minetest/src/client/clientmedia.cpp
2021-09-09 16:51:35 +02:00

793 lines
22 KiB
C++

/*
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 "clientmedia.h"
#include "httpfetch.h"
#include "client.h"
#include "filecache.h"
#include "filesys.h"
#include "log.h"
#include "porting.h"
#include "settings.h"
#include "util/hex.h"
#include "util/serialize.h"
#include "util/sha1.h"
#include "util/string.h"
static std::string getMediaCacheDir()
{
return porting::path_cache + DIR_DELIM + "media";
}
bool clientMediaUpdateCache(const std::string &raw_hash, const std::string &filedata)
{
FileCache media_cache(getMediaCacheDir());
std::string sha1_hex = hex_encode(raw_hash);
if (!media_cache.exists(sha1_hex))
return media_cache.update(sha1_hex, filedata);
return true;
}
/*
ClientMediaDownloader
*/
ClientMediaDownloader::ClientMediaDownloader():
m_httpfetch_caller(HTTPFETCH_DISCARD)
{
}
ClientMediaDownloader::~ClientMediaDownloader()
{
if (m_httpfetch_caller != HTTPFETCH_DISCARD)
httpfetch_caller_free(m_httpfetch_caller);
for (auto &file_it : m_files)
delete file_it.second;
for (auto &remote : m_remotes)
delete remote;
}
bool ClientMediaDownloader::loadMedia(Client *client, const std::string &data,
const std::string &name)
{
return client->loadMedia(data, name);
}
void ClientMediaDownloader::addFile(const std::string &name, const std::string &sha1)
{
assert(!m_initial_step_done); // pre-condition
// if name was already announced, ignore the new announcement
if (m_files.count(name) != 0) {
errorstream << "Client: ignoring duplicate media announcement "
<< "sent by server: \"" << name << "\""
<< std::endl;
return;
}
// if name is empty or contains illegal characters, ignore the file
if (name.empty() || !string_allowed(name, TEXTURENAME_ALLOWED_CHARS)) {
errorstream << "Client: ignoring illegal file name "
<< "sent by server: \"" << name << "\""
<< std::endl;
return;
}
// length of sha1 must be exactly 20 (160 bits), else ignore the file
if (sha1.size() != 20) {
errorstream << "Client: ignoring illegal SHA1 sent by server: "
<< hex_encode(sha1) << " \"" << name << "\""
<< std::endl;
return;
}
FileStatus *filestatus = new FileStatus();
filestatus->received = false;
filestatus->sha1 = sha1;
filestatus->current_remote = -1;
m_files.insert(std::make_pair(name, filestatus));
}
void ClientMediaDownloader::addRemoteServer(const std::string &baseurl)
{
assert(!m_initial_step_done); // pre-condition
#ifdef USE_CURL
if (g_settings->getBool("enable_remote_media_server")) {
infostream << "Client: Adding remote server \""
<< baseurl << "\" for media download" << std::endl;
RemoteServerStatus *remote = new RemoteServerStatus();
remote->baseurl = baseurl;
remote->active_count = 0;
m_remotes.push_back(remote);
}
#else
infostream << "Client: Ignoring remote server \""
<< baseurl << "\" because cURL support is not compiled in"
<< std::endl;
#endif
}
void ClientMediaDownloader::step(Client *client)
{
if (!m_initial_step_done) {
initialStep(client);
m_initial_step_done = true;
}
// Remote media: check for completion of fetches
if (m_httpfetch_active) {
bool fetched_something = false;
HTTPFetchResult fetch_result;
while (httpfetch_async_get(m_httpfetch_caller, fetch_result)) {
m_httpfetch_active--;
fetched_something = true;
// Is this a hashset (index.mth) or a media file?
if (fetch_result.request_id < m_remotes.size())
remoteHashSetReceived(fetch_result);
else
remoteMediaReceived(fetch_result, client);
}
if (fetched_something)
startRemoteMediaTransfers();
// Did all remote transfers end and no new ones can be started?
// If so, request still missing files from the minetest server
// (Or report that we have all files.)
if (m_httpfetch_active == 0) {
if (m_uncached_received_count < m_uncached_count) {
infostream << "Client: Failed to remote-fetch "
<< (m_uncached_count-m_uncached_received_count)
<< " files. Requesting them"
<< " the usual way." << std::endl;
}
startConventionalTransfers(client);
}
}
}
void ClientMediaDownloader::initialStep(Client *client)
{
// Check media cache
m_uncached_count = m_files.size();
for (auto &file_it : m_files) {
const std::string &name = file_it.first;
FileStatus *filestatus = file_it.second;
const std::string &sha1 = filestatus->sha1;
if (tryLoadFromCache(name, sha1, client)) {
filestatus->received = true;
m_uncached_count--;
}
}
assert(m_uncached_received_count == 0);
// Create the media cache dir if we are likely to write to it
if (m_uncached_count != 0)
createCacheDirs();
// If we found all files in the cache, report this fact to the server.
