#include #include #include #include #include #include #include #include #include #include #include #include #include "torch/csrc/jit/tensorexpr/eval.h" #include "torch/csrc/jit/tensorexpr/ir.h" namespace torch { namespace jit { using namespace torch::jit::tensorexpr; using SimpleIRExprEval = ExprEval; using namespace torch::indexing; using namespace torch::jit::tensorexpr; class Quantization : public ::testing::Test { public: void SetUp() override { getTEMustUseLLVMOnCPU() = false; } }; TEST_F(Quantization, QuantDequantInt8) { const auto graph_string = R"IR( graph(%x.1 : Float(2, 2, strides=[2, 1], device=cpu)): %2 : int = prim::Constant[value=12]() %3 : int = prim::Constant[value=13]() %4 : float = prim::Constant[value=0.1]() %q.1 : QInt8(2, 2) = aten::quantize_per_tensor(%x.1, %4, %3, %2) %6 : Float(2, 2) = aten::dequantize(%q.1) return (%6))IR"; auto graph = std::make_shared(); parseIR(graph_string, &*graph); auto x = at::rand({2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto q = at::quantize_per_tensor(x, 0.1f, 13, at::kQInt8); auto y_expected = at::dequantize(q); TensorExprKernel k(graph); std::vector inputs = {x}; StmtPtr s = k.getCodeGenStmt(); std::vector stack = fmap(inputs); k.run(stack); auto y = stack[0].toTensor(); bool check = at::allclose(y_expected, y); if (!check) { std::cout << "y_expected:\n" << y_expected << std::endl; std::cout << "y:\n" << y << std::endl; } TORCH_CHECK_EQ(check, 1); } TEST_F(Quantization, QuantDequantUInt8) { const auto graph_string = R"IR( graph(%x.1 : Float(2, 2, strides=[2, 1], device=cpu)): %2 : int = prim::Constant[value=13]() %3 : int = prim::Constant[value=122]() %4 : float = prim::Constant[value=0.1]() %q.1 : QUInt8(2, 2) = aten::quantize_per_tensor(%x.1, %4, %3, %2) %6 : Float(2, 2) = aten::dequantize(%q.1) return (%6))IR"; auto graph = std::make_shared(); parseIR(graph_string, &*graph); auto x = 2 * at::rand({2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto q = at::quantize_per_tensor(x, 0.1f, 122, at::kQUInt8); auto y_expected = at::dequantize(q); TensorExprKernel k(graph); std::vector inputs = {x}; StmtPtr s = k.getCodeGenStmt(); std::vector stack = fmap(inputs); k.run(stack); auto y = stack[0].toTensor(); bool check = at::allclose(y_expected, y); if (!check) { std::cout << "y_expected:\n" << y_expected << std::endl; std::cout << "y:\n" << y << std::endl; } TORCH_CHECK_EQ(check, 1); } TEST_F(Quantization, QuantDequantUInt8_NLC) { const auto graph_string = R"IR( graph(%x.1 : Float(1, 2, 2, strides=[4, 1, 2], device=cpu)): %2 : int = prim::Constant[value=13]() %3 : int = prim::Constant[value=122]() %4 : float = prim::Constant[value=0.1]() %q.1 : QUInt8(1, 2, 2) = aten::quantize_per_tensor(%x.1, %4, %3, %2) %6 : Float(1, 2, 2) = aten::dequantize(%q.1) return (%6))IR"; auto graph = std::make_shared(); parseIR(graph_string, &*graph); auto x = 2 * at::rand({1, 2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); x.unsafeGetTensorImpl()->set_sizes_and_strides( std::initializer_list{1, 2, 2}, {4, 1, 2}); auto q = at::quantize_per_tensor(x, 0.1f, 122, at::kQUInt8); auto y_expected = at::dequantize(q); TensorExprKernel k(graph); std::vector inputs = {x}; StmtPtr s = k.getCodeGenStmt(); std::vector stack = fmap(inputs); k.run(stack); auto y = stack[0].toTensor(); bool check = at::allclose(y_expected, y); if (!check) { std::cout << "x:\n" << x << std::endl; std::cout << "y_expected:\n" << y_expected << std::endl; std::cout << "y:\n" << y << std::endl; } TORCH_CHECK_EQ(check, 1); } at::Tensor quantized_add( at::Tensor x1, at::Tensor x2, double scale, int64_t zero) { const auto qadd_op = c10::Dispatcher::singleton() .findSchemaOrThrow("quantized::add", "") .typed(); return