[源码解析]PyTorch如何实现前向传播(2) --- 基础类(下)
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[源码解析]PyTorch如何实现前向传播(2) --- 基础类(下)
目录- [源码解析]PyTorch如何实现前向传播(2) --- 基础类(下)
- 0x00 摘要
- 0x01 前文回顾
- 0x02 TensorImpl
- 2.1 转嫁
- 2.2 定义
- 0x03 自动求导相关类
- 3.1 AutogradMeta
- 3.2 DifferentiableViewMeta
- 3.3 AutogradContext
- 3.4 Auto Function
- 0x04 Node
- 4.1 定义
- 4.2 重要成员变量
- 4.2.1 input_metadata_
- 4.2.2 next_edges_
- 4.2.3 sequence_nr_
- 4.2.4 topological_nr_
- 4.2.5 operator()
- 0x05 Edge
- 0x06 逻辑图
- 0xFF 参考
0x00 摘要
本系列将通过大概十篇左右文章来分析 PyTorch 的自动微分功能如何实现。本文是前向传播的第二篇,介绍自动微分(梯度计算)所涉及的部分 PyTorch 基础类。因为字数太多(1万两千字),所以拆分成上下两篇。
系列前几篇连接如下:
深度学习利器之自动微分(1)
深度学习利器之自动微分(2)
深度学习利器之自动微分(3) --- 示例解读
[源码解析]PyTorch如何实现前向传播(1) --- 基础类(上)
0x01 前文回顾
前文介绍了部分基础类,比如 Variable, Function, Tensor,本文我们继续分析其他基础类。为了行文完整,我们从前文摘取了总体逻辑关系如下,SubBackward0,PowBackward0 和 都是Node 的派生类,在本文我们会细化这个图。
+---------------------+ +----------------------+ | SubBackward0 | | PowBackward0 | | | Edge | | Edge | next_functions +-----+--------> | next_functions +----------> ... | | | | | +---------------------+ | +----------------------+ | | | +----------------------+ | Edge | MulBackward0 | +--------> | | Edge | next_functions +----------> ... | | +----------------------+
0x02 TensorImpl
2.1 转嫁
PyTorch 之中大量使用了bridge设计模式,at::Tensor就是利用bridge模式把具体实现转交给TensorImpl完成。
class TORCH_API Tensor { private: struct unsafe_borrow_t { explicit unsafe_borrow_t() = default; }; explicit Tensor(unsafe_borrow_t, const Tensor& rhs) : impl_(c10::intrusive_ptr<at::TensorImpl, UndefinedTensorImpl>::reclaim(rhs.impl_.get())) {} friend MaybeOwnedTraits<Tensor>; protected: friend class ::caffe2::Tensor; void enforce_invariants(); c10::intrusive_ptr<TensorImpl, UndefinedTensorImpl> impl_; // 转嫁出去 };
具体如下:
+------------------------------------------------+ +---------------------------+ |Tensor | |TensorImpl | | | | | | | bridge | | | <TensorImpl, UndefinedTensorImpl> impl_+-----------> | autograd_meta_ | | | | | | | | named_tensor_meta_ | +------------------------------------------------+ | | | pyobj_ | | | | sizes_and_strides_ | | | | storage_offset_ | | | | data_type_ | | | | device_opt_ | | | | | +---------------------------+
2.2 定义
TensorImpl 定义如下,因为本文是自动微分和前向传播相关,因此我们专注这部分功能的相关变量,就是autograd_meta_ 。除了 autograd_meta_ 之外,主要是一些描述Tensor大小的元数据,包含元素的类型(dtype),Tensor所依赖的设备,Strides(步幅)等等。
struct C10_API TensorImpl : public c10::intrusive_ptr_target { Storage storage_; private: // This pointer points to an AutogradMeta struct that stores autograd-specific // fields (such as grad_ / grad_fn_ / grad_accumulator_). This pointer always // has unique ownership (meaning only one TensorImpl can own it at a time). // // autograd_meta_ can be nullptr, as an optimization. When this occurs, it is // equivalent to having an autograd_meta_ pointing to a default constructed // AutogradMeta; intuitively, tensors which don't require grad will have this // field set to null. // // This means accessors on autograd_meta_ have to be careful to test if they // got a nullptr, and handle default behavior appropriately in that case. // // Note that we don't enforce the invariant that if the AutogradMeta is // default constructed, it is nullptr (to do this, we'd have to continuously // check if an AutogradMeta became, by mutation, equal to the default // constructed form. (This might be useful, but it seems rare enough that // a requires_grad=True variable will turn back into the requires_grad=False // version.) So there are three representable states: // // 1. autograd_meta_ == nullptr // 2. autograd_meta_ is default constructed (semantically, same as (1)) // 3. autograd_meta_ has nontrivial information content // std::unique_ptr<c10::AutogradMetaInterface> autograd_meta_ = nullptr; // 主要关注这里 protected: std::unique_ptr<c10::NamedTensorMetaInterface> named_tensor_meta_ = nullptr; c10::VariableVersion version_counter_; PyObject* pyobj_ = nullptr; c10::impl::SizesAndStrides sizes_and_strides_; int64_t storage_offset_ = 0; int64_t numel_ = 1; caffe2::TypeMeta data_type_; c10::optional<c10::Device> device_opt_; bool is_contiguous_ : 1; /* HasContiguityPolicy */ uint8_t has_contiguity_ : 2; bool storage_access_should_throw_ = false; bool is_channels_last_ : 1; bool is_channels_last_contiguous_ : 1; bool is_channels_last_3d_ : 1; bool is_channels_last_3d_contiguous_ : 1; bool is_non_overlapping_and_dense_ : 1; bool is_wrapped_number_ : 1; bool allow_tensor_metadata_change_ : 1; bool reserved_ : 1; DispatchKeySet key_set_; };
对于自动微分,std::unique_ptr<c10::AutogradMetaInterface> autograd_meta_ = nullptr;
是关键。
此成员变量用来存储自动微分相关的特殊变量,比如grad_ / grad_fn_ / grad_accumulator_
,每一个TensorImpl在同一时刻只有唯一一个AutogradMeta。
autograd_meta_ 是区分一个 Variable 是普通张量还是带 autograd 功能张量的唯一标识:
- 对于不需要梯度的张量,autograd_meta_ 这个变量为null。
- 但是出于优化的目的,即使需要梯度,autograd_meta_ 也可以是null,这种情况等同于被赋值成一个缺省的AutogradMeta。所以在使用时候需要仔细校验是否为null。
- 在需要梯度情况下,一般来说,autograd_meta_会被初始化为 AutogradMeta 或者DifferentiableViewMeta。
AutogradMetaInterface 定义如下,这是一个抽象接口,需要派生类来实现具体功能。
struct C10_API AutogradMetaInterface { virtual void set_requires_grad( bool requires_grad, at::TensorImpl* self_impl) = 0; virtual bool requires_grad() const = 0; virtual at::Tensor& mutable_grad() = 0; virtual const at::Tensor& grad() const = 0; virtual const at::Tensor& fw_grad(uint64_t level, const at::Tensor& self) const = 0; virtual void set_fw_grad( const at::Tensor& new_grad, const at::Tensor& self, uint64_t level, bool is_inplace_op) = 0; virtual ~AutogradMetaInterface(); };
0x03 自动求导相关类
以下类是与自动求导相关。
3.1 AutogradMeta
AutogradMeta 继承了 AutogradMetaInterface,存储于自动微分相关的东西,比如节点的梯度值和梯度计算函数,其具体定义如下:
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ // AutogradMeta //~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /// Each `Variable` has one unique `AutogradMeta` struct, which stores autograd /// metadata fields that are necessary for tracking the Variable's autograd history. /// As an optimization, a Variable may store a nullptr, in lieu of a default /// constructed AutogradMeta. /// 1. A `grad_fn`, if the variable is in the interior of the graph. This is the /// gradient of the function that produced the variable. /// 2. A `grad_accumulator`, if the variable is a leaf, which accumulates a /// scalar gradient value into its `grad` variable. struct TORCH_API AutogradMeta : public c10::AutogradMetaInterface { std::string name_; Variable grad_; // 保存当前Variable的梯度,本身也是一个Variable std::shared_ptr<Node> grad_fn_; // 非叶子节点才有意义,中间节点负责梯度计算。Pytorch就是判断grad_fn_是否为空来判断一个Variable是否是叶子节点,可以通过grad_fn()方法来访问。 