// If the server reported no remote servers, immediately start
// conventional transfers. Note: if cURL support is not compiled in,
// m_remotes is always empty, so "!USE_CURL" is redundant but may
// reduce the size of the compiled code
if (!USE_CURL || m_uncached_count == 0 || m_remotes.empty()) {
startConventionalTransfers(client);
}
else {
// Otherwise start off by requesting each server's sha1 set
// This is the first time we use httpfetch, so alloc a caller ID
m_httpfetch_caller = httpfetch_caller_alloc();
// Set the active fetch limit to curl_parallel_limit or 84,
// whichever is greater. This gives us some leeway so that
// inefficiencies in communicating with the httpfetch thread
// don't slow down fetches too much. (We still want some limit
// so that when the first remote server returns its hash set,
// not all files are requested from that server immediately.)
// One such inefficiency is that ClientMediaDownloader::step()
// is only called a couple times per second, while httpfetch
// might return responses much faster than that.
// Note that httpfetch strictly enforces curl_parallel_limit
// but at no inter-thread communication cost. This however
// doesn't help with the aforementioned inefficiencies.
// The signifance of 84 is that it is 2*6*9 in base 13.
m_httpfetch_active_limit = g_settings->getS32("curl_parallel_limit");
m_httpfetch_active_limit = MYMAX(m_httpfetch_active_limit, 84);
// Write a list of hashes that we need. This will be POSTed
// to the server using Content-Type: application/octet-stream
std::string required_hash_set = serializeRequiredHashSet();
// minor fixme: this loop ignores m_httpfetch_active_limit
// another minor fixme, unlikely to matter in normal usage:
// these index.mth fetches do (however) count against
// m_httpfetch_active_limit when starting actual media file
// requests, so if there are lots of remote servers that are
// not responding, those will stall new media file transfers.
for (u32 i = 0; i < m_remotes.size(); ++i) {
assert(m_httpfetch_next_id == i);
RemoteServerStatus *remote = m_remotes[i];
actionstream << "Client: Contacting remote server \""
<< remote->baseurl << "\"" << std::endl;
HTTPFetchRequest fetch_request;
fetch_request.url =
remote->baseurl + MTHASHSET_FILE_NAME;
fetch_request.caller = m_httpfetch_caller;
fetch_request.request_id = m_httpfetch_next_id; // == i
fetch_request.method = HTTP_POST;
fetch_request.raw_data = required_hash_set;
fetch_request.extra_headers.emplace_back(
"Content-Type: application/octet-stream");
// Encapsulate possible IPv6 plain address in []
std::string addr = client->getAddressName();
if (addr.find(':', 0) != std::string::npos)
addr = '[' + addr + ']';
fetch_request.extra_headers.emplace_back(
std::string("Referer: minetest://") +
addr + ":" +
std::to_string(client->getServerAddress().getPort()));
httpfetch_async(fetch_request);
m_httpfetch_active++;
m_httpfetch_next_id++;
m_outstanding_hash_sets++;
}
}
}
void ClientMediaDownloader::remoteHashSetReceived(
const HTTPFetchResult &fetch_result)
{
u32 remote_id = fetch_result.request_id;
assert(remote_id < m_remotes.size());
RemoteServerStatus *remote = m_remotes[remote_id];
m_outstanding_hash_sets--;
if (fetch_result.succeeded) {
try {
// Server sent a list of file hashes that are
// available on it, try to parse the list
std::set<std::string> sha1_set;
deSerializeHashSet(fetch_result.data, sha1_set);
// Parsing succeeded: For every file that is
// available on this server, add this server
// to the available_remotes array
for(auto it = m_files.upper_bound(m_name_bound);
it != m_files.end(); ++it) {
FileStatus *f = it->second;
if (!f->received && sha1_set.count(f->sha1))
f->available_remotes.push_back(remote_id);
}
}
catch (SerializationError &e) {
infostream << "Client: Remote server \""
<< remote->baseurl << "\" sent invalid hash set: "
<< e.what() << std::endl;
}
}
}
void ClientMediaDownloader::remoteMediaReceived(
const HTTPFetchResult &fetch_result,
Client *client)
{
// Some remote server sent us a file.
