string& SourceRootInfo::initPhpRoot() {
GlobalVariables *g = get_global_variables();
CVarRef server = g->get(s_SERVER);
CVarRef v = server.rvalAt(s_PHP_ROOT);
if (v.isString()) {
*s_phproot.getCheck() = string(v.asCStrRef().data()) + string("/");
} else {
// Our best guess at the source root.
*s_phproot.getCheck() = GetCurrentSourceRoot();
}
return *s_phproot.getCheck();
}
bool UrlFile::open(CStrRef url, CStrRef mode) {
const char* modestr = mode.c_str();
if (strchr(modestr, '+') || strchr(modestr, 'a') || strchr(modestr, 'w')) {
std::string msg = "cannot open a url stream for write/append operation: ";
msg += url.c_str();
m_error = msg;
return false;
}
HttpClient http(m_timeout, m_maxRedirect);
m_response.reset();
HeaderMap *pHeaders = nullptr;
HeaderMap requestHeaders;
if (!m_headers.empty()) {
pHeaders = &requestHeaders;
for (ArrayIter iter(m_headers); iter; ++iter) {
requestHeaders[string(iter.first().toString().data())].
push_back(iter.second().toString().data());
}
}
int code;
vector<String> responseHeaders;
if (m_get) {
code = http.get(url.c_str(), m_response, pHeaders, &responseHeaders);
} else {
code = http.post(url.c_str(), m_postData.data(), m_postData.size(),
m_response, pHeaders, &responseHeaders);
}
GlobalVariables *g = get_global_variables();
Variant &r = g->getRef(s_http_response_header);
r = Array::Create();
for (unsigned int i = 0; i < responseHeaders.size(); i++) {
r.append(responseHeaders[i]);
}
m_responseHeaders = r;
if (code == 200) {
m_name = (std::string) url;
m_data = const_cast<char*>(m_response.data());
m_len = m_response.size();
return true;
} else {
m_error = http.getLastError().c_str();
return false;
}
}
Array f_getopt(CStrRef options, CVarRef longopts /* = null_variant */) {
opt_struct *opts, *orig_opts;
int len = parse_opts(options.data(), options.size(), &opts);
if (!longopts.isNull()) {
Array arropts = longopts.toArray();
int count = arropts.size();
/* the first <len> slots are filled by the one short ops
* we now extend our array and jump to the new added structs */
opts = (opt_struct *)realloc(opts, sizeof(opt_struct) * (len + count + 1));
orig_opts = opts;
opts += len;
memset(opts, 0, count * sizeof(opt_struct));
for (ArrayIter iter(arropts); iter; ++iter) {
String entry = iter.second().toString();
opts->need_param = 0;
opts->opt_name = strdup(entry.data());
len = strlen(opts->opt_name);
if ((len > 0) && (opts->opt_name[len - 1] == ':')) {
opts->need_param++;
opts->opt_name[len - 1] = '\0';
if ((len > 1) && (opts->opt_name[len - 2] == ':')) {
opts->need_param++;
opts->opt_name[len - 2] = '\0';
}
}
opts->opt_char = 0;
opts++;
}
} else {
opts = (opt_struct*) realloc(opts, sizeof(opt_struct) * (len + 1));
orig_opts = opts;
opts += len;
}
/* php_getopt want to identify the last param */
opts->opt_char = '-';
opts->need_param = 0;
opts->opt_name = NULL;
static const StaticString s_argv("argv");
GlobalVariables *g = get_global_variables();
Array vargv = g->get(s_argv).toArray();
int argc = vargv.size();
char **argv = (char **)malloc((argc+1) * sizeof(char*));
vector<String> holders;
int index = 0;
for (ArrayIter iter(vargv); iter; ++iter) {
String arg = iter.second().toString();
holders.push_back(arg);
argv[index++] = (char*)arg.data();
}
argv[index] = NULL;
Array ret = Array::Create();
/* after our pointer arithmetic jump back to the first element */
opts = orig_opts;
int o;
char *php_optarg = NULL;
int php_optind = 1;
Variant val;
int optchr = 0;
int dash = 0; /* have already seen the - */
char opt[2] = { '\0' };
char *optname;
int optname_len = 0;
int php_optidx;
while ((o = php_getopt(argc, argv, opts, &php_optarg, &php_optind, 0, 1,
optchr, dash, php_optidx))
!= -1) {
/* Skip unknown arguments. */
if (o == '?') {
continue;
}
/* Prepare the option character and the argument string. */
if (o == 0) {
optname = opts[php_optidx].opt_name;
} else {
if (o == 1) {
o = '-';
}
opt[0] = o;
