write DETAILS files for each major example
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GUIDE.txt
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GUIDE.txt
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#################################### Hello ####################################
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The main goal of this investigation is to organize shared data and code across
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multiple binary files. This is especially important for something like a base
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layer that will be used in a program that supports hot-reloading or plugins.
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layer that is used in a program that supports hot-reloading and/or plugins.
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Each isolated example in this repository explores a way to set up the base
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layer, plugin, and main program.
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This repository contains examples of source and build details needed to achieve
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dynamic linking (shared data and code) on Windows, and Linux, with the cl, gcc,
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and clang compilers.
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The examples:
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To start exploring an example navigate into the folder of the example and run
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the build script from your command line. It should generate an executable in
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a build/ folder. Each example also has a DETAILS.txt with info about the
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details that go into the example's structure and the expected output of the
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example program.
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################################### Topics ####################################
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Looking for a specific topic? This index tells you which example to jump to.
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exporting symbols -> win32_linking, linux_linking
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load-time import symbols -> win32_linking, linux_linking
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run-time linking symbols -> win32_linking, linux_linking
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building a .dll file -> win32_linking
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building a .so file -> linux_linking
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module initialization -> win32_before_main, linux_before_main
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cl build line options -> win32_linking
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gcc build line options -> linux_linking
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linux load-time search paths -> linux_linking
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clang build line options -> clang
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abstracted base layer -> xlist
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################################ The Examples #################################
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An explanation of the main ideas in each example.
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*_linking - Concrete examples for each operating system showing how to
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setup and use various types of dynamic linking. In these
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@ -11,4 +11,4 @@ cd build
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REM: Build
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clang %src%\win32_before_main.c
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clang %src%\win32_before_main.c -o win32_before_main.exe
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@echo off
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REM: It turns out the gcc syntax __attribute__((constructor)) works
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REM: on clang even for windows builds. You can run this script to
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REM: see for yourself.
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REM: Path setup
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cd ..\linux_before_main
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SET src=%cd%
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cd ..
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if not exist "build\" mkdir build
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cd build
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REM: Build
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clang %src%\linux_before_main.c -o win32_before_main_v2.exe
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@ -0,0 +1,9 @@
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gcc makes this really easy with a straightforward compiler extension. All we
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have to do is write a regular `void f(void)` function and mark it with:
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__attribute__((constructor))
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Literally that's it. Someone tell Microsoft how cool this is!
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@ -12,3 +12,16 @@ int main(){
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printf("x = %d\n", x);
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return(0);
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}
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#if 0
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// wrapped in a macro:
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#define BEFORE_MAIN(n) \
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__attribute__((constructor)) static void n(void)
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BEFORE_MAIN(before_main_rule){
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// do work here
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}
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#endif
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linux_main.c defines the executable linux_main.exe
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it depends on load-time linking with linux_base.so
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it tries to perform run-time linking with linux_plugin.so
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linux_base.c defines the binary linux_base.so
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linux_plugin.c defines the binary linux_plugin.so
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it depends on load-time linking with linux_base.so
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The build script has to build linux_base.c first because it needs the
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results of that build to setup the load-time linking in the other builds.
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The linux_base.so is used to resolve load-time imported symbols.
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The program has a shared data structure 'int x' in the 'base' layer that is
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read and modified from both the 'main' layer and 'plugin' layer.
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The expected output if the plugin loads successfully is:
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```
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x = 0
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provided by plugin: {
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x = 1
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x = 2
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}
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x = 3
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```
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The expected output if the plugin is not found is:
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```
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x = 0
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x = 1
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```
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The default Linux search paths for loading binaries do not include the
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current directory of the process, or the path to the executable binary file.
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It is possible to get it to behave like Windows binary loading, but some
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extra steps need to be taken. (Load-Time Search Paths) (Run-Time Search Paths)
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########################### Load-Time Search Paths ############################
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For load-time binary dependencies, we can actually bake extra search paths
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into a binary. GCC's options do not cover this, but there is a backdoor in
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GCC for talking right to the underlying linker (ld).
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The backdoor is the option -Wl (lowercase L). The syntax of this option is a
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little unusual. As soon as a space occurs the backdoor is closed, so the
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entire option has to be specified without any spaces. Since we need spaces,
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the backdoor lets us use commas. It will remove the commas and replace them
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with spaces before passing the command on to ld. It looks something like this:
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gcc ... -Wl,-option,value ...