std::weak_ptr<Node> grad_accumulator_; // Node实例,只有叶子节点才有,叶子节点负责对梯度进行累加,grad_accumulator_就是梯度累加处理函数,梯度就被保存在grad_变量之中 // This field is used to store all the forward AD gradients // associated with this AutogradMeta (and the Tensor it corresponds to) // There is a semantic 1:1 correspondence between AutogradMeta and // ForwardGrad but: // - This field is lazily populated. // - This field is a shared_ptr but it must never be // shared by multiple Tensors. See Note [ Using ForwardGrad ] // Any transition from not_initialized to initialized // must be protected by mutex_ std::shared_ptr<ForwardGrad> fw_grad_; // forward AD gradients std::vector<std::shared_ptr<FunctionPreHook>> hooks_; std::shared_ptr<hooks_list> cpp_hooks_list_; // Only meaningful on leaf variables (must be false otherwise) bool requires_grad_; // 此Variable是否需要grad // Only meaningful on non-leaf variables (must be false otherwise) bool retains_grad_; // 只有非叶子节点才有意义,是否需要保持图 bool is_view_; // 此Variable是否是一个View(没有实际存储,这是基于base的Variable) // The "output number" of this variable; e.g., if this variable // was the second output of a function, then output_nr == 1. // We use this to make sure we can setup the backwards trace // correctly when this variable is passed to another function. uint32_t output_nr_; // Variable是某一个函数的输出数据,output_nr_ 就记录了它是第几个输出,比如 = 0,就表示是函数的第1个输出 // Mutex to ensure that concurrent read operations that modify internal // state are still thread-safe. Used by grad_fn(), grad_accumulator(), // fw_grad() and set_fw_grad() // This is mutable because we need to be able to acquire this from const // version of this class for the functions above mutable std::mutex mutex_; };
AutogradMeta 的主要成员变量如下:
- grad_ :存储当前Variable实例的梯度,本身也是一个Variable。
- grad_fn :是个Node实例,非叶子节点才有。通过 grad_fn() 方法来访问,实际上,PyTorch中就是通过 grad_fn是否为空 来判断一个Variable是否是leaf variable。
- grad_accumulator_ :也是Node的实例,只有叶子节点才有。
- 通过Variable的grad_accumulator()来访问。
- 叶子节点负责对梯度进行累加,grad_accumulator_ 就是梯度累加处理函数。
- 其对应梯度就被保存在 grad_ 变量之中。
- requires_grad_ :表明此Variable实例是否需要grad。
- retains_grad_ : 只有非叶子节点才有意义,意义为是否需要保持图。
- is_view_ :是个flag,表明此Variable实例是否是个view(没有实际存储,基于base的variable)。
- version_counter_ :version number。
- output_nr_:是个数字。output_nr_表明是 Node 的第几个输出,比如为 0 就 表明这个Variable是Node 的第 1 个输出。
- base_ :是view的base variable。
具体如下:
+----------------------------------------------+ +-------------------------+ |Tensor | |TensorImpl | | | | | | | bridge | | | <TensorImpl, UndefinedTensorImpl> impl_ +-----------> | autograd_meta_ +---------+ | | | | | | | | named_tensor_meta_ | | +----------------------------------------------+ | | | | pyobj_ | | | | | | sizes_and_strides_ | | | | | | storage_offset_ | | | | | | data_type_ | | | | | | device_opt_ | | | | | | | | +-------------------------+ | | +-------------------------+ | | AutogradMeta | | | +<--+ | | | grad_fn_ | | | | grad_accumulator_ | | | | hooks_ | | | | retains_grad_ | | | | output_nr_ | | | | fw_grad_ | | | +-------------------------+
3.2 DifferentiableViewMeta
对于输入变量,许多操作返回与输入变量共享存储的新变量,返回的变量被称为在基变量之上的视图(view)变量。在PyTorch中,我们有两种类型的视图:可微视图和不可微的视图。为了支持合适的版本校验,无论是哪种类型,基变量和视图变量必须分享同样的版本计数器(version_counter)。
DifferentiableViewMeta 就是用来处理可微视图。
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ // DifferentiableViewMeta //~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ /// DifferentiableViewMeta is created to support gradient tracking of /// such **in-place** operations. In particular, /// + if an in-place op is done on base, the grad_fn field of the view may /// become stale. So accesses should always go through grad_fn(), which /// reconstructs an updated grad_fn if the version_counter has incremented. /// All other fields are always valid. /// + if an in-place op is done on view, in rebase_history() of view, which is /// called after every in-place op in VariableType.cpp, the