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Node.js unofficially supports a shared library variant where the main node executable is a thin wrapper around node.dll/libnode.so. The key benefit of this is to support embedding Node.js in other applications. Since Node.js 12 there have been a number of issues preventing the shared library build from working correctly, primarily on Windows: * A number of functions used executables such as `mksnapshot` are not exported from `libnode.dll` using a `NODE_EXTERN` attribute * A dependency on the `Winmm` system library is missing * Incorrect defines on executable targets leads to `node.exe` claiming to export a number of functions that are actually in `libnode.dll` * Because `node.exe` attempts to export symbols, `node.lib` gets generated causing native extensions to try to link against `node.exe` not `libnode.dll`. * Similarly, because `node.dll` was renamed to `libnode.dll`, native extensions don't know to look for `libnode.lib` rather than `node.lib`. * On macOS an RPATH is added to find `libnode.dylib` relative to `node` in the same folder. This works fine from the `out/Release` folder but not from an installed prefix, where `node` will be in `bin/` and `libnode.dylib` will be in `lib/`. * Similarly on Linux, no RPATH is added so LD_LIBRARY_PATH needs setting correctly for `bin/node` to find `lib/libnode.so`. For the `libnode.lib` vs `node.lib` issue there are two possible options: 1. Ensure `node.lib` from `node.exe` does not get generated, and instead copy `libnode.lib` to `node.lib`. This means addons compiled when referencing the correct `node.lib` file will correctly depend on `libnode.dll`. The down side is that native addons compiled with stock Node.js will still try to resolve symbols against node.exe rather than libnode.dll. 2. After building `libnode.dll`, dump the exports using `dumpbin`, and process this to generate a `node.def` file to be linked into `node.exe` with the `/DEF:node.def` flag. The export entries in `node.def` will all read ``` my_symbol=libnode.my_symbol ``` so that `node.exe` will redirect all exported symbols back to `libnode.dll`. This has the benefit that addons compiled with stock Node.js will load correctly into `node.exe` from a shared library build, but means that every embedding executable also needs to perform this same trick. I went with the first option as it is the cleaner of the two solutions in my opinion. Projects wishing to generate a shared library variant of Node.js can now, for example, ``` .\vcbuild dll package vs ``` to generate a full node installation including `libnode.dll`, `Release\node.lib`, and all the necessary headers. Native addons can then be built against the shared library build easily by specifying the correct `nodedir` option. For example ``` >npx node-gyp configure --nodedir C:\Users\User\node\Release\node-v18.0.0-win-x64 ... >npx node-gyp build ... >dumpbin /dependents build\Release\binding.node Microsoft (R) COFF/PE Dumper Version 14.29.30136.0 Copyright (C) Microsoft Corporation. All rights reserved. Dump of file build\Release\binding.node File Type: DLL Image has the following dependencies: KERNEL32.dll libnode.dll VCRUNTIME140.dll api-ms-win-crt-string-l1-1-0.dll api-ms-win-crt-stdio-l1-1-0.dll api-ms-win-crt-runtime-l1-1-0.dll ... ``` PR-URL: https://github.com/nodejs/node/pull/41850 Reviewed-By: Michael Dawson <midawson@redhat.com> Reviewed-By: Beth Griggs <bgriggs@redhat.com> Reviewed-By: Richard Lau <rlau@redhat.com>
198 lines
7.0 KiB
C++
198 lines
7.0 KiB
C++
#include <Windows.h>
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#include <algorithm>
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#include <cstdint>
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#include <fstream>
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#include <iostream>
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#include <memory>
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#include <vector>
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// This executable takes a Windows DLL and uses it to generate
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// a module-definition file [1] which forwards all the exported
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// symbols from the DLL and redirects them back to the DLL.
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// This allows node.exe to export the same symbols as libnode.dll
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// when building Node.js as a shared library. This is conceptually
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// similary to the create_expfile.sh script used on AIX.
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//
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// Generating this .def file requires parsing data out of the
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// PE32/PE32+ file format. Helper structs are defined in <Windows.h>
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// hence why this is an executable and not a script. See [2] for
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// details on the PE format.
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//
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// [1]: https://docs.microsoft.com/en-us/cpp/build/reference/module-definition-dot-def-files
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// [2]: https://docs.microsoft.com/en-us/windows/win32/debug/pe-format
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// The PE32 format encodes pointers as Relative Virtual Addresses
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// which are 32 bit offsets from the start of the image. This helper
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// class hides the mess of the pointer arithmetic
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struct RelativeAddress {
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uintptr_t root;
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uintptr_t offset = 0;
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RelativeAddress(HMODULE handle) noexcept
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: root(reinterpret_cast<uintptr_t>(handle)) {}
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RelativeAddress(HMODULE handle, uintptr_t offset) noexcept
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: root(reinterpret_cast<uintptr_t>(handle)), offset(offset) {}
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RelativeAddress(uintptr_t root, uintptr_t offset) noexcept
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: root(root), offset(offset) {}
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template <typename T>
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const T* AsPtrTo() const noexcept {
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return reinterpret_cast<const T*>(root + offset);
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}
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template <typename T>
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T Read() const noexcept {
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return *AsPtrTo<T>();
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}
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RelativeAddress AtOffset(uintptr_t amount) const noexcept {
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return {root, offset + amount};
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}
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RelativeAddress operator+(uintptr_t amount) const noexcept {
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return {root, offset + amount};
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}
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RelativeAddress ReadRelativeAddress() const noexcept {
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return {root, Read<uint32_t>()};
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}
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};
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// A wrapper around a dynamically loaded Windows DLL. This steps through the
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// PE file structure to find the export directory and pulls out a list of
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// all the exported symbol names.