optname = opt;
}
if (php_optarg != NULL) {
/* keep the arg as binary, since the encoding is not known */
val = String(php_optarg, CopyString);
} else {
val = false;
}
/* Add this option / argument pair to the result hash. */
optname_len = strlen(optname);
if (!(optname_len > 1 && optname[0] == '0') &&
is_numeric_string(optname, optname_len, NULL, NULL, 0) ==
KindOfInt64) {
/* numeric string */
int optname_int = atoi(optname);
if (ret.exists(optname_int)) {
Variant &e = ret.lvalAt(optname_int);
if (!e.isArray()) {
ret.set(optname_int, CREATE_VECTOR2(e, val));
} else {
e.append(val);
}
} else {
ret.set(optname_int, val);
}
} else {
/* other strings */
String key(optname, strlen(optname), CopyString);
if (ret.exists(key)) {
Variant &e = ret.lvalAt(key);
if (!e.isArray()) {
ret.set(key, CREATE_VECTOR2(e, val));
} else {
e.append(val);
}
} else {
ret.set(key, val);
}
}
php_optarg = NULL;
}
free_longopts(orig_opts);
free(orig_opts);
free(argv);
return ret;
}
void DummySandbox::run() {
TRACE(2, "DummySandbox::run\n");
ThreadInfo *ti = ThreadInfo::s_threadInfo.getNoCheck();
Debugger::RegisterThread();
while (!m_stopped) {
try {
CLISession hphpSession;
DSandboxInfo sandbox = m_proxy->getSandbox();
string msg;
if (sandbox.valid()) {
GlobalVariables *g = get_global_variables();
SourceRootInfo sri(sandbox.m_user, sandbox.m_name);
if (sandbox.m_path.empty()) {
sandbox.m_path = sri.path();
}
if (!sri.sandboxOn()) {
msg = "Invalid sandbox was specified. "
"PHP files may not be loaded properly.\n";
} else {
sri.setServerVariables(g->getRef(s__SERVER));
}
Debugger::RegisterSandbox(sandbox);
g_context->setSandboxId(sandbox.id());
std::string doc = getStartupDoc(sandbox);
if (!doc.empty()) {
char cwd[PATH_MAX];
getcwd(cwd, sizeof(cwd));
Logger::Info("Start loading startup doc '%s', pwd = '%s'",
doc.c_str(), cwd);
bool error; string errorMsg;
bool ret = hphp_invoke(g_context.getNoCheck(), doc, false, null_array,
uninit_null(), "", "", error, errorMsg, true,
false, true);
if (!ret || error) {
msg += "Unable to pre-load " + doc;
if (!errorMsg.empty()) {
msg += ": " + errorMsg;
}
}
Logger::Info("Startup doc " + doc + " loaded");
}
} else {
g_context->setSandboxId(m_proxy->getDummyInfo().id());
}
ti->m_reqInjectionData.setDebugger(true);
{
DebuggerDummyEnv dde;
// This is really the entire point of having the dummy sandbox. This
// fires the initial session started interrupt to the client after
// it first attaches.
Debugger::InterruptSessionStarted(nullptr, msg.c_str());
}
// Blocking until Ctrl-C is issued by end user and DebuggerProxy cannot
// find a real sandbox thread to handle it.
{
Lock lock(this);
while (!m_stopped && m_signum != CmdSignal::SignalBreak) {
wait(1);
}
if (m_stopped) {
// stopped by worker thread
break;
}
m_signum = CmdSignal::SignalNone;
}
} catch (const DebuggerClientExitException &e) {
// stopped by the dummy sandbox thread itself
break;
} catch (const DebuggerException &e) {
}
}
}
bool RPCRequestHandler::executePHPFunction(Transport *transport,
SourceRootInfo &sourceRootInfo,
ReturnEncodeType returnEncodeType) {
string rpcFunc = transport->getCommand();
{
ServerStatsHelper ssh("input");
RequestURI reqURI(rpcFunc);
HttpProtocol::PrepareSystemVariables(transport, reqURI, sourceRootInfo);
GlobalVariables *g = get_global_variables();
g->getRef(s__ENV).set(s_HPHP_RPC, 1);
}
bool isFile = rpcFunc.rfind('.') != string::npos;
string rpcFile;
bool error = false;
Array params;
string sparams = transport->getParam("params");
if (!sparams.empty()) {
Variant jparams = f_json_decode(String(sparams), true);
if (jparams.isArray()) {
params = jparams.toArray();
} else {
error = true;
}
} else {
vector<string> sparams;
transport->getArrayParam("p", sparams);
if (!sparams.empty()) {
for (unsigned int i = 0; i < sparams.size(); i++) {
Variant jparams = f_json_decode(String(sparams[i]), true);
if (same(jparams, false)) {
error = true;
break;