grad_fn of base /// is updated. /// + if a single autograd Node returns multiple differentiable views, if any /// output is modified by an inplace operation, the autograd engine will make /// an equivalent graph (corresponding to the view operations) without using /// equivalent graph, where each output is treated as if it were produced by a /// distinct view operation. This discards the original (e.g., user provided) /// grad_fn. If the provided grad_fn does more than the backward of the view, /// then the DifferentiableViewMeta must be created with creation_meta= /// CreationMeta::MULTI_OUTPUT_NODE to prevent the engine from ignoring the /// provided grad_fn. enum class CreationMeta: uint8_t { DEFAULT, IN_CUSTOM_FUNCTION, MULTI_OUTPUT_NODE, NO_GRAD_MODE, MULTI_OUTPUT_SAFE, INFERENCE_MODE}; struct TORCH_API DifferentiableViewMeta : public AutogradMeta { private: /// Informations about the views c10::optional<ViewInfo> backward_info_; c10::optional<ViewInfo> forward_info_; // Optimization to reduce the number of ViewInfo we create. // In the (very common) case where backward_info_ == forward_info_, we only // populate backward_info_ (that should be used as both the forward and backward // view information) and set shared_view_info_ = true. // Invariants: // - If shared_view_info_ is false, there is no special constraints on // backward_info_ and forward_info_ // - If shared_view_info_ is true, we must have: // - backward_info_.has_value() == true // - forward_info_.has_value() == false bool shared_view_info_; /// The two following fields are extra information that we track to ensure that /// any operation on this backward view is valid. /// The value of the version_counter at the time grad_fn was created. The /// grad_fn field is stale if attr_version_ != version_counter.current_version(). uint32_t attr_version_; CreationMeta creation_meta_; };
3.3 AutogradContext
AutogradContext 是操作 autograd 的上下文,用来存储在前向过程中产生的信息,这样在后向传播中就可以访问。
/// Context to save information during `forward` that can be accessed in `backward` /// in custom autograd operations (see `torch::autograd::Function` for details). struct TORCH_API AutogradContext { // NOLINTNEXTLINE(cppcoreguidelines-pro-type-member-init) AutogradContext() : materialize_grads_(true) {} AutogradContext(const AutogradContext &other) = delete; AutogradContext& operator=(const AutogradContext& other) = delete; /// Can be used to save non-variable data for `backward`. // NOLINTNEXTLINE(cppcoreguidelines-non-private-member-variables-in-classes) ska::flat_hash_map<std::string, at::IValue> saved_data; /// Saves the list of variables for a future call to `backward`. This /// should be called at most once from inside of `forward`. void save_for_backward(variable_list to_save); /// Marks variables in the list as modified in an in-place operation. This /// should be called at most once from inside of `forward` and all arguments /// should be inputs. void mark_dirty(const variable_list &inputs); /// Marks outputs in the list as not requiring gradients. This should be called /// at most once from inside of `forward` and all arguments should be outputs. void mark_non_differentiable(const variable_list &outputs); // Sets whether undefined output grad tensors should be expanded to tensors // full of zeros before calling backward function. Default value is true. void set_materialize_grads(bool value); /// Get the list of variables that were saved in `forward` using /// `save_for_backward()`. Before returning them to the user, a check is made to /// ensure that they were not modified by any in-place operations. variable_list get_saved_variables() const; const std::unordered_set<at::TensorImpl*>& get_and_bump_dirty() const; const std::unordered_set<at::TensorImpl*>& get_non_differentiable() const; private: std::unordered_set<at::TensorImpl*> non_differentiable_; std::unordered_set<at::TensorImpl*> dirty_inputs_; std::vector<torch::autograd::SavedVariable> saved_variables_; variable_list to_save_; bool materialize_grads_; // The CppNode in the autograd graph that owns this AutogradContext. We need a // weak_ptr to avoid a refcycle. Since grad_fn_ owns this AutogradContext, it // will always be alive when we want to use it. std::weak_ptr<Node> grad_fn_; bool has_freed_buffers_; void save_variables(); template <class T> friend struct CppNode; };
对用户来说,AutogradContext 主要是在 自定义 Auto Function 方面。以下是注释之中的例子。
/// ``` /// class MyFunction : public Function<MyFunction> { /// public: /// static variable_list forward(AutogradContext *ctx, int n, Variable var) { /// // Save data for backward in context /// ctx->saved_data["n"] = n; /// var.mul_(2); /// // Mark var as modified by inplace operation /// ctx->mark_dirty({var}); /// return {var}; /// } /// /// static variable_list backward(AutogradContext *ctx, variable_list /// grad_output) { /// // Use data saved in forward /// auto n = ctx->saved_data["n"].toInt(); /// return {grad_output[0]*n}; /// } /// }; /// ``` /// /// To use `MyFunction`: /// ``` /// Variable x; /// auto y = MyFunction::apply(6, x); /// // Example backward call /// y[0].sum().backward();
我们籍此进入到 Auto Function。
3.4 Auto Function
Autograd使用Function来计算结果和梯度,并对操作历史进行编码。在Tensor
上执行的每个操作都会创建一个新的 Function 对象,该对象执行计算并记录发生了什么。操作历史以函数 DAG 的形式保留,边表示数据依赖关系 ( input <- output
)。
通常,用户与 Function 交互的唯一方式是创建子类和定义新操作(扩展新的功能),这是扩展 torch.autograd 的推荐方式。有关如何使用此类的更多详细信息,请参阅有关扩展 autograd 引擎的说明: https://pytorch.org/docs/stable/notes/extending.html#extending-torch-autograd
用户如果要使用自定义autograd操作,请使用静态正向和反向函数实现一个Function子类。
forward
可以接受任意多个参数,并应返回变量列表或变量。- 任何Variable参数的使用都将在计算图中注册,但是vectors/sets 或者其他数据结构不会遍历注册。
- 您可以使用c10::optional
作为参数之一,如果参数有值,它将在图形中注册为变量。 - forward应该将指向“torch::autograd::AutogradContext”的指针作为第一个参数。变量可以使用“ctx->save_for_backward”,保存在“ctx->saved_data” map中,其他数据将以
<std::string, at::IValue>
”对的形式保存在“ctx->saved_data” map中。
backward
应该使用指向torch::autograd::AutogradContext
的指针 以及一个变量列表作为参数。- 该变量列表包含的变量数量与
forward
输出的变量数量相同。 - backward应该返回与输入一样多的变量,其中每个变量都包含与输入相应的梯度。
- “forward”中保存的变量可以通过“ctx->get_saved_Variables”访问,其他保存的数据可以通过“ctx->saved_data”访问。
- 当 backward被调用时,通过调用每个Function对象的方法,并将返回的梯度传递给下一个Function ,我们就可以按照拓扑顺序来处理这个计算图 。
- 该变量列表包含的变量数量与
Function 具体派生子类例子如下:
class Exp(Function): @staticmethod def forward(ctx, i): result = i.exp() ctx.save_for_backward(result) return result @staticmethod def backward(ctx, grad_output): result, = ctx.saved_tensors return grad_output * result #Use it by calling the apply method: output = Exp.apply(input)
如前所示,Function 已经被 Node 替换,所以我们再来到了 Node。
0x04 Node
早期版本中,Node的名字是Function,后来修改为Node,应该是想与节点概念更好的对应。
Node 是一个代表操作的抽象类,其输入是0个或者多个Variable,输出是0个或多个Variable。前向图中该Node节点的输入节点,就是后向传播图中该Node节点的输出节点。PyTorch的autograd机制中,所有函数都派生自此类,并重写其“apply”方法。这样子类的实例就可以通过call操作符调用。
将autograd系统视为计算图时,Node
是通过(有向)Edge
相互连接的顶点或节点,其本身通过(Node,input_nr)对来表示。Variable 是Node 的输入和输出,并在图形执行期间在这些边之间移动。当两个或多个“边”(来自不同来源)指向一个“节点”的同一输入时,沿所有这些边生成的值在转发到目标“节点”之前将被隐式求和。
