/** * \file imperative/src/test/backward_graph.cpp * MegEngine is Licensed under the Apache License, Version 2.0 (the "License") * * Copyright (c) 2014-2021 Megvii Inc. All rights reserved. * * Unless required by applicable law or agreed to in writing, * software distributed under the License is distributed on an * "AS IS" BASIS, WITHOUT ARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. */ #include "./helper.h" #include "megbrain/opr/basic_arith.h" #include "megbrain/opr/dnn/batch_norm.h" #include "megbrain/imperative/ops/opr_attr.h" #include "megbrain/imperative/ops/autogen.h" #include "megbrain/imperative/backward_graph_opt.h" using namespace mgb; using namespace cg; using namespace imperative; template T prepare_backward_graph_inputs(const BackwardGraphResult& bg, const T& inputs, const T& outputs, const T& grads) { T ret; size_t i = 0; for (auto&& t : inputs) { if (bg.save_for_backward[i++]) { ret.push_back(t); } } for (auto&& t : outputs) { if (bg.save_for_backward[i++]) { ret.push_back(t); } } for (auto&& t : grads) { if (bg.save_for_backward[i++]) { ret.push_back(t); } } return ret; } template T expand_grads(const U& bg, const T& outputs) { T ret(bg.input_has_grad.size()); for (size_t i = 0, j = 0; i < bg.input_has_grad.size(); ++i) { if (bg.input_has_grad[i]) { ret[i] = outputs[j++]; } } return ret; } template T prepare_optimized_backward_inputs(const OptimizedBackwardGraphResult& bg, const T& precomp, const T& inputs, const T& outputs, const T& grads) { T ret = precomp; size_t i = 0; for (auto&& t : inputs) { if (bg.save_for_backward[i++]) { ret.push_back(t); } } for (auto&& t : outputs) { if (bg.save_for_backward[i++]) { ret.push_back(t); } } for (auto&& t : grads) { if (bg.save_for_backward[i++]) { ret.push_back(t); } } return ret; } TEST(TestImperative, BackwardGraphBasic) { HostTensorGenerator<> gen; SmallVector hvs; SmallVector inputs; for(size_t i = 0; i < 2; ++ i) { hvs.push_back(*gen({42})); inputs.push_back(Tensor::make(hvs.back())); } using Param = opr::Elemwise::Param; Param param{Param::Mode::MUL}; auto attr = OprAttr::make("Elemwise"); attr->cast_final_safe().param.write_pod(param); SmallVector input_descs; for (auto&& i : inputs) { input_descs.push_back({i->layout(), i->comp_node()}); } auto result = OpDef::make_backward_graph(*attr, input_descs, {true, true}, {true}); auto&& save_for_backward = result.save_for_backward; auto&& input_has_grad = result.input_has_grad; auto outputs = OpDef::apply_on_physical_tensor(*attr, inputs); inputs.push_back(outputs[0]); hvs.push_back(*gen({42})); inputs.push_back(Tensor::make(hvs.back())); mgb_assert(save_for_backward.size() == inputs.size()); for (size_t i = 0; i < inputs.size(); ++ i) { if (!save_for_backward[i]) { inputs[i].reset(); // drop unused tensor } } SmallVector backward_graph_inputs; for (auto&& i : inputs) { if (i) { backward_graph_inputs.push_back(i); } } inputs.clear(); auto input_grads = OpDef::apply_on_physical_tensor(*(result.backward), backward_graph_inputs); mgb_assert(input_grads.size() == input_has_grad.size()); for (size_t i = 0; i < input_has_grad.size(); ++ i) { mgb_assert(input_has_grad[i] == static_cast(input_grads[i])); } SmallVector res; for (auto&& i : input_grads) { res.emplace_back(); res.back().copy_from(i->dev_tensor()).sync(); } for (size_t i = 0; i < 42; ++ i) { for (size_t j = 0; j < 1; ++ j) { ASSERT_EQ(hvs[2].ptr()[i] * hvs[j].ptr()[i], res[j ^ 1].ptr()[i]); } } } TEST(TestImperative, BackwardGraphIdentity) { HostTensorGenerator<> gen; auto host_a = gen({42}), host_dc = gen({42}); auto a = Tensor::make(*host_a), dc = Tensor::make(*host_dc); SmallVector