEqual(res, {sym_dim, 64}); // Show that cache can handle multiple functions res = calculateSymbolicShapesOnOp(mul_scalar, {ss1, const_int}); assertShapeEqual(res, {sym_dim, 64}); EXPECT_EQ(get_shape_cache_size(), 2); res = calculateSymbolicShapesOnOp(mul_tensor, {ss1, ss1}); assertShapeEqual(res, {sym_dim, 64}); EXPECT_EQ(get_shape_cache_size(), 3); // Even when the expected outcome is the same, should not collide res = calculateSymbolicShapesOnOp(div_tensor, {ss1, ss1}); assertShapeEqual(res, {sym_dim, 64}); EXPECT_EQ(get_shape_cache_size(), 4); // Don't lose cached objects res = calculateSymbolicShapesOnOp(mul_scalar, {ss1, const_int}); assertShapeEqual(res, {sym_dim, 64}); EXPECT_EQ(get_shape_cache_size(), 4); res = calculateSymbolicShapesOnOp(matmul, {ss1, ss1}); // SSA can infer that sym_dim is 64 as both tensors // use the same sym_dim assertShapeEqual(res, {64, 64}); EXPECT_EQ(get_shape_cache_size(), 5); } TEST(ShapeAnalysisTest, TestShapeMultipleReturns) { clear_shape_cache(); auto max_dim_op = getSchema( "aten::max.dim(Tensor self, int dim, bool keepdim=False) -> (Tensor values, Tensor indices)"); c10::IValue const_int = 1; c10::IValue false_ival = false; c10::SymbolicShape ss1 = c10::SymbolicShape({sym_dim, 64}); c10::SymbolicShape ss2 = c10::SymbolicShape({sym_dim, 64}); auto res = calculateSymbolicShapesOnOp(max_dim_op, {ss1, const_int, false_ival}); c10::SymbolicShape expected_res = c10::SymbolicShape(std::vector>{sym_dim}); assertShapeEqual(res->at(0), expected_res); // res0 and res1 should share the same symbolic symbol EXPECT_EQ(res->at(0), res->at(1)); // Also test that the shape cache also returns consistent result shapes res = calculateSymbolicShapesOnOp(max_dim_op, {ss2, const_int, false_ival}); assertShapeEqual(res->at(0), expected_res); EXPECT_EQ(res->at(0), res->at(1)); EXPECT_EQ(get_shape_cache_size(), 1); } } // namespace jit } // namespace torch