其子类通常用来表示可微函数及其梯度算子。然而,请注意,由于“节点”的定义非常笼统,“节点”接受零或更多的输入并产生零或更多的输出。“节点”的使用非常灵活,超出了纯数学运算的范围。例如,AccumageGrad
函数是一个sink,它接受一个输入,但不产生输出,而是将输入作为副作用进行累积。在另一端,“GraphRoot”函数不接收来自其他函数的输入,而是产生多个输出。具体可以参见 torch/csrc/autograd/function.h 的注释。
4.1 定义
我们看看 Node 类的定义,为了更好的说明,这里只保留成员变量,删除成员函数。
using edge_list = std::vector<Edge>; struct TORCH_API Node : std::enable_shared_from_this<Node> { protected: /// Performs the `Node`'s actual operation. virtual variable_list apply(variable_list&& inputs) = 0; /// Calls `apply()`, but instruments it with tracing machinery. variable_list traced_apply(variable_list inputs); /// NOTE [ Sequence Number] /// /// The sequence_nr has two main usages in autograd: /// /// 1) Helps determine the node's execution priority in the engine. /// All else being equal, nodes with higher priority numbers are executed first. /// Thus, nodes corresponding to ops executed later are the first to be executed in /// the backward pass. One caveat is that we prioritize AccumulateGrad nodes by /// explicitly setting its sequence_nr to be UINT64_MAX. /// 2) The sequence number of this `Node` is paired with with thread_id it was created in /// as a unique identifier by the profiler to annotate recorded events. /// The purpose of this is to help users (and possibly programs) interpreting the profiler's /// output to correlate backward nodes with its forward ops. /// We need both sequence_nr and thread_id to identify a node because sequence_nr is /// thread_local, i.e., starts counting up from zero in a new thread // Sequence number used to correlate backward nodes with forward ops in the // profiler and provide determinisim in the engine. const uint64_t sequence_nr_; // NOTE [ Topological Number ] // // topological_nr is used to prune branches in the DAG during autograd discovery as // maintaining topological_nr helps us check in O(1) if there does NOT exist // a directed path between two nodes. // // The topological order number of this `Node` representing the length of the // longest possible path from this Node to any leaf node. If you are leaf node, // aka AccumulateGrad, this will be zero. This value has the property that // For every pair of nodes X, Y in G, existence of a directed path from X to Y // implies topo_nr(X) > topo_nr(Y). The converse is not true, however, so we // cannot prove existence of a path from X to Y, only non-existence. // // One assumption we make when using topo_nr is that once a node // has been used, i.e., has a parent node, its own topo_nr does not change // we have added some checks with the `has_parent_` field to enforce this. // // What NOT to do: // // 1) 2 -> 1 -> 0 In this diagram we label nodes with their topo_nr. // 2 -> 1 -> 0 We have two simple graphs that can each arise from // `t.exp().exp()`, for example. // 2) 2 -> 1 -> 0 // / // 2 -> 1 -> 0 We add 2 as a next edge to 1 even though 1 already // has a parent. // 3) 2 -> 1 -> 0 // / // 2 -> 3 -> 0 2 < 3, yet there exists a path from 2 to 3! // uint64_t topological_nr_ = 0; // Tracks whether this node has been added as the next_edge of another node // via set_next_edge(s), which always calls topological_nr() of all its children // See NOTE [ Topological Number ] for why we need this. mutable bool has_parent_ = false; // Id of the thread that created the instance uint64_t thread_id_ = 0; std::mutex mutex_; // 前向过程中的输入variable,在前向过程中与该算子相关联的边 edge_list next_edges_; PyObject* pyobj_ = nullptr; // weak