inputs; inputs.push_back(a); auto attr = OprAttr::make("Identity"); attr->cast_final_safe().param.write_pod({}); SmallVector input_descs; input_descs.push_back({a->layout(), a->comp_node()}); auto result = OpDef::make_backward_graph(*attr, input_descs, {true}, {true}); auto&& save_for_backward = result.save_for_backward; auto&& input_has_grad = result.input_has_grad; auto outputs = OpDef::apply_on_physical_tensor(*attr, inputs); inputs.push_back(outputs[0]); inputs.push_back(dc); mgb_assert(save_for_backward.size() == inputs.size()); for (size_t i = 0; i < inputs.size(); ++ i) { if (!save_for_backward[i]) { inputs[i].reset(); // drop unused tensor } } SmallVector backward_graph_inputs; for (auto&& i : inputs) { if (i) { backward_graph_inputs.push_back(i); } } inputs.clear(); auto input_grads = OpDef::apply_on_physical_tensor(*(result.backward), backward_graph_inputs); mgb_assert(input_grads.size() == input_has_grad.size()); for (size_t i = 0; i < input_has_grad.size(); ++ i) { mgb_assert(input_has_grad[i] == static_cast(input_grads[i])); } HostTensorND hv; hv.copy_from(input_grads[0]->dev_tensor()).sync(); for (size_t i = 0; i < 42; ++ i) { ASSERT_EQ(host_dc->ptr()[i], hv.ptr()[i]); } } TEST(TestImperative, BatchNormGrad) { auto cn = CompNode::load("xpux"); using Param = opr::BatchNorm::Param; size_t N=2, C=3, H=5, W=5; LogicalTensorDesc inp{TensorLayout{{N, C, H, W}, dtype::Float32()}, cn}; LogicalTensorDesc stat{TensorLayout{{C}, dtype::Float32()}, cn}; { auto op = OprAttr::make("BatchNorm"); auto&& attr = op->cast_final_safe(); Param param; param.fwd_mode = Param::FwdMode::TRAINING; attr.param.write_pod(param); OpDef::make_backward_graph(attr, {inp, stat, stat, stat, stat}, {true, true ,true, false, false}, {false, false, false, false, true}); } { auto op = OprAttr::make("BatchNorm"); auto&& attr = op->cast_final_safe(); Param param; param.fwd_mode = Param::FwdMode::TRAINING; attr.param.write_pod(param); OpDef::make_backward_graph(attr, {inp, stat, stat}, {true, true ,true}, {false, false, true}); } } TEST(TestImperative, OptimizedBackwardGraphBasic) { auto cn = CompNode::load("xpux"); LogicalTensorDesc desc = {TensorLayout(dtype::Float32()), cn}; HostTensorGenerator<> gen; auto op = std::shared_ptr(Elemwise::make(Elemwise::Mode::ADD)); auto bg = OpDef::make_backward_graph(*op, {desc, desc}, {true, true}, {true}); auto obg = OptimizedBackwardGraphResult(bg); ASSERT_EQ(obg.save_for_backward.size(), 4); ASSERT_FALSE(obg.save_for_backward[0]); ASSERT_FALSE(obg.save_for_backward[1]); ASSERT_FALSE(obg.save_for_backward[2]); auto a_hv = gen({42}); auto b_hv = gen({5, 42}); auto dc_hv = gen({5, 42}); auto a_tn = Tensor::make(*a_hv); auto b_tn = Tensor::make(*b_hv); auto dc_tn = Tensor::make(*dc_hv); auto c_tn = OpDef::apply_on_physical_tensor(*op, {a_tn, b_tn})[0]; auto backward_graph_inputs = prepare_backward_graph_inputs>(bg, {a_tn, b_tn}, {c_tn}, {dc_tn}); auto grads = expand_grads(bg, OpDef::apply_on_physical_tensor(*bg.backward, backward_graph_inputs)); auto precomp = OpDef::apply_on_physical_tensor(*obg.precomp, {a_tn, b_tn, c_tn}); ASSERT_EQ(precomp.size(), 2); ASSERT_EQ(precomp[0]->shape().ndim, 1); ASSERT_LE(precomp[0]->shape()[0], 2); ASSERT_EQ(precomp[1]->shape().ndim, 1); ASSERT_LE(precomp[1]->shape()[0], 2); auto backward_inputs = prepare_optimized_backward_inputs>(obg, precomp, {a_tn, b_tn}, {c_tn}, {dc_tn}); auto grads2 = expand_grads(obg, OpDef::apply_on_physical_tensor(*obg.backward, backward_inputs)); ASSERT_EQ(grads2.size(), 2); MGB_ASSERT_TENSOR_EQ(grads[0]->get_value(), grads2[0]->get_value()); MGB_ASSERT_TENSOR_EQ(grads[1]->get_value(), grads2[1]->get_value()); }