//===-- sanitizer_local_address_space_view.h --------------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // `LocalAddressSpaceView` provides the local (i.e. target and current address // space are the same) implementation of the `AddressSpaveView` interface which // provides a simple interface to load memory from another process (i.e. // out-of-process) // // The `AddressSpaceView` interface requires that the type can be used as a // template parameter to objects that wish to be able to operate in an // out-of-process manner. In normal usage, objects are in-process and are thus // instantiated with the `LocalAddressSpaceView` type. This type is used to // load any pointers in instance methods. This implementation is effectively // a no-op. When an object is to be used in an out-of-process manner it is // instansiated with the `RemoteAddressSpaceView` type. // // By making `AddressSpaceView` a template parameter of an object, it can // change its implementation at compile time which has no run time overhead. // This also allows unifying in-process and out-of-process code which avoids // code duplication. // //===----------------------------------------------------------------------===// #ifndef SANITIZER_LOCAL_ADDRES_SPACE_VIEW_H #define SANITIZER_LOCAL_ADDRES_SPACE_VIEW_H namespace __sanitizer { struct LocalAddressSpaceView { // Load memory `sizeof(T) * num_elements` bytes of memory from the target // process (always local for this implementation) starting at address // `target_address`. The local copy of this memory is returned as a pointer. // The caller should not write to this memory. The behaviour when doing so is // undefined. Callers should use `LoadWritable()` to get access to memory // that is writable. // // The lifetime of loaded memory is implementation defined. template static const T *Load(const T *target_address, uptr num_elements = 1) { // The target address space is the local address space so // nothing needs to be copied. Just return the pointer. return target_address; } // Load memory `sizeof(T) * num_elements` bytes of memory from the target // process (always local for this implementation) starting at address // `target_address`. The local copy of this memory is returned as a pointer. // The memory returned may be written to. // // Writes made to the returned memory will be visible in the memory returned // by subsequent `Load()` or `LoadWritable()` calls provided the // `target_address` parameter is the same. It is not guaranteed that the // memory returned by previous calls to `Load()` will contain any performed // writes. If two or more overlapping regions of memory are loaded via // separate calls to `LoadWritable()`, it is implementation defined whether // writes made to the region returned by one call are visible in the regions // returned by other calls. // // Given the above it is recommended to load the largest possible object // that requires modification (e.g. a class) rather than individual fields // from a class to avoid issues with overlapping writable regions. // // The lifetime of loaded memory is implementation defined. template static T *LoadWritable(T *target_address, uptr num_elements = 1) { // The target address space is the local address space so // nothing needs to be copied. Just return the pointer. return target_address; } }; } // namespace __sanitizer #endif