// -> decrement number of active fetches
// -> mark file as received if fetch succeeded
// -> try to load media
std::string name;
{
auto it = m_remote_file_transfers.find(fetch_result.request_id);
assert(it != m_remote_file_transfers.end());
name = it->second;
m_remote_file_transfers.erase(it);
}
sanity_check(m_files.count(name) != 0);
FileStatus *filestatus = m_files[name];
sanity_check(!filestatus->received);
sanity_check(filestatus->current_remote >= 0);
RemoteServerStatus *remote = m_remotes[filestatus->current_remote];
filestatus->current_remote = -1;
remote->active_count--;
// If fetch succeeded, try to load media file
if (fetch_result.succeeded) {
bool success = checkAndLoad(name, filestatus->sha1,
fetch_result.data, false, client);
if (success) {
filestatus->received = true;
assert(m_uncached_received_count < m_uncached_count);
m_uncached_received_count++;
}
}
}
s32 ClientMediaDownloader::selectRemoteServer(FileStatus *filestatus)
{
// Pre-conditions
assert(filestatus != NULL);
assert(!filestatus->received);
assert(filestatus->current_remote < 0);
if (filestatus->available_remotes.empty())
return -1;
// Of all servers that claim to provide the file (and haven't
// been unsuccessfully tried before), find the one with the
// smallest number of currently active transfers
s32 best = 0;
s32 best_remote_id = filestatus->available_remotes[best];
s32 best_active_count = m_remotes[best_remote_id]->active_count;
for (u32 i = 1; i < filestatus->available_remotes.size(); ++i) {
s32 remote_id = filestatus->available_remotes[i];
s32 active_count = m_remotes[remote_id]->active_count;
if (active_count < best_active_count) {
best = i;
best_remote_id = remote_id;
best_active_count = active_count;
}
}
filestatus->available_remotes.erase(
filestatus->available_remotes.begin() + best);
return best_remote_id;
}
void ClientMediaDownloader::startRemoteMediaTransfers()
{
bool changing_name_bound = true;
for (auto files_iter = m_files.upper_bound(m_name_bound);
files_iter != m_files.end(); ++files_iter) {
// Abort if active fetch limit is exceeded
if (m_httpfetch_active >= m_httpfetch_active_limit)
break;
const std::string &name = files_iter->first;
FileStatus *filestatus = files_iter->second;
if (!filestatus->received && filestatus->current_remote < 0) {
// File has not been received yet and is not currently
// being transferred. Choose a server for it.
s32 remote_id = selectRemoteServer(filestatus);
if (remote_id >= 0) {
// Found a server, so start fetching
RemoteServerStatus *remote =
m_remotes[remote_id];
std::string url = remote->baseurl +
hex_encode(filestatus->sha1);
verbosestream << "Client: "
<< "Requesting remote media file "
<< "\"" << name << "\" "
<< "\"" << url << "\"" << std::endl;
HTTPFetchRequest fetch_request;
fetch_request.url = url;
fetch_request.caller = m_httpfetch_caller;
fetch_request.request_id = m_httpfetch_next_id;
fetch_request.timeout =
g_settings->getS32("curl_file_download_timeout");
httpfetch_async(fetch_request);
m_remote_file_transfers.insert(std::make_pair(
m_httpfetch_next_id,
name));
filestatus->current_remote = remote_id;
remote->active_count++;
m_httpfetch_active++;
m_httpfetch_next_id++;
}
}
if (filestatus->received ||
(filestatus->current_remote < 0 &&
!m_outstanding_hash_sets)) {
// If we arrive here, we conclusively know that we
// won't fetch this file from a remote server in the
// future. So update the name bound if possible.