qadd_op.call(x1, x2, scale, zero); } TEST_F(Quantization, QuantAddDequantInt8) { const auto graph_string = R"IR( graph(%x1 : Float(2, 2, strides=[2, 1], device=cpu), %x2 : Float(2, 2, strides=[2, 1], device=cpu)): %2 : int = prim::Constant[value=12]() %qz1 : int = prim::Constant[value=13]() %qs1 : float = prim::Constant[value=0.1]() %qz2 : int = prim::Constant[value=13]() %qs2 : float = prim::Constant[value=0.1]() %qza : int = prim::Constant[value=13]() %qsa : float = prim::Constant[value=0.1]() %q1 : QInt8(2, 2) = aten::quantize_per_tensor(%x1, %qs1, %qz1, %2) %q2 : QInt8(2, 2) = aten::quantize_per_tensor(%x2, %qs2, %qz2, %2) %qa : QInt8(2, 2) = quantized::add(%q1, %q2, %qsa, %qza) %6 : Float(2, 2) = aten::dequantize(%qa) return (%6))IR"; auto graph = std::make_shared(); parseIR(graph_string, &*graph); auto x1 = at::rand({2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto x2 = at::rand({2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto q1 = at::quantize_per_tensor(x1, 0.1f, 13, at::kQInt8); auto q2 = at::quantize_per_tensor(x2, 0.1f, 13, at::kQInt8); auto qa = quantized_add(q1, q2, 0.1f, 13); auto y_expected = at::dequantize(qa); TensorExprKernel k(graph); std::vector inputs = {x1, x2}; StmtPtr s = k.getCodeGenStmt(); std::vector stack = fmap(inputs); k.run(stack); auto y = stack[0].toTensor(); bool check = at::allclose(y_expected, y); if (!check) { std::cout << "x1:\n" << x1 << std::endl; std::cout << "q1:\n" << q1 << std::endl; std::cout << "x2:\n" << x2 << std::endl; std::cout << "q2:\n" << q2 << std::endl; std::cout << "y_expected:\n" << y_expected << std::endl; std::cout << "y:\n" << y << std::endl; } TORCH_CHECK_EQ(check, 1); } TEST_F(Quantization, QuantAddDequantUInt8) { const auto graph_string = R"IR( graph(%x1 : Float(2, 2, strides=[2, 1], device=cpu), %x2 : Float(2, 2, strides=[2, 1], device=cpu)): %2 : int = prim::Constant[value=13]() %qz1 : int = prim::Constant[value=13]() %qs1 : float = prim::Constant[value=0.1]() %qz2 : int = prim::Constant[value=13]() %qs2 : float = prim::Constant[value=0.1]() %qza : int = prim::Constant[value=13]() %qsa : float = prim::Constant[value=0.1]() %q1 : QUInt8(2, 2) = aten::quantize_per_tensor(%x1, %qs1, %qz1, %2) %q2 : QUInt8(2, 2) = aten::quantize_per_tensor(%x2, %qs2, %qz2, %2) %qa : QUInt8(2, 2) = quantized::add(%q1, %q2, %qsa, %qza) %6 : Float(2, 2) = aten::dequantize(%qa) return (%6))IR"; auto graph = std::make_shared(); parseIR(graph_string, &*graph); auto x1 = at::rand({2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto x2 = at::rand({2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto q1 = at::quantize_per_tensor(x1, 0.1f, 13, at::kQUInt8); auto q2 = at::quantize_per_tensor(x2, 0.1f, 13, at::kQUInt8); auto qa = quantized_add(q1, q2, 0.1f, 13); auto y_expected = at::dequantize(qa); TensorExprKernel k(graph); std::vector inputs = {x1, x2}; StmtPtr s = k.getCodeGenStmt(); std::vector stack = fmap(inputs); k.run(stack); auto y = stack[0].toTensor(); bool check = at::allclose(y_expected, y); if (!check) { std::cout << "x1:\n" << x1 << std::endl; std::cout << "q1:\n" << q1 << std::endl; std::cout << "x2:\n" << x2 << std::endl; std::cout << "q2:\n" << q2 << std::endl; std::cout << "y_expected:\n" << y_expected << std::endl; std::cout << "y:\n" << y << std::endl; } TORCH_CHECK_EQ(check, 1); } TEST_F(Quantization, QuantSigmoidDequantUInt8) { const auto graph_string = R"IR( graph(%x1 : Float(2, 2, strides=[2, 1], device=cpu)): %2 : int = prim::Constant[value=13]() %qz1 : int = prim::Constant[value=13]() %qs1 : float = prim::Constant[value=0.1]() %q1 : QUInt8(2, 2) = aten::quantize_per_tensor(%x1, %qs1, %qz1, %2) %qa : QUInt8(2, 2) = aten::sigmoid(%q1) %6 : Float(2, 