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The specific option we want to pass through this way is -rpath. This option
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tells the linker to bake a path into the search paths of the binary, so the
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syntax for specifying a path this way with the backdoor syntax is:
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gcc ... -Wl,-rpath,loadpath ...
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In order to get the same behavior as we have on Windows, we want the path to
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be relative to the binary itself. This can be done using the special syntax
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'$ORIGIN/' as the path. But there is a problem here too. The dollar sign
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already has a meaning in the shell, so to actually pass a raw dollar sign we
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actually have to escape it with a backslash. Putting it all together the option
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looks like this:
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gcc ... -Wl,-rpath,\$ORIGIN/ ...
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If that seems like a lot, that's because it is A LOT.
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It's also pretty atypical to do things this way on Linux where the system tries
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to have a specific place to put all the different pieces of executables. In
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particular you might try to put the executable in a 'bin/' folder and the
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shared object binaries in a 'lib/' folder. Then you would use the binary
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relative path like this:
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gcc ... -Wl,-rpath,\$ORIGIN/../lib ...
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############################ Run-Time Search Paths ############################
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The search paths for dlopen only include the system binary paths by default.
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This matters if we are calling dlopen like this:
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dlopen("mylayer.so", flags)
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In this case the search paths will not include any binary relative rules or
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current directory relative rules.
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We can use $ORIGIN like we did in the load-time case to specify paths relative
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to the calling binary:
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dlopen("$ORIGIN/mylayer.so", flags)
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Since this version is not just a base file name, the system search paths are
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ignored and the path indicated by $ORIGIN is inspected directly.
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We can also use . to specify the current directory like we do on the command
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line when we call a script or run an executable in the current directory:
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dlopen("./mylayer.so", flags)
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In this case the system will look exactly in the current directory.
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Finally we can use full paths to specify a directory without ambiguity:
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dlopen("/home/username/pluginproject/mylayer.so", flags)
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The nice thing about this option is that it means we can perform our own
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search on the file system, and assemble a full path to get exactly what we want
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if we have to.
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// to call a function with run-time linking, we must manually load and link it
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void *module = dlopen("./linux_plugin.so", RTLD_NOW);
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void *module = dlopen("$ORIGIN/linux_plugin.so", RTLD_NOW);
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if (module != 0){
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GET_PROC(plugin_func, module, "plugin_func");
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}
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Being able to run code 'before main' isn't just a magic trick. In a situation
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where there may be more than one layer with dynamic linking and more than one
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.dll (plugin system for instance), the maintenance burden of setting up each
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layer in a central DllMain or main is significant enough to be a burden.
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It is possible to get this effect on Windows through the CL compiler, but it
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would be a stretch to say that it is "supported". The way I show here works
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by relying on the fact that a special section does exist that contains function
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pointers that run before 'main' or 'DllMain'. We can use CL's compiler
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extensions to add a function pointer to that section just by declaring it as a
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global variable and marking it up with:
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__declspec(allocate(".CRT$XCU"))
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If you look up this method on the internet, you will find claims that under
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certain types of whole-program optimization, this won't work. In particular
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this happens if you use the option /GL in CL.
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This happens because the global variable appears to be unused from the
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perspective of the compiler & linker. Since it is never directly referenced,
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there is no C-level semantical reason to think this global variable is doing
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anything.
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However, in this example I show how we can still make it work. We have to
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make sure the linker won't eliminate the global variable that we are trying to
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place into the ".CRT$XCU" section. I achieve this by marking it as an export
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symbol. Export symbols can't be eliminated even if they aren't used locally.
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From what I've seen in testing, this works as desired, even with the /GL option.
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IMPORTANT RESTRICTION: Because this creates an export symbol, each time we use
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this within a binary it must have a unique name. Generally I would recommend
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naming before-main symbol by scoping it to the layer where it exists.
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CLANG NOTE: Interestingly, clang can build this, but it can also use the
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__attribute__((constructor)) extension on Windows, which is a lot closer to
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"supporting" this feature. I suspect that When I am building with clang I will
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prefer to go with this option most of the time.