if (changing_name_bound)
m_name_bound = name;
}
else
changing_name_bound = false;
}
}
void ClientMediaDownloader::startConventionalTransfers(Client *client)
{
assert(m_httpfetch_active == 0); // pre-condition
if (m_uncached_received_count != m_uncached_count) {
// Some media files have not been received yet, use the
// conventional slow method (minetest protocol) to get them
std::vector<std::string> file_requests;
for (auto &file : m_files) {
if (!file.second->received)
file_requests.push_back(file.first);
}
assert((s32) file_requests.size() ==
m_uncached_count - m_uncached_received_count);
client->request_media(file_requests);
}
}
bool ClientMediaDownloader::conventionalTransferDone(
const std::string &name,
const std::string &data,
Client *client)
{
// Check that file was announced
auto file_iter = m_files.find(name);
if (file_iter == m_files.end()) {
errorstream << "Client: server sent media file that was"
<< "not announced, ignoring it: \"" << name << "\""
<< std::endl;
return false;
}
FileStatus *filestatus = file_iter->second;
assert(filestatus != NULL);
// Check that file hasn't already been received
if (filestatus->received) {
errorstream << "Client: server sent media file that we already"
<< "received, ignoring it: \"" << name << "\""
<< std::endl;
return true;
}
// Mark file as received, regardless of whether loading it works and
// whether the checksum matches (because at this point there is no
// other server that could send a replacement)
filestatus->received = true;
assert(m_uncached_received_count < m_uncached_count);
m_uncached_received_count++;
// Check that received file matches announced checksum
// If so, load it
checkAndLoad(name, filestatus->sha1, data, false, client);
return true;
}
/*
IClientMediaDownloader
*/
IClientMediaDownloader::IClientMediaDownloader():
m_media_cache(getMediaCacheDir()), m_write_to_cache(true)
{
}
void IClientMediaDownloader::createCacheDirs()
{
if (!m_write_to_cache)
return;
std::string path = getMediaCacheDir();
if (!fs::CreateAllDirs(path)) {
errorstream << "Client: Could not create media cache directory: "
<< path << std::endl;
}
}
bool IClientMediaDownloader::tryLoadFromCache(const std::string &name,
const std::string &sha1, Client *client)
{
std::ostringstream tmp_os(std::ios_base::binary);
bool found_in_cache = m_media_cache.load(hex_encode(sha1), tmp_os);
// If found in cache, try to load it from there
if (found_in_cache)
return checkAndLoad(name, sha1, tmp_os.str(), true, client);
return false;
}
bool IClientMediaDownloader::checkAndLoad(
const std::string &name, const std::string &sha1,
const std::string &data, bool is_from_cache, Client *client)
{
const char *cached_or_received = is_from_cache ? "cached" : "received";
const char *cached_or_received_uc = is_from_cache ? "Cached" : "Received";
std::string sha1_hex = hex_encode(sha1);
// Compute actual checksum of data
std::string data_sha1;
{
SHA1 data_sha1_calculator;
data_sha1_calculator.addBytes(data.c_str(), data.size());
unsigned char *data_tmpdigest = data_sha1_calculator.getDigest();
data_sha1.assign((char*) data_tmpdigest, 20);
free(data_tmpdigest);
}
// Check that received file matches announced checksum
if (data_sha1 != sha1) {
std::string data_sha1_hex = hex_encode(data_sha1);
infostream << "Client: "
<< cached_or_received_uc << " media file "
<< sha1_hex << " \"" << name << "\" "
<< "mismatches actual checksum " << data_sha1_hex
<< std::endl;
return false;
}
// Checksum is ok, try loading the file
bool success = loadMedia(client, data, name);
if (!success) {
infostream << "Client: "
<< "Failed to load " << cached_or_received << " media: "
<< sha1_hex << " \"" << name << "\""
<< std::endl;
return false;
}
verbosestream << "Client: "
<< "Loaded " << cached_or_received << " media: "
<< sha1_hex << " \"" << name << "\""
<< std::endl;
// Update cache (unless we just loaded the file from the cache)
if (!is_from_cache && m_write_to_cache)
m_media_cache.update(sha1_hex, data);
return true;
}
/*
Minetest Hashset File Format
All values are stored in big-endian byte order.
