advtrains.git - Advtrains mod for minetest.

	Commit message (Expand)	Author	Age
*	Add signal safety control override, restructure control system	orwell96	2018-10-10
*	Mainly make collisions and coupling work	orwell96	2018-06-14
*	Add digiline interface and is_passive function to LuaATC	orwell96	2018-04-25
*	Rewrite rail connection system...	orwell96	2017-12-18
*	Implement multi-occupation in detector.on_node table to finally fix collisions	orwell96	2017-10-25
*	Set wagon line number	Gabriel Pérez-Cerezo	2017-10-23
*	Remove zip release files, move mod to root, exclude assets from Makefile (#92)	rubenwardy	2017-09-20

/* Minetest Copyright (C) 2013 celeron55, Perttu Ahola <celeron55@gmail.com> This program is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include "socket.h" // for select() #include "porting.h" // for sleep_ms(), get_sysinfo() #include "httpfetch.h" #include <iostream> #include <sstream> #include <list> #include <map> #include <errno.h> #include "jthread/jevent.h" #include "config.h" #include "exceptions.h" #include "debug.h" #include "log.h" #include "util/container.h" #include "util/thread.h" #include "version.h" #include "main.h" #include "settings.h" JMutex g_httpfetch_mutex; std::map<unsigned long, std::list<HTTPFetchResult> > g_httpfetch_results; HTTPFetchRequest::HTTPFetchRequest() { url = ""; caller = HTTPFETCH_DISCARD; request_id = 0; timeout = g_settings->getS32("curl_timeout"); connect_timeout = timeout; multipart = false; useragent = std::string("Minetest/") + minetest_version_hash + " (" + porting::get_sysinfo() + ")"; } static void httpfetch_deliver_result(const HTTPFetchResult &fetch_result) { unsigned long caller = fetch_result.caller; if (caller != HTTPFETCH_DISCARD) { JMutexAutoLock lock(g_httpfetch_mutex); g_httpfetch_results[caller].push_back(fetch_result); } } static void httpfetch_request_clear(unsigned long caller); unsigned long httpfetch_caller_alloc() { JMutexAutoLock lock(g_httpfetch_mutex); // Check each caller ID except HTTPFETCH_DISCARD const unsigned long discard = HTTPFETCH_DISCARD; for (unsigned long caller = discard + 1; caller != discard; ++caller) { std::map<unsigned long, std::list<HTTPFetchResult> >::iterator it = g_httpfetch_results.find(caller); if (it == g_httpfetch_results.end()) { verbosestream<<"httpfetch_caller_alloc: allocating " <<caller<<std::endl; // Access element to create it g_httpfetch_results[caller]; return caller; } } assert("httpfetch_caller_alloc: ran out of caller IDs" == 0); return discard; } void httpfetch_caller_free(unsigned long caller) { verbosestream<<"httpfetch_caller_free: freeing " <<caller<<std::endl; httpfetch_request_clear(caller); if (caller != HTTPFETCH_DISCARD) { JMutexAutoLock lock(g_httpfetch_mutex); g_httpfetch_results.erase(caller); } } bool httpfetch_async_get(unsigned long caller, HTTPFetchResult &fetch_result) { JMutexAutoLock lock(g_httpfetch_mutex); // Check that caller exists std::map<unsigned long, std::list<HTTPFetchResult> >::iterator it = g_httpfetch_results.find(caller); if (it == g_httpfetch_results.end()) return false; // Check that result queue is nonempty std::list<HTTPFetchResult> &caller_results = it->second; if (caller_results.empty()) return false; // Pop first result fetch_result = caller_results.front(); caller_results.pop_front(); return true; } #if USE_CURL #include <curl/curl.h> /* USE_CURL is on: use cURL based httpfetch implementation */ static size_t httpfetch_writefunction( char *ptr, size_t size, size_t nmemb, void *userdata) { std::ostringstream *stream = (std::ostringstream*)userdata; size_t count = size * nmemb; stream->write(ptr, count); return count; } static size_t httpfetch_discardfunction( char *ptr, size_t size, size_t nmemb, void *userdata) { return size * nmemb; } class CurlHandlePool { std::list<CURL*> handles; public: CurlHandlePool() {} ~CurlHandlePool() { for (std::list<CURL*>::iterator it = handles.begin(); it != handles.end(); ++it) { curl_easy_cleanup(*it); } } CURL * alloc() { CURL *curl; if (handles.empty()) { curl = curl_easy_init(); if (curl == NULL) { errorstream<<"curl_easy_init returned NULL"<<std::endl; } } else { curl = handles.front(); handles.pop_front(); } return curl; } void free(CURL *handle) { if (handle) handles.push_back(handle); } }; class HTTPFetchOngoing { public: HTTPFetchOngoing(HTTPFetchRequest request, CurlHandlePool *pool); ~HTTPFetchOngoing(); CURLcode start(CURLM *multi); const HTTPFetchResult * complete(CURLcode res); const HTTPFetchRequest &getRequest() const { return request; }; const CURL *getEasyHandle() const { return curl; }; private: CurlHandlePool *pool; CURL *curl; CURLM *multi; HTTPFetchRequest request; HTTPFetchResult result; std::ostringstream oss; char *post_fields; struct curl_slist *http_header; curl_httppost *post; }; HTTPFetchOngoing::HTTPFetchOngoing(HTTPFetchRequest request_, CurlHandlePool *pool_): pool(pool_), curl(NULL), multi(NULL), request(request_), result(request_), oss(std::ios::binary), http_header(NULL), post(NULL) { curl = pool->alloc(); if (curl == NULL) { return; } // Set static cURL options curl_easy_setopt(curl, CURLOPT_NOSIGNAL, 1); curl_easy_setopt(curl, CURLOPT_FAILONERROR, 1); curl_easy_setopt(curl, CURLOPT_FOLLOWLOCATION, 1); curl_easy_setopt(curl, CURLOPT_MAXREDIRS, 1); std::string bind_address = g_settings->get("bind_address"); if (!bind_address.empty()) { curl_easy_setopt(curl, CURLOPT_INTERFACE, bind_address.c_str()); } #if LIBCURL_VERSION_NUM >= 0x071304 // Restrict protocols so that curl vulnerabilities in // other protocols don't affect us. // These settings were introduced in curl 7.19.4. long protocols = CURLPROTO_HTTP | CURLPROTO_HTTPS | CURLPROTO_FTP | CURLPROTO_FTPS; curl_easy_setopt(curl, CURLOPT_PROTOCOLS, protocols); curl_easy_setopt(curl, CURLOPT_REDIR_PROTOCOLS, protocols); #endif // Set cURL options based on HTTPFetchRequest curl_easy_setopt(curl, CURLOPT_URL, request.url.c_str()); curl_easy_setopt(curl, CURLOPT_TIMEOUT_MS, request.timeout); curl_easy_setopt(curl, CURLOPT_CONNECTTIMEOUT_MS, request.connect_timeout); if (request.useragent != "") curl_easy_setopt(curl, CURLOPT_USERAGENT, request.useragent.c_str()); // Set up a write callback that writes to the // ostringstream ongoing->oss, unless the data // is to be discarded if (request.caller == HTTPFETCH_DISCARD) { curl_easy_setopt(curl, CURLOPT_WRITEFUNCTION, httpfetch_discardfunction); curl_easy_setopt(curl, CURLOPT_WRITEDATA, NULL); } else { curl_easy_setopt(curl, CURLOPT_WRITEFUNCTION, httpfetch_writefunction); curl_easy_setopt(curl, CURLOPT_WRITEDATA, &oss); } // Set POST (or GET) data if (request.post_fields.empty()) { curl_easy_setopt(curl, CURLOPT_HTTPGET, 1); } else if (request.multipart) { curl_httppost *last = NULL; for (std::map<std::string, std::string>::iterator it = request.post_fields.begin(); it != request.post_fields.end(); ++it) { curl_formadd(&post, &last, CURLFORM_NAMELENGTH, it->first.size(), CURLFORM_PTRNAME, it->first.c_str(), CURLFORM_CONTENTSLENGTH, it->second.size(), CURLFORM_PTRCONTENTS, it->second.c_str(), CURLFORM_END); } curl_easy_setopt(curl, CURLOPT_HTTPPOST, post); // request.post_fields must now *never* be // modified until CURLOPT_HTTPPOST is cleared } else if (request.post_data.empty()) { curl_easy_setopt(curl, CURLOPT_POST, 1); std::string str; for (std::map<std::string, std::string>::iterator it = request.post_fields.begin(); it != request.post_fields.end(); ++it) { if (str != "") str += "&"; str += urlencode(it->first); str += "="; str += urlencode(it->second); } curl_easy_setopt(curl, CURLOPT_POSTFIELDSIZE, str.size()); curl_easy_setopt(curl, CURLOPT_COPYPOSTFIELDS, str.c_str()); } else { curl_easy_setopt(curl, CURLOPT_POST, 1); curl_easy_setopt(curl, CURLOPT_POSTFIELDSIZE, request.post_data.size()); curl_easy_setopt(curl, CURLOPT_POSTFIELDS, request.post_data.c_str()); // request.post_data must now *never* be // modified until CURLOPT_POSTFIELDS is cleared } // Set additional HTTP headers for (std::vector<std::string>::iterator it = request.extra_headers.begin(); it != request.extra_headers.end(); ++it) { http_header = curl_slist_append(http_header, it->c_str()); } curl_easy_setopt(curl, CURLOPT_HTTPHEADER, http_header); if (!g_settings->getBool("curl_verify_cert")) { curl_easy_setopt(curl, CURLOPT_SSL_VERIFYPEER, false); } } CURLcode HTTPFetchOngoing::start(CURLM *multi_) { if (!curl) return CURLE_FAILED_INIT; if (!multi_) { // Easy interface (sync) return curl_easy_perform(curl); } // Multi interface (async) CURLMcode mres = curl_multi_add_handle(multi_, curl); if (mres != CURLM_OK) { errorstream << "curl_multi_add_handle" << " returned error code " << mres << std::endl; return CURLE_FAILED_INIT; } multi = multi_; // store for curl_multi_remove_handle return CURLE_OK; } const HTTPFetchResult * HTTPFetchOngoing::complete(CURLcode res) { result.succeeded = (res == CURLE_OK); result.timeout = (res == CURLE_OPERATION_TIMEDOUT); result.data = oss.str(); // Get HTTP/FTP response code result.response_code = 0; if (curl && (curl_easy_getinfo(curl, CURLINFO_RESPONSE_CODE, &result.response_code) != CURLE_OK)) { // We failed to get a return code, make sure it is still 0 result.response_code = 0; } if (res != CURLE_OK) { errorstream << request.url << " not found (" << curl_easy_strerror(res) << ")" << " (response code " << result.response_code << ")" << std::endl; } return &result; } HTTPFetchOngoing::~HTTPFetchOngoing() { if (multi) { CURLMcode mres = curl_multi_remove_handle(multi, curl); if (mres != CURLM_OK) { errorstream << "curl_multi_remove_handle" << " returned error code " << mres << std::endl; } } // Set safe options for the reusable cURL handle curl_easy_setopt(curl, CURLOPT_WRITEFUNCTION, httpfetch_discardfunction); curl_easy_setopt(curl, CURLOPT_WRITEDATA, NULL); curl_easy_setopt(curl, CURLOPT_POSTFIELDS, NULL); if (http_header) { curl_easy_setopt(curl, CURLOPT_HTTPHEADER, NULL); curl_slist_free_all(http_header); } if (post) { curl_easy_setopt(curl, CURLOPT_HTTPPOST, NULL); curl_formfree(post); } // Store the cURL handle for reuse pool->free(curl); } class