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// set the before-main execution function pointer
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__declspec(allocate(".CRT$XCU"))
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__pragma(comment(linker, "/INCLUDE:run_before_main_ptr"))
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__declspec(dllexport)
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void (*run_before_main_ptr)(void) = run_before_main_func;
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// define the "before main" function
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printf("x = %d\n", x);
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return(0);
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}
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#if 0
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// wrapped in a macro:
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#define BEFORE_MAIN(n) static void n(void); \
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__declspec(allocate(".CRT$XCU")) \
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__declspec(dllexport) \
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void (*n##__)(void) = n; \
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static void n(void)
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BEFORE_MAIN(before_main_rule){
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// do work here
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}
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#endif
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win32_main.c defines the executable win32_main.exe
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it depends on load-time linking with win32_base.dll
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it tries to perform run-time linking with win32_plugin.dll
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win32_base.c defines the binary win32_base.dll
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win32_plugin.c defines the binary win32_plugin.dll
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it depends on load-time linking with win32_base.dll
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The build script has to build win32_base.c first because it needs the
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results of that build to setup the load-time linking in the other builds.
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The win32_base.lib that is generated along with win32_base.dll is used
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to resolve load-time imported symbols.
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The program has a shared data structure 'int x' in the 'base' layer that is
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read and modified from both the 'main' layer and 'plugin' layer.
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The expected output if the plugin loads successfully is:
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```
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x = 0
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provided by plugin: {
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x = 1
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x = 2
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}
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x = 3
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```
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The expected output if the plugin is not found is:
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```
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x = 0
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x = 1
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```
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You should be able to relocate the plugin and use a full path to it and still
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get the first result. As long as the load-time dependency win32_base.dll is
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with the executable, it will load. It can be found in some other paths, but
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you cannot specify the search paths manually, so keeping it with the executable
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is the simplest option.
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In this example I link everything through run-time linking. The upsides to this
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are that everything dealing with the linking is in my code so I can tweak it
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or debug it directly, and I don't have a mix of load-time and run-time linking
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making the wranling of keyword abstraction and linker options simpler.
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There are some downsides too, and in this example I show how I can mitigate
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these downsides pretty well.
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The two big downsides I address in this example are:
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1. Symbol declaration and binding gets more difficult in C
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2. Each binary requires some dynamic initialization
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Finally after going over these problems in detail, I will present some details
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of the solution I use in this example.
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Like the *_linking examples, the expected output if the plugin loads
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successfully is:
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```
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x = 0
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provided by plugin: {
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x = 1
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x = 2
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}
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x = 3
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```
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And the expected output if the plugin is not found is:
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```
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x = 0
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x = 1
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```
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############################# Symbol Declaration ##############################
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The symbol declaration problem requires a bit of setup to fully appreciate.
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Normally in C you think of your program code as header & implementation, or
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declaration & definition.
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So we might have a header file like:
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`layer.h`
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```
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void* layer_a(int x);
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void layer_b(void *a, void *m);
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int layer_c(void *a);
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```
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And then an implementation file like:
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`layer.c`
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```
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void* layer_a(int x){
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// ...
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}
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void layer_b(void *a, void *m){
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// ...
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}
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int layer_c(void *a){
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// ...
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}
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```
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Whether we are linking these statically (unity build) or across object files
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(classic build) it's pretty easy, the header just gets included at all usage
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and implementation sites as it is.
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When we transition to linking across binaries, we hit a problem. The reason we
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hit a problem is that with run-time linking we need to be directing our
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calls through function pointers instead of through functions.
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## Solution: reroute from function to function pointer ##
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One way to handle this is to keep header and provide a different implementation
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file:
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`layer.dynamic.c`
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```
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void* layer_a(int x){
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return(layer_funcs->layer_a(x));
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}
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void layer_b(void *a, void *m){
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layer_funcs->layer_b(a, m);
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}
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int layer_c(void *a){
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return(layer_funcs->layer_c(a));
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}
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```
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Then on the side that defines the symbols, we still use `layer.c` but in any
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binary that wants to load the symbols, we would use `layer.dynamic.c` which
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reroutes the normal function calls to function pointers.
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This `*.dynamic.c` file is pretty fatty though - requiring several lines of
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pattern duplication for each function in the layer.
