#pragma once //auto execute(const string& name, const string& args...) -> string; //[[synchronous]] //executes program, waits for completion, and returns data written to stdout //auto invoke(const string& name, const string& args...) -> void; //[[asynchronous]] //if a program is specified, it is executed with the arguments provided //if a file is specified, the file is opened using the program associated with said file type //if a folder is specified, the folder is opened using the associated file explorer //if a URL is specified, the default web browser is opened and pointed at the URL requested #include #include namespace nall { struct execute_result_t { explicit operator bool() const { return code == EXIT_SUCCESS; } int code = EXIT_FAILURE; string output; string error; }; #if defined(PLATFORM_MACOSX) || defined(PLATFORM_LINUX) || defined(PLATFORM_BSD) template inline auto execute(const string& name, P&&... p) -> execute_result_t { int fdout[2]; int fderr[2]; if(pipe(fdout) == -1) return {}; if(pipe(fderr) == -1) return {}; pid_t pid = fork(); if(pid == 0) { const char* argv[1 + sizeof...(p) + 1]; const char** argp = argv; lstring argl(forward

(p)...); *argp++ = (const char*)name; for(auto& arg : argl) *argp++ = (const char*)arg; *argp++ = nullptr; dup2(fdout[1], STDOUT_FILENO); dup2(fderr[1], STDERR_FILENO); close(fdout[0]); close(fderr[0]); close(fdout[1]); close(fderr[1]); execvp(name, (char* const*)argv); //this is called only if execvp fails: //use _exit instead of exit, to avoid destroying key shared file descriptors _exit(EXIT_FAILURE); } else { close(fdout[1]); close(fderr[1]); char buffer[256]; execute_result_t result; while(true) { auto size = read(fdout[0], buffer, sizeof(buffer)); if(size <= 0) break; auto offset = result.output.size(); result.output.resize(offset + size); memory::copy(result.output.get() + offset, buffer, size); } while(true) { auto size = read(fderr[0], buffer, sizeof(buffer)); if(size <= 0) break; auto offset = result.error.size(); result.error.resize(offset + size); memory::copy(result.error.get() + offset, buffer, size); } close(fdout[0]); close(fderr[0]); int status = 0; waitpid(pid, &status, 0); if(!WIFEXITED(status)) return {}; result.code = WEXITSTATUS(status); return result; } } template inline auto invoke(const string& name, P&&... p) -> void { pid_t pid = fork(); if(pid == 0) { const char* argv[1 + sizeof...(p) + 1]; const char** argp = argv; lstring argl(forward

(p)...); *argp++ = (const char*)name; for(auto& arg : argl) *argp++ = (const char*)arg; *argp++ = nullptr; if(execvp(name, (char* const*)argv) < 0) { execlp("xdg-open", "xdg-open", (const char*)name, nullptr); } exit(0); } } #elif defined(PLATFORM_WINDOWS) template inline auto execute(const string& name, P&&... p) -> execute_result_t { lstring argl(name, forward

(p)...); for(auto& arg : argl) if(arg.find(" ")) arg = {"\"", arg, "\""}; string arguments = argl.merge(" "); SECURITY_ATTRIBUTES sa; ZeroMemory(&sa, sizeof(SECURITY_ATTRIBUTES)); sa.nLength = sizeof(SECURITY_ATTRIBUTES); sa.bInheritHandle = true; sa.lpSecurityDescriptor = nullptr; HANDLE stdoutRead; HANDLE stdoutWrite; if(!CreatePipe(&stdoutRead, &stdoutWrite, &sa, 0)) return {}; if(!SetHandleInformation(stdoutRead, HANDLE_FLAG_INHERIT, 0)) return {}; HANDLE stderrRead; HANDLE stderrWrite; if(!CreatePipe(&stderrRead, &stderrWrite, &sa, 0)) return {}; if(!SetHandleInformation(stderrRead, HANDLE_FLAG_INHERIT, 0)) return {}; HANDLE stdinRead; HANDLE stdinWrite; if(!CreatePipe(&stdinRead, &stdinWrite, &sa, 0)) return {}; if(!SetHandleInformation(stdinWrite, HANDLE_FLAG_INHERIT, 0)) return {}; STARTUPINFO si; ZeroMemory(&si, sizeof(STARTUPINFO)); si.cb = sizeof(STARTUPINFO); si.hStdOutput = stdoutWrite; si.hStdError = stderrWrite; si.hStdInput = stdinRead; si.dwFlags = STARTF_USESTDHANDLES; PROCESS_INFORMATION pi; ZeroMemory(&pi, sizeof(PROCESS_INFORMATION)); if(!CreateProcess( nullptr, utf16_t(arguments), nullptr, nullptr, true, CREATE_NO_WINDOW, nullptr, nullptr, &si, &pi )) return {}; DWORD exitCode = EXIT_FAILURE; if(WaitForSingleObject(pi.hProcess, INFINITE)) return {}; if(!GetExitCodeProcess(pi.hProcess, &exitCode)) return {}; CloseHandle(pi.hThread); CloseHandle(pi.hProcess); char buffer[256]; execute_result_t result; result.code = exitCode; while(true) { DWORD read, available, remaining; if(!PeekNamedPipe(stdoutRead, nullptr, sizeof(buffer), &read, &available, &remaining)) break; if(read == 0) break; if(!ReadFile(stdoutRead, buffer, sizeof(buffer), &read, nullptr)) break; if(read == 0) break; auto offset = result.output.size(); result.output.resize(offset + read); memory::copy(result.output.get() + offset, buffer, read); } while(true) { DWORD read, available, remaining; if(!PeekNamedPipe(stderrRead, nullptr, sizeof(buffer), &read, &available, &remaining)) break; if(read == 0) break; if(!ReadFile(stderrRead, buffer, sizeof(buffer), &read, nullptr)) break; if(read == 0) break; auto offset = result.error.size(); result.error.resize(offset + read); memory::copy(result.error.get() + offset, buffer, read); } return result; } template inline auto invoke(const string& name, P&&... p) -> void { lstring argl(forward

(p)...); for(auto& arg : argl) if(arg.find(" ")) arg = {"\"", arg, "\""}; string arguments = argl.merge(" "); ShellExecute(nullptr, nullptr, utf16_t(name), utf16_t(arguments), nullptr, SW_SHOWNORMAL); } #else template inline auto execute(const string& name, P&&... p) -> string { return ""; } template inline auto invoke(const string& name, P&&... p) -> void { } #endif }