reference std::unique_ptr<AnomalyMetadata> anomaly_metadata_ = nullptr; std::vector<std::unique_ptr<FunctionPreHook>> pre_hooks_; std::vector<std::unique_ptr<FunctionPostHook>> post_hooks_; at::SmallVector<InputMetadata, 2> input_metadata_; // 这里对运算符()进行重载,核心其实就是调用apply() variable_list operator()(variable_list&& inputs) { // In the first iteration of named tensors, autograd ignores names and // operates on unnamed tensors. In the long term, autograd should // probably operate with names. at::NoNamesGuard no_names_guard; bool pre_sampled = false; if (at::shouldRunRecordFunction(&pre_sampled)) { // Using RecordFunction to trigger observers in the backward pass at::RecordFunction guard(at::RecordScope::BACKWARD_FUNCTION, pre_sampled); if (guard.isActive()) { // Using sequence number and thread id to correlate with // the forward pass function guard.setForwardThreadId(thread_id_); if (guard.needsInputs()) { guard.before( name(), std::vector<c10::IValue>(inputs.begin(), inputs.end()), sequence_nr()); } else { guard.before(name(), sequence_nr()); } } // keeping stack guard object alive during the call return apply(std::move(inputs)); } else { return apply(std::move(inputs)); } } };
其构造函数是:
explicit Node( uint64_t sequence_nr, edge_list&& next_edges = edge_list()) : sequence_nr_(sequence_nr), next_edges_(std::move(next_edges)) { for (const Edge& edge: next_edges_) { update_topological_nr(edge); } if (AnomalyMode::is_enabled()) { metadata()->store_stack(); // If anomaly mode is enabled and graph is constructed, then assign the // currently evaluating node as the parent of this node. // A parent is a Node where this Node is created. // We are tracking the parents to track multiple backward operations. assign_parent(); } // Store the thread_id of the forward operator. // See NOTE [ Sequence Numbers ] thread_id_ = at::RecordFunction::currentThreadId(); }
4.2 重要成员变量
我们具体解释一些重要成员变量。
4.2.1 input_metadata_
input_metadata_ 代表了 input data 的元信息,界定了一个Function的输入参数。
4.2.2 next_edges_
这是在前向过程中与该算子相关联的边。
我们将 PyTorch的autograd系统看作是一个图,每个 Node 实例就是图节点,各个 Node 实例之间则是通过Edge连接的。Edge是个结构体,通过 (Function, input_nr) 的配对来代表graph中的边。Node 的成员 next_edges_ 正是一组这样的Edge实例,其代表此 Node 实例的返回值要输出到的(另外)Node,即 next_edges_是 Node 和Node 之间的纽带。
Node 的输入输出都是Variable实例,因此当一个graph被执行的时候,Variable实例就在这些edges之间来传输流动。当两个或者多个Edge指向同一个Node的时候(这个节点的入度大于1),这些edges的输出将被隐含相加起来再送给指向的目标 Node。
用户可以使用add_next_edge()来向 Node 添加一个edge, 通过next_edge(index)获取对应的edge,通过next_edges()方法获得迭代edge的迭代器。
4.2.3 sequence_nr_
该变量用于将网络中的后向节点与前向操作关联起来,并且在引擎中提供确定信息。sequence_nr_ 随着Function实例的不断构建而单调增长,具体有两个用处:
-
帮助确定节点在引擎中的执行优先级。在所有其他条件相同的情况下,优先级较高的节点将首先执行。因此,前向传播时后执行的操作就是后向传播之中先执行的操作。需要注意的一点是,对于 AccumulateGrad 节点,我们将sequence_nr显式地设置为UINT64_MAX。在PyTorch的反向图计算中,
AccumulateGrad
类型代表的就是叶子节点类型,也就是计算图终止节点。AccumulateGrad
类中有一个.variable
属性指向叶子节点。 -
此“节点”的 sequence_nr_ 与 thread_id 一起搭配,作为一个节点的唯一标示,在 profiler 之中记录事件。这样做的目的是帮助用户(可能还有程序)解释 profiler 的输出,以便将向后的节点与其向前的操作关联起来。因为 sequence_nr 是 thread_local 类型变量,即在新线程中从零开始计数。
4.2.4 topological_nr_
此变量是 “节点”的拓扑顺序号,表示从该节点到任何叶节点的最长可能路径的长度。如果有一个叶节点,即AccumulateGrad,topological_nr_ 将是零。
topological_nr_ 用于在autograd发现期间对DAG中的分支进行修剪,维护拓扑 topological_nr_有助于我们在两个节点之间不存在有向路径时,在O(1) 时间完成检查。
topological_nr_ 具有以下属性:
- 对于G中的每一对节点X,Y,如果存在从X到Y的有向路径,则意味着 topo_nr(X) > topo_nr(Y)。然而,事实并非如此,因此我们无法证明从X到Y的路径的存在性,只能证明不存在。
- 我们在使用 topological_nr_ 时所做的一个假设是:一旦使用了一个节点,即它有一个父节点,那么它自己的topological_nr_ 就不会改变。我们在“has_parent_”字段中添加了一些检查来强制执行这一点。
4.2.5 operator()
