# Design Doc: Variable Variable is also known as *blob* in MxNet and Caffe2. It is the input and output type of operators, where a neural network is a graph of operators. ## Requirements: Lazy Memory Allocation For the flexibility of a DL system, a variable should be able to contain any typed value -- a tensor in most cases, but could also be some integer IDs or a scope of other variables in the case of RNN. To use the minimum amount of memory, we'd like that a variable to allocate memory when it has to, or, lazy memory allocation. Let's take the following example: ```cpp Variable vr, v1, v2; Tensor* t1 = new Tensor(); Tensor* t2 = new Tensor(); Randomize( /* malloc */ v1.GetMutable().mutable_data(DDim(100,200)), /* size */ t1.Size()); Randomize( /* malloc */ v2.GetMutable().mutable_data(DDim(200,300)), /* size */ t2.Size()); Mult( /*result*/ vr.GetMutable().mutable_data(SizeOfMult(v1, v2)), /*input1*/ v1.Get().data(), /*input2*/ v2.Get().data()); ``` We see that a variable holds nothing until `Variable::GetMutable()` allocates a tensor and puts it in the variable. Similarly, a tensor gets its memory until `Tensor::mutable_data()`. This syntax for lazy memory allocation when we call `Randomize` and `Mult`, those functions that mutate the variable, so it saves us some line of C++ code. ## Implementation: Type Hiding To make memory allocation lazy, we cannot assume that we know the type held by a variable at definition time. In other words, `class Variable` cannot be a template `template class Variable`. Because we don't know the type `T`, we cannot save a `T*` as `Variable's` data member. Instead, we save an interface object `Placeholder`, who can return the pointer to the saved object via `Placeholder::Ptr()` as `void*`. But anyway, Variable needs to know `T` so could it `delete(ptr)` and so could `Variable::Get` checks the expected type and the saved object's type. We save `T` in `PlaceholderImpl`, the implementation of `Placeholder`. Please be aware that `PlaceholderImpl` is a class template and `T` is passed in as a template parameter. Because `PlaceholderImpl` knows `T`, it can save and return `typeid(T)` for the type comparison in `Variable::Get` and `Variable::GetMutable`. ## Conclusion The technique type hiding utilizes C++ class templates, interface and derivation, and C++ RTTI (typeid). This combination saves us from definition something like `caffe2::TypeMata`, which takes hundreds of lines of C++ code.