[u32] signature: 'MTHS'
[u16] version: 1
For each hash in set:
[u8*20] SHA1 hash
Version changes:
1 - Initial version
*/
std::string ClientMediaDownloader::serializeRequiredHashSet()
{
std::ostringstream os(std::ios::binary);
writeU32(os, MTHASHSET_FILE_SIGNATURE); // signature
writeU16(os, 1); // version
// Write list of hashes of files that have not been
// received (found in cache) yet
for (const auto &it : m_files) {
if (!it.second->received) {
FATAL_ERROR_IF(it.second->sha1.size() != 20, "Invalid SHA1 size");
os << it.second->sha1;
}
}
return os.str();
}
void ClientMediaDownloader::deSerializeHashSet(const std::string &data,
std::set<std::string> &result)
{
if (data.size() < 6 || data.size() % 20 != 6) {
throw SerializationError(
"ClientMediaDownloader::deSerializeHashSet: "
"invalid hash set file size");
}
const u8 *data_cstr = (const u8*) data.c_str();
u32 signature = readU32(&data_cstr[0]);
if (signature != MTHASHSET_FILE_SIGNATURE) {
throw SerializationError(
"ClientMediaDownloader::deSerializeHashSet: "
"invalid hash set file signature");
}
u16 version = readU16(&data_cstr[4]);
if (version != 1) {
throw SerializationError(
"ClientMediaDownloader::deSerializeHashSet: "
"unsupported hash set file version");
}
for (u32 pos = 6; pos < data.size(); pos += 20) {
result.insert(data.substr(pos, 20));
}
}
/*
SingleMediaDownloader
*/
SingleMediaDownloader::SingleMediaDownloader(bool write_to_cache):
m_httpfetch_caller(HTTPFETCH_DISCARD)
{
m_write_to_cache = write_to_cache;
}
SingleMediaDownloader::~SingleMediaDownloader()
{
if (m_httpfetch_caller != HTTPFETCH_DISCARD)
httpfetch_caller_free(m_httpfetch_caller);
}
bool SingleMediaDownloader::loadMedia(Client *client, const std::string &data,
const std::string &name)
{
return client->loadMedia(data, name, true);
}
void SingleMediaDownloader::addFile(const std::string &name, const std::string &sha1)
{
assert(m_stage == STAGE_INIT); // pre-condition
assert(!name.empty());
assert(sha1.size() == 20);
FATAL_ERROR_IF(!m_file_name.empty(), "Cannot add a second file");
m_file_name = name;
m_file_sha1 = sha1;
}
void SingleMediaDownloader::addRemoteServer(const std::string &baseurl)
{
assert(m_stage == STAGE_INIT); // pre-condition
if (g_settings->getBool("enable_remote_media_server"))
m_remotes.emplace_back(baseurl);
}
void SingleMediaDownloader::step(Client *client)
{
if (m_stage == STAGE_INIT) {
m_stage = STAGE_CACHE_CHECKED;
initialStep(client);
}
// Remote media: check for completion of fetches
if (m_httpfetch_caller != HTTPFETCH_DISCARD) {
HTTPFetchResult fetch_result;
while (httpfetch_async_get(m_httpfetch_caller, fetch_result)) {
remoteMediaReceived(fetch_result, client);
}
}
}
bool SingleMediaDownloader::conventionalTransferDone(const std::string &name,
const std::string &data, Client *client)
{
if (name != m_file_name)
return false;
// Mark file as received unconditionally and try to load it
m_stage = STAGE_DONE;
checkAndLoad(name, m_file_sha1, data, false, client);
return true;
}
void SingleMediaDownloader::initialStep(Client *client)
{
if (tryLoadFromCache(m_file_name, m_file_sha1, client))
m_stage = STAGE_DONE;
if (isDone())
return;
createCacheDirs();
// If the server reported no remote servers, immediately fall back to
// conventional transfer.
if (!USE_CURL || m_remotes.empty()) {
startConventionalTransfer(client);
} else {
// Otherwise start by requesting the file from the first remote media server
m_httpfetch_caller = httpfetch_caller_alloc();
m_current_remote = 0;
startRemoteMediaTransfer();
}
}
void SingleMediaDownloader::remoteMediaReceived(
const HTTPFetchResult &fetch_result, Client *client)
{
sanity_check(!isDone());
sanity_check(m_current_remote >= 0);
// If fetch succeeded, try to load it
if (fetch_result.succeeded) {
bool success = checkAndLoad(m_file_name, m_file_sha1,
fetch_result.data, false, client);
if (success) {
m_stage = STAGE_DONE;
return;
}
}
// Otherwise try the next remote server or fall back to conventional transfer
m_current_remote++;
if (m_current_remote >= (int)m_remotes.size()) {
infostream << "Client: Failed to remote-fetch \"" << m_file_name
<< "\". Requesting it the usual way." << std::endl;
m_current_remote = -1;
startConventionalTransfer(client);
} else {
startRemoteMediaTransfer();
}
}
void SingleMediaDownloader::startRemoteMediaTransfer()
{
std::string url = m_remotes.at(m_current_remote) + hex_encode(m_file_sha1);
verbosestream << "Client: Requesting remote media file "
<< "\"" << m_file_name << "\" " << "\"" << url << "\"" << std::endl;
HTTPFetchRequest fetch_request;
fetch_request.url = url;
fetch_request.caller = m_httpfetch_caller;
fetch_request.request_id = m_httpfetch_next_id;
fetch_request.timeout = g_settings->getS32("curl_file_download_timeout");
httpfetch_async(fetch_request);
m_httpfetch_next_id++;
}
void SingleMediaDownloader::startConventionalTransfer(Client *client)
{
std::vector<std::string> requests;
requests.emplace_back(m_file_name);
client->request_media(requests);
}