variable_list operator()(variable_list&& inputs)
是Node的主要方法。该方法接收vector封装的多个Variable实例,并输出vector封装的多个Variable实例,然后调用apply 具体业务函数。该方法依靠C++的多态,将对operator 的调用转化为对自身(子类)的apply方法调用。
PyTorch中所有用于反向传播计算的函数都继承自Function类,并重写Function类中的apply纯虚函数。
0x05 Edge
从名字可知,Edge 就是计算图的边。主要变量是:
- std::shared_ptr
function :本边指向的目标Node。 - uint32_t input_nr : 指定本Edge是 function 的第几个输入 。
using tensor_list = std::vector<at::Tensor>; using variable_list = std::vector<Variable>; using edge_list = std::vector<Edge>; using saved_variable_list = std::vector<SavedVariable>; using IndexRange = std::pair<size_t, size_t>; /// Represents a particular input of a function. struct Edge { Edge() noexcept : function(nullptr), input_nr(0) {} Edge(std::shared_ptr<Node> function_, uint32_t input_nr_) noexcept : function(std::move(function_)), input_nr(input_nr_) {} /// Convenience method to test if an edge is valid. bool is_valid() const noexcept { return function != nullptr; } // Required for use in associative containers. bool operator==(const Edge& other) const noexcept { return this->function == other.function && this->input_nr == other.input_nr; } bool operator!=(const Edge& other) const noexcept { return !(*this == other); } /// The function this `Edge` points to. std::shared_ptr<Node> function; // 指向的Node /// The identifier of a particular input to the function. uint32_t input_nr; //指定本Edge是function的第几个输入 }; }} // namespace torch::autograd
0x06 逻辑图
我们把文初的逻辑图细化如下,上半部分是 Python 世界,下半部分是 C++世界:
+--------------------------------------------+ +------------------------------+ | SubBackward0 | | PowBackward0 | | | | | Edge | | | next_functions +----------> ... | next_functions[0] = (PowBackward0, 0) +----------> | | | | +------------------------------+ | | | | +-------------------------------+ | next_functions[1] = (MulBackward0, 0) +----------> | MulBackward0 | | | | | Edge | | | next_functions +----------> ... +--------------------------------------------+ | | +-------------------------------+ ^ | | | Python +--------------------------------------------------------------------------------------------------------+ | C++ | v +---------------------------------------------+ +----------------------+ +------------------+ | SubBackward0 | | Edge 1 | | PowBackward0 | | +-------------------------> | | | | | | | | function +----------> | | | + | | | | | | next_edges_ = [Edge 1, Edge 2] | | input_nr = 0 | | | | + | +----------------------+ +------------------+ | | | | | | +---------------------------------------------+ +----------------------+ +------------------+ | | Edge 2 | | MulBackward0 | | | | | | +----------------> | function +----------> | | | | | | | input_nr = 0 | | | | | | | +----------------------+ +------------------+
手机如下:
至此,传播过程中的基础类已经分析完毕,下一篇我们介绍如何使用这些类来完成前向传播。
0xFF 参考
https://github.com/KeithYin/read-pytorch-source-code/
pytorch学习笔记(十三):backward过程的底层实现解析
PyTorch的初始化
pytorch的自动求导机制 - 计算图的建立
How autograd encodes the history
https://pytorch.org/tutorials/beginner/blitz/autograd_tutorial.html
pytorch笔记(计算图+autograd)-Node(1)
详解Pytorch中的网络构造
PyTorch的优化器
PyTorch的分布式
PyTorch的Tensor(下)
PyTorch的Tensor(中)
PyTorch的Tensor(上)
PyTorch的动态图(下)
PyTorch的动态图(上)
计算图——用Pytorch解释李宏毅老师PPT中的实例
如何使用pytorch自动求梯度
PyTorch自动求导(Autograd)原理解析
pytorch自动求导Autograd系列教程(一)
PyTorch核心开发者亲自揭秘其内部机制
PyTorch自动微分基本原理
https://towardsdatascience.com/pytorch-autograd-understanding-the-heart-of-pytorchs-magic-2686cd94ec95
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