CurlFetchThread : public JThread { protected: enum RequestType { RT_FETCH, RT_CLEAR, RT_WAKEUP, }; struct Request { RequestType type; HTTPFetchRequest fetch_request; Event *event; }; CURLM *m_multi; MutexedQueue<Request> m_requests; size_t m_parallel_limit; // Variables exclusively used within thread std::vector<HTTPFetchOngoing*> m_all_ongoing; std::list<HTTPFetchRequest> m_queued_fetches; public: CurlFetchThread(int parallel_limit) { if (parallel_limit >= 1) m_parallel_limit = parallel_limit; else m_parallel_limit = 1; } void requestFetch(const HTTPFetchRequest &fetch_request) { Request req; req.type = RT_FETCH; req.fetch_request = fetch_request; req.event = NULL; m_requests.push_back(req); } void requestClear(unsigned long caller, Event *event) { Request req; req.type = RT_CLEAR; req.fetch_request.caller = caller; req.event = event; m_requests.push_back(req); } void requestWakeUp() { Request req; req.type = RT_WAKEUP; req.event = NULL; m_requests.push_back(req); } protected: // Handle a request from some other thread // E.g. new fetch; clear fetches for one caller; wake up void processRequest(const Request &req) { if (req.type == RT_FETCH) { // New fetch, queue until there are less // than m_parallel_limit ongoing fetches m_queued_fetches.push_back(req.fetch_request); // see processQueued() for what happens next } else if (req.type == RT_CLEAR) { unsigned long caller = req.fetch_request.caller; // Abort all ongoing fetches for the caller for (std::vector<HTTPFetchOngoing*>::iterator it = m_all_ongoing.begin(); it != m_all_ongoing.end();) { if ((*it)->getRequest().caller == caller) { delete (*it); it = m_all_ongoing.erase(it); } else { ++it; } } // Also abort all queued fetches for the caller for (std::list<HTTPFetchRequest>::iterator it = m_queued_fetches.begin(); it != m_queued_fetches.end();) { if ((*it).caller == caller) it = m_queued_fetches.erase(it); else ++it; } } else if (req.type == RT_WAKEUP) { // Wakeup: Nothing to do, thread is awake at this point } if (req.event != NULL) req.event->signal(); } // Start new ongoing fetches if m_parallel_limit allows void processQueued(CurlHandlePool *pool) { while (m_all_ongoing.size() < m_parallel_limit && !m_queued_fetches.empty()) { HTTPFetchRequest request = m_queued_fetches.front(); m_queued_fetches.pop_front(); // Create ongoing fetch data and make a cURL handle // Set cURL options based on HTTPFetchRequest HTTPFetchOngoing *ongoing = new HTTPFetchOngoing(request, pool); // Initiate the connection (curl_multi_add_handle) CURLcode res = ongoing->start(m_multi); if (res == CURLE_OK) { m_all_ongoing.push_back(ongoing); } else { httpfetch_deliver_result(*ongoing->complete(res)); delete ongoing; } } } // Process CURLMsg (indicates completion of a fetch) void processCurlMessage(CURLMsg *msg) { // Determine which ongoing fetch the message pertains to size_t i = 0; bool found = false; for (i = 0; i < m_all_ongoing.size(); ++i) { if (m_all_ongoing[i]->getEasyHandle() == msg->easy_handle) { found = true; break; } } if (msg->msg == CURLMSG_DONE && found) { // m_all_ongoing[i] succeeded or failed. HTTPFetchOngoing *ongoing = m_all_ongoing[i]; httpfetch_deliver_result(*ongoing->complete(msg->data.result)); delete ongoing; m_all_ongoing.erase(m_all_ongoing.begin() + i); } } // Wait for a request from another thread, or timeout elapses void