2) = aten::dequantize(%qa) return (%6))IR"; auto graph = std::make_shared(); parseIR(graph_string, &*graph); auto x1 = at::rand({2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto q1 = at::quantize_per_tensor(x1, 0.1f, 13, at::kQUInt8); auto qs = at::sigmoid(q1); auto y_expected = at::dequantize(qs); TensorExprKernel k(graph); std::vector inputs = {x1}; StmtPtr s = k.getCodeGenStmt(); std::vector stack = fmap(inputs); k.run(stack); auto y = stack[0].toTensor(); bool check = at::allclose(y_expected, y); if (!check) { std::cout << "x1:\n" << x1 << std::endl; std::cout << "q1:\n" << q1 << std::endl; std::cout << "qs:\n" << qs << std::endl; std::cout << "y_expected:\n" << y_expected << std::endl; std::cout << "y:\n" << y << std::endl; } TORCH_CHECK_EQ(check, 1); } at::Tensor quantized_mul( at::Tensor x1, at::Tensor x2, double scale, int64_t zero) { const auto op = c10::Dispatcher::singleton() .findSchemaOrThrow("quantized::mul", "") .typed(); return op.call(x1, x2, scale, zero); } TEST_F(Quantization, QuantMulDequantUInt8) { const auto graph_string = R"IR( graph(%x1 : Float(2, 2, strides=[2, 1], device=cpu), %x2 : Float(2, 2, strides=[2, 1], device=cpu)): %2 : int = prim::Constant[value=13]() %qz1 : int = prim::Constant[value=13]() %qs1 : float = prim::Constant[value=0.1]() %qz2 : int = prim::Constant[value=13]() %qs2 : float = prim::Constant[value=0.1]() %qza : int = prim::Constant[value=13]() %qsa : float = prim::Constant[value=0.1]() %q1 : QUInt8(2, 2) = aten::quantize_per_tensor(%x1, %qs1, %qz1, %2) %q2 : QUInt8(2, 2) = aten::quantize_per_tensor(%x2, %qs2, %qz2, %2) %qa : QUInt8(2, 2) = quantized::mul(%q1, %q2, %qsa, %qza) %6 : Float(2, 2) = aten::dequantize(%qa) return (%6))IR"; auto graph = std::make_shared(); parseIR(graph_string, &*graph); auto x1 = at::rand({2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto x2 = at::rand({2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto q1 = at::quantize_per_tensor(x1, 0.1f, 13, at::kQUInt8); auto q2 = at::quantize_per_tensor(x2, 0.1f, 13, at::kQUInt8); auto qa = quantized_mul(q1, q2, 0.1f, 13); auto y_expected = at::dequantize(qa); TensorExprKernel k(graph); std::vector inputs = {x1, x2}; StmtPtr s = k.getCodeGenStmt(); std::vector stack = fmap(inputs); k.run(stack); auto y = stack[0].toTensor(); bool check = at::allclose(y_expected, y); if (!check) { std::cout << "x1:\n" << x1 << std::endl; std::cout << "q1:\n" << q1 << std::endl; std::cout << "x2:\n" << x2 << std::endl; std::cout << "q2:\n" << q2 << std::endl; std::cout << "y_expected:\n" << y_expected << std::endl; std::cout << "y:\n" << y << std::endl; } TORCH_CHECK_EQ(check, 1); } TEST_F(Quantization, QuantUpsampleNearst2dDequantUInt8) { const auto graph_string = R"IR( graph(%x : Float(1, 1, 4, 4, strides=[16, 16, 4, 1], device=cpu)): %2 : int = prim::Constant[value=13]() %4 : NoneType = prim::Constant() %3 : int[] = prim::Constant[value=[6, 6]]() %qz : int = prim::Constant[value=13]() %qs : float = prim::Constant[value=0.1]() %q : QUInt8(1, 1, 4, 4) = aten::quantize_per_tensor(%x, %qs, %qz, %2) %qu : QUInt8(1, 1, 6, 6) = aten::upsample_nearest2d(%q, %3, %4) %6 : Float(1, 1, 6, 6) = aten::dequantize(%qu) return (%6))IR"; auto graph = std::make_shared(); parseIR(graph_string, &*graph); auto x = at::rand({1, 1, 4, 4}, TensorOptions(kCPU).dtype(at::kFloat)); auto q = at::quantize_per_tensor(x, 0.1f, 13, at::kQUInt8); auto qu = at::upsample_nearest2d(q, {6, 6}); auto y_expected = at::dequantize(qu); TensorExprKernel k(graph); std::vector inputs = {x}; StmtPtr s = k.getCodeGenStmt(); std::vector stack = fmap(inputs); k.run(stack); auto y = stack[0].toTensor(); bool check = at::allclose(y_expected, y); if (!check) { std::cout << "x:\n" << x << std::endl; std::cout << "q:\n" << q << std::endl; std::cout << "qu:\n" << qu << std::endl; std::cout << "y_expected:\n" << y_expected << std::endl; std::cout << "y:\n" << y << std::endl; } TORCH_CHECK_EQ(check, 1); } TEST_F(Quantization, UpsampleNearst2d) { const auto graph_string = R"IR( graph(%x : Float(1, 1, 2, 2, strides=[2, 2, 2, 1], device=cpu)): %4 : NoneType = prim::Constant() %3 : int[] = prim::Constant[value=[4, 4]]() %u : Float(1, 1, 4, 4) = aten::upsample_nearest2d(%x, %3, %4) return (%u))IR"; auto graph = std::make_shared(); parseIR(graph_string, &*graph); auto x = at::rand({1, 1, 2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto y_expected = at::upsample_nearest2d(x, {4, 4}); TensorExprKernel k(graph); std::vector inputs = {x}; StmtPtr s = k.getCodeGenStmt(); std::vector stack = fmap(inputs); k.run(stack); auto y = stack[0].toTensor(); bool check = at::allclose(y_expected, y); if (!check) { std::cout << "x:\n" << x << std::endl; std::cout << "y_expected:\n" << y_expected << std::endl; std::cout << "y:\n" << y << std::endl; } TORCH_CHECK_EQ(check, 1); } at::Tensor quantized_cat( c10::List const& xs, int64_t dim, double scale, int64_t zero) { const auto op = c10::Dispatcher::singleton() .findSchemaOrThrow("quantized::cat", "") .typed const&, int64_t, std::optional, std::optional)>(); return op.redispatch( DispatchKeySet({DispatchKey::QuantizedCPU}), xs, dim, scale, zero); } TEST_F(Quantization, QuantCatDequantUInt8) { const auto graph_string = R"IR( graph(%x : Float(1, 1, 2, 2, strides=[2, 2, 2, 1], device=cpu), %y : Float(1, 1, 2, 2, strides=[2, 2, 2, 1], device=cpu), %z : Float(1, 1, 2, 2, strides=[2, 2, 2, 1], device=cpu)): %qdt : int = prim::Constant[value=13]() %qxz : int = prim::Constant[value=13]() %qxs : float = prim::Constant[value=0.1]() %qyz : int = prim::Constant[value=16]() %qys : float = prim::Constant[value=0.15]() %qzz : int = prim::Constant[value=19]() %qzs : float = prim::Constant[value=0.2]() %qx : QUInt8(1, 1, 2, 2) = aten::quantize_per_tensor(%x, %qxs, %qxz, %qdt) %qy : QUInt8(1, 1, 2, 2) = aten::quantize_per_tensor(%y, %qys, %qyz, %qdt) %qz : QUInt8(1, 1, 2, 2) = aten::quantize_per_tensor(%z, %qzs, %qzz, %qdt) %catx : Tensor[] = prim::ListConstruct(%qx, %qy, %qz) %catd : int = prim::Constant[value=0]() %qcat : QUInt8(3, 1, 2, 2) = quantized::cat(%catx, %catd, %qxs, %qxz) %cat : Float(3, 1, 2, 2) = aten::dequantize(%qcat) return (%cat))IR"; auto graph = std::make_shared(); parseIR(graph_string, &*graph); auto x = at::rand({1, 1, 2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto y = at::rand({1, 1, 2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto z = at::rand({1, 1, 2, 2}, TensorOptions(kCPU).dtype(at::kFloat)); auto qx = at::quantize_per_tensor(x, 0.1f, 13, at::kQUInt8); auto qy = at::quantize_per_tensor(y, 0.15f, 16, at::kQUInt8); auto qz = at::quantize_per_tensor(z, 0.2f, 19, at::kQUInt8); auto qcat = quantized_cat({qx, qy, qz}, 0, 0.1f, 13); auto expected = at::dequantize(qcat); TensorExprKernel k(graph); std::vector inputs = {x, y, z}; StmtPtr s = k.getCodeGenStmt(); std::vector stack = fmap(inputs); k.run(stack); auto result = stack[0].toTensor(); bool check = at::allclose(expected, result); if (!check) { std::cout << "x:\n" << x << std::endl; std::cout << "y:\n" << y << std::endl; std::cout << "z:\n" << z << std::endl; std::cout << "qx:\n" << qx << std::endl; std::cout << "qy:\n" << qy << std::endl; std::cout << "qz:\n" << qz << std::endl; std::cout << "qcat:\n" << qcat << std::endl; std::cout << "expected:\n" << expected << std::endl; std::cout << "result:\n" << result << std::endl; } TORCH_CHECK_EQ(check, 1); } } // namespace jit } // namespace torch