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A metaprogramming system can help here if you want to go that route, but
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putting another build program in the mix isn't exactly light weight either.
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## Solution: call through function pointer table ##
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Another option is to say that the place where the issue will pop-out is at
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all the usage sites. Any code written as a user of the layer will switch from
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calling the layer like this `layer_foo( ... )` to `layer->foo( ... )`.
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In theory this eliminates maintenance work, but oh boy are we in for it the
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first time we realize we have a helper that wants to work in both the context
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of the layer's user AND the layer's definer. At that point we're either
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duplicating the helper, which leads us to minimize the richness of helpers we
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develop around the layer, or we put them in some kind of unifying
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wrapper, which is the problem we were trying to solve in the first place.
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## Solution: global function pointers ##
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A third way to handle this is to define a new version of the header:
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`layer.dynamic.h`
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```
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void* (*layer_a)(int x) = 0;
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void (*layer_b)(void *a, void *m) = 0;
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int (*layer_c)(void *a) = 0;
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```
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In this version each function symbol that the user wants to see gets replaced
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with a global function pointer.
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Now each usage site can looks like a function usage site. We still have some
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maintenance burden increase like in the `*.dynamic.c` but not as much. What's
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really nice about this version is we can actually generate this from an xlist.
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We can't so easily use an xlist in the other case because the pattern expansion
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is a little too heterogenous.
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This is essentially what I do in this example. I generate the function pointers
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from an xlist. I don't have a separate `base.dynamic.h` though, I just
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put both versions of the function symbols in `base.h` and use the preprocessor
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to select one or the other. This way they can easily have shared type
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definitions and constants.
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## Conclusion: Symbol Declaration ##
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So the symbol declaration problem is really about deciding how to provide the
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declarations that allow us to refer to symbols that get resolved dynamically.
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This is only a problem for run-time linking because with load-time linking we
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can just create regular function symbols with some special mark up. It would
|
||||
be nice if C had anticipated this and gave us a better way to define these
|
||||
run-time resolved symbols with the same basic syntax we use for regular
|
||||
function symbols. But alas, that's not how it is.
|
||||
|
||||
|
||||
########################### Dynamic Initialization ############################
|
||||
|
||||
The dynamic initialization problem is about how to maintain the run-time
|
||||
linking code.
|
||||
|
||||
Imagine we have a 'base' layer like this:
|
||||
|
||||
`base.h`
|
||||
|
||||
```
|
||||
void base_a(void);
|
||||
void base_b(void);
|
||||
void base_c(void);
|
||||
```
|
||||
|
||||
If we just maintain the run-time linking with brute force our run-time linking
|
||||
code would look *something* like this:
|
||||
|
||||
```
|
||||
void base_init(void){
|
||||
Library *library = library_open("base");
|
||||
GET_PROC(base_a, library, "base_a");
|
||||
GET_PROC(base_b, library, "base_b");
|
||||
GET_PROC(base_c, library, "base_c");
|
||||
}
|
||||
```
|
||||
|
||||
The exact details depend on how you've solved the symbol declaration problem
|
||||
and on the operating system APIs for loading and linking binaries.
|
||||
|
||||
We can easily clean up the maintenance burden of this part with an xlist, or
|
||||
by using a single GET_PROC which then passes through a function pointer table
|
||||
with the rest of the layer's functions.
|
||||
|
||||
The other part of dynamic initialization problem is deciding how we will ensure
|
||||
the initialization actually gets done.
|
||||
|
||||
For instance, let's look at the layers used in this example 'base' 'plugin' and
|
||||
'main'. Both 'plugin' and 'main' are users of 'base'. 'main' is responsible for
|
||||
loading 'plugin' if it wants to, and for proceeding gracefully if the 'plugin'
|
||||
is missing.
|
||||
|
||||
We need to ensure `base_init` gets called in each binary.
|
||||
|
||||
## Solution: manual initialization ##
|
||||
|
||||
For 'main' we would just say it's the responsibility of the entry point to call
|
||||
`base_init`.
|
||||
|
||||
For 'plugin' we have two options. The first option is that when 'main' loads
|
||||
the 'plugin' layer it is responsible for reaching into the module, finding its
|
||||
`base_init` function and calling it. The second option is that the 'plugin'
|
||||
module has an on-load entry point that calls `base_init`.