waitForRequest(long timeout) { if (m_queued_fetches.empty()) { try { Request req = m_requests.pop_front(timeout); processRequest(req); } catch (ItemNotFoundException &e) {} } } // Wait until some IO happens, or timeout elapses void waitForIO(long timeout) { fd_set read_fd_set; fd_set write_fd_set; fd_set exc_fd_set; int max_fd; long select_timeout = -1; struct timeval select_tv; CURLMcode mres; FD_ZERO(&read_fd_set); FD_ZERO(&write_fd_set); FD_ZERO(&exc_fd_set); mres = curl_multi_fdset(m_multi, &read_fd_set, &write_fd_set, &exc_fd_set, &max_fd); if (mres != CURLM_OK) { errorstream<<"curl_multi_fdset" <<" returned error code "<<mres <<std::endl; select_timeout = 0; } mres = curl_multi_timeout(m_multi, &select_timeout); if (mres != CURLM_OK) { errorstream<<"curl_multi_timeout" <<" returned error code "<<mres <<std::endl; select_timeout = 0; } // Limit timeout so new requests get through if (select_timeout < 0 || select_timeout > timeout) select_timeout = timeout; if (select_timeout > 0) { // in Winsock it is forbidden to pass three empty // fd_sets to select(), so in that case use sleep_ms if (max_fd != -1) { select_tv.tv_sec = select_timeout / 1000; select_tv.tv_usec = (select_timeout % 1000) * 1000; int retval = select(max_fd + 1, &read_fd_set, &write_fd_set, &exc_fd_set, &select_tv); if (retval == -1) { #ifdef _WIN32 errorstream<<"select returned error code " <<WSAGetLastError()<<std::endl; #else errorstream<<"select returned error code " <<errno<<std::endl; #endif } } else { sleep_ms(select_timeout); } } } void * Thread() { ThreadStarted(); log_register_thread("CurlFetchThread"); DSTACK(__FUNCTION_NAME); porting::setThreadName("CurlFetchThread"); CurlHandlePool pool; m_multi = curl_multi_init(); if (m_multi == NULL) { errorstream<<"curl_multi_init returned NULL\n"; return NULL; } assert(m_all_ongoing.empty()); while (!StopRequested()) { BEGIN_DEBUG_EXCEPTION_HANDLER /* Handle new async requests */ while (!m_requests.empty()) { Request req = m_requests.pop_frontNoEx(); processRequest(req); } processQueued(&pool); /* Handle ongoing async requests */ int still_ongoing = 0; while (curl_multi_perform(m_multi, &still_ongoing) == CURLM_CALL_MULTI_PERFORM) /* noop */; /* Handle completed async requests */ if (still_ongoing < (int) m_all_ongoing.size()) { CURLMsg *msg; int msgs_in_queue; msg = curl_multi_info_read(m_multi, &msgs_in_queue); while (msg != NULL) { processCurlMessage(msg); msg = curl_multi_info_read(m_multi, &msgs_in_queue); } } /* If there are ongoing requests, wait for data (with a timeout of 100ms so that new requests can be processed). If no ongoing requests, wait for a new request. (Possibly an empty request that signals that the thread should be stopped.) */ if (m_all_ongoing.empty()) waitForRequest(100000000); else waitForIO(100); END_DEBUG_EXCEPTION_HANDLER(errorstream) } // Call curl_multi_remove_handle and cleanup easy handles for (size_t i = 0; i < m_all_ongoing.size(); ++i) { delete m_all_ongoing[i]; } m_all_ongoing.clear(); m_queued_fetches.clear(); CURLMcode mres = curl_multi_cleanup(m_multi); if (mres != CURLM_OK) { errorstream<<"curl_multi_cleanup" <<" returned error code "<<mres <<std::endl; } return NULL; } }; CurlFetchThread *g_httpfetch_thread = NULL; void httpfetch_init(int parallel_limit) { verbosestream<<"httpfetch_init: parallel_limit="<<parallel_limit <<std::endl;