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struct Library {
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HMODULE library;
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std::string libraryName;
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std::vector<std::string> exportedSymbols;
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Library(HMODULE library) : library(library) {
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auto libnode = RelativeAddress(library);
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// At relative offset 0x3C is a 32 bit offset to the COFF signature, 4 bytes
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// after that is the start of the COFF header.
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auto coffHeaderPtr =
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libnode.AtOffset(0x3C).ReadRelativeAddress().AtOffset(4);
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auto coffHeader = coffHeaderPtr.AsPtrTo<IMAGE_FILE_HEADER>();
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// After the coff header is the Optional Header (which is not optional). We
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// don't know what type of optional header we have without examining the
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// magic number
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auto optionalHeaderPtr = coffHeaderPtr.AtOffset(sizeof(IMAGE_FILE_HEADER));
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auto optionalHeader = optionalHeaderPtr.AsPtrTo<IMAGE_OPTIONAL_HEADER>();
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auto exportDirectory =
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(optionalHeader->Magic == 0x20b) ? optionalHeaderPtr.AsPtrTo<IMAGE_OPTIONAL_HEADER64>()
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->DataDirectory[IMAGE_DIRECTORY_ENTRY_EXPORT]
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: optionalHeaderPtr.AsPtrTo<IMAGE_OPTIONAL_HEADER32>()
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->DataDirectory[IMAGE_DIRECTORY_ENTRY_EXPORT];
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auto exportTable = libnode.AtOffset(exportDirectory.VirtualAddress)
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.AsPtrTo<IMAGE_EXPORT_DIRECTORY>();
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// This is the name of the library without the suffix, this is more robust
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// than parsing the filename as this is what the linker uses.
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libraryName = libnode.AtOffset(exportTable->Name).AsPtrTo<char>();
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libraryName = libraryName.substr(0, libraryName.size() - 4);
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const uint32_t* functionNameTable =
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libnode.AtOffset(exportTable->AddressOfNames).AsPtrTo<uint32_t>();
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// Given an RVA, parse it as a std::string. The resulting string is empty
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// if the symbol does not have a name (i.e. it is ordinal only).
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auto nameRvaToName = [&](uint32_t rva) -> std::string {
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auto namePtr = libnode.AtOffset(rva).AsPtrTo<char>();
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if (namePtr == nullptr) return {};
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return {namePtr};
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};
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std::transform(functionNameTable,
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functionNameTable + exportTable->NumberOfNames,
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std::back_inserter(exportedSymbols),
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nameRvaToName);
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}
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~Library() { FreeLibrary(library); }
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};
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bool IsPageExecutable(void* address) {
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MEMORY_BASIC_INFORMATION memoryInformation;
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size_t rc = VirtualQuery(
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address, &memoryInformation, sizeof(MEMORY_BASIC_INFORMATION));
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if (rc != 0 && memoryInformation.Protect != 0) {
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return memoryInformation.Protect == PAGE_EXECUTE ||
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memoryInformation.Protect == PAGE_EXECUTE_READ ||
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memoryInformation.Protect == PAGE_EXECUTE_READWRITE ||
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memoryInformation.Protect == PAGE_EXECUTE_WRITECOPY;
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}
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return false;
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}
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Library LoadLibraryOrExit(const char* dllPath) {
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auto library = LoadLibrary(dllPath);
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if (library != nullptr) return library;
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auto error = GetLastError();
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std::cerr << "ERROR: Failed to load " << dllPath << std::endl;
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LPCSTR buffer = nullptr;
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auto rc = FormatMessageA(
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FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM,
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nullptr,
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error,
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LANG_USER_DEFAULT,
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(LPSTR)&buffer,
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0,
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nullptr);
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if (rc != 0) {
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std::cerr << buffer << std::endl;
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LocalFree((HLOCAL)buffer);
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}
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exit(1);
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}
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int main(int argc, char** argv) {
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if (argc != 3) {
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std::cerr << "Usage: " << argv[0]
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<< " path\\to\\libnode.dll path\\to\\node.def" << std::endl;
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return 1;
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}
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auto libnode = LoadLibraryOrExit(argv[1]);
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auto defFile = std::ofstream(argv[2]);
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defFile << "EXPORTS" << std::endl;
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for (const std::string& functionName : libnode.exportedSymbols) {
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// If a symbol doesn't have a name then it has been exported as an
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// ordinal only. We assume that only named symbols are exported.
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if (functionName.empty()) continue;
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// Every name in the exported symbols table should be resolvable
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// to an address because we have actually loaded the library into
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// our address space.
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auto address = GetProcAddress(libnode.library, functionName.c_str());
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if (address == nullptr) {
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std::cerr << "WARNING: " << functionName
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<< " appears in export table but is not a valid symbol"
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<< std::endl;
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continue;
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}
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defFile << " " << functionName << " = " << libnode.libraryName << "."
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<< functionName;
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// Nothing distinguishes exported global data from exported functions
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// with C linkage. If we do not specify the DATA keyword for such symbols
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// then consumers of the .def file will get a linker error. This manifests
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// as nodedbg_ symbols not being found. We assert that if the symbol is in
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// an executable page in this process then it is a function, not data.
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if (!IsPageExecutable(address)) {
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defFile << " DATA";
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}
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defFile << std::endl;
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}
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return 0;
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}
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