|
||||
|
||||
None of these options are "broken" but they do require some extra
|
||||
hand shaking and protocol designing between all these binaries.
|
||||
|
||||
## Solution: automatic initialization ##
|
||||
|
||||
Another option is to have the 'base' layer itself provide the code that does
|
||||
all of the initialization automatically for the users of the 'base' layer. In
|
||||
order to do this 'base' will need to be able to write something like an
|
||||
"on-load hook". A function that gets called automatically when the binary
|
||||
loads. The code that defines the 'base' layer will only insert this hook into
|
||||
binaries that are trying to run-time link to the 'base' layer definitions.
|
||||
|
||||
In the *_before_main examples I show how it is actually possible to do this in
|
||||
C, although the details are admittedly sketchy in the case of Windows with the
|
||||
CL compiler.
|
||||
|
||||
This basically lets us emulate the automatic linking provided by load-time
|
||||
linking, but as a downside, it means we have less flexibility about how the
|
||||
layer gets loaded.
|
||||
|
||||
|
||||
################################## Solution ###################################
|
||||
|
||||
The big idea of my solution is to use an xlist to minimize maintenance burden
|
||||
without bringing in a whole cloth code generator.
|
||||
|
||||
I put all the 'base' layer functions that will be run-time linked into an
|
||||
xlist file `base.xlist.h`.
|
||||
|
||||
I also put the normal style of symbol definition list in `base.h`. Technically
|
||||
I don't need this, I could just generate it from the xlist, but then I don't
|
||||
have any "normal" looking version of the function declarations. The xlist is
|
||||
highly reusable, suitable for almost every purpose, but it is not very
|
||||
readable. Users of my code should be able to just skim some natural looking
|
||||
C code with comments and formatting to understand the code they are using.
|
||||
|
||||
I setup a function pointer table `BASE_Funcs` so that I only have to export
|
||||
one symbol from the 'base' layer implementor. That symbol fills and exposes
|
||||
the function pointer table for run-time linking.
|
||||
|
||||
When the base layer is included in a binary that is not the implementor the
|
||||
'base' layer generates a before-main hook to load the 'base' layer and
|
||||
perform the run-time linking.
|
||||
|
||||
Thanks to this design neither 'main' nor 'plugin' have to do anything to
|
||||
start using the 'base' layer except to include it.
|
|
@ -53,7 +53,7 @@ BEFORE_MAIN(base_dynamic_user_init){
|
|||
}
|
||||
}
|
||||
#elif OS_LINUX
|
||||
void *module = dlopen("./base.so", RTLD_NOW);
|
||||
void *module = dlopen("$ORIGIN/base.so", RTLD_NOW);
|
||||
if (module != 0){
|
||||
BASE_ExportFuncs *base_export_functions = (BASE_ExportFuncs*)dlsym(module, "base_export_functions");
|
||||
if (base_export_functions != 0){
|
||||
|
|
14
xlist/base.h
14
xlist/base.h
|
@ -27,14 +27,16 @@
|
|||
#endif
|
||||
|
||||
|
||||
// before-main abstraction
|
||||
|
||||
#if OS_WINDOWS
|
||||
|
||||
# pragma section(".CRT$XCU", read)
|
||||
|
||||
# define BEFORE_MAIN(n) static void n(void); \
|
||||
__declspec(allocate(".CRT$XCU")) \
|
||||
__pragma(comment(linker, "/INCLUDE:" #n "__")) \
|
||||
void (*n##__)(void) = n; \
|
||||
# define BEFORE_MAIN(n) static void n(void); \
|
||||
__declspec(allocate(".CRT$XCU")) \
|
||||
__declspec(dllexport) \
|
||||
void (*n##__)(void) = n; \
|
||||
static void n(void)
|
||||
|
||||
#elif OS_LINUX
|
||||
|
@ -46,10 +48,6 @@ __attribute__((constructor)) static void n(void)
|
|||
# error BEFORE_MAIN missing for this OS
|
||||
#endif
|
||||
|
||||
// base layer types
|
||||
|
||||
typedef void BASE_Library;
|
||||
|
||||
|
||||
// base symbols shared
|
||||
|
||||
|
|
Loading…
Reference in New Issue