}
params.append(jparams);
}
} else {
// single string parameter, used by xbox to avoid any en/decoding
int size;
const void *data = transport->getPostData(size);
if (data && size) {
params.append(String((char*)data, size, CopyString));
}
}
}
if (transport->getIntParam("reset") == 1) {
m_reset = true;
}
int output = transport->getIntParam("output");
int code;
if (!error) {
Variant funcRet;
string errorMsg = "Internal Server Error";
string reqInitFunc, reqInitDoc;
reqInitDoc = transport->getHeader("ReqInitDoc");
if (reqInitDoc.empty() && m_serverInfo) {
reqInitFunc = m_serverInfo->getReqInitFunc();
reqInitDoc = m_serverInfo->getReqInitDoc();
}
if (!reqInitDoc.empty()) {
reqInitDoc = (std::string)canonicalize_path(reqInitDoc, "", 0);
}
if (!reqInitDoc.empty()) {
reqInitDoc = getSourceFilename(reqInitDoc, sourceRootInfo);
}
bool runOnce = false;
bool ret = true;
if (isFile) {
rpcFile = rpcFunc;
rpcFunc.clear();
} else {
rpcFile = transport->getParam("include");
if (rpcFile.empty()) {
rpcFile = transport->getParam("include_once");
runOnce = true;
}
}
if (!rpcFile.empty()) {
// invoking a file through rpc
bool forbidden = false;
if (!RuntimeOption::ForbiddenFileExtensions.empty()) {
const char *ext = rpcFile.c_str() + rpcFile.rfind('.') + 1;
if (RuntimeOption::ForbiddenFileExtensions.find(ext) !=
RuntimeOption::ForbiddenFileExtensions.end()) {
forbidden = true;
}
}
if (!forbidden) {
rpcFile = (std::string) canonicalize_path(rpcFile, "", 0);
rpcFile = getSourceFilename(rpcFile, sourceRootInfo);
ret = hphp_invoke(m_context, rpcFile, false, Array(), uninit_null(),
reqInitFunc, reqInitDoc, error, errorMsg, runOnce);
}
// no need to do the initialization for a second time
reqInitFunc.clear();
reqInitDoc.clear();
}
if (ret && !rpcFunc.empty()) {
ret = hphp_invoke(m_context, rpcFunc, true, params, ref(funcRet),
reqInitFunc, reqInitDoc, error, errorMsg);
}
if (ret) {
bool serializeFailed = false;
String response;
switch (output) {
case 0: {
assert(returnEncodeType == ReturnEncodeType::Json ||
returnEncodeType == ReturnEncodeType::Serialize);
try {
response = (returnEncodeType == ReturnEncodeType::Json) ?
f_json_encode(funcRet) :
f_serialize(funcRet);
} catch (...) {
serializeFailed = true;
}
break;
}
case 1: response = m_context->obDetachContents(); break;
case 2:
response =
f_json_encode(
make_map_array(s_output, m_context->obDetachContents(),
s_return, f_json_encode(funcRet)));
break;
case 3: response = f_serialize(funcRet); break;
}
if (serializeFailed) {
code = 500;
transport->sendString(
"Serialization of the return value failed", 500);
m_reset = true;
} else {
transport->sendRaw((void*)response.data(), response.size());
code = transport->getResponseCode();
}
} else if (error) {
code = 500;
transport->sendString(errorMsg, 500);
m_reset = true;
} else {
code = 404;
transport->sendString("Not Found", 404);
}
} else {
code = 400;
transport->sendString("Bad Request", 400);
}
params.reset();
sourceRootInfo.clear();
transport->onSendEnd();
ServerStats::LogPage(isFile ? rpcFile : rpcFunc, code);
m_context->onShutdownPostSend();
m_context->obClean(); // in case postsend/cleanup output something
m_context->restoreSession();
return !error;
}
bool UrlFile::open(const String& input_url, const String& mode) {
String url = input_url;
const char* modestr = mode.c_str();
if (strchr(modestr, '+') || strchr(modestr, 'a') || strchr(modestr, 'w')) {
std::string msg = "cannot open a url stream for write/append operation: ";
msg += url.c_str();
m_error = msg;
return false;
}
HttpClient http(m_timeout, m_maxRedirect);
m_response.clear();
HeaderMap *pHeaders = nullptr;
HeaderMap requestHeaders;
if (!m_headers.empty()) {
pHeaders = &requestHeaders;
for (ArrayIter iter(m_headers); iter; ++iter) {
requestHeaders[std::string(iter.first().toString().data())].
push_back(iter.second().toString().data());
}
}
Variant user = f_parse_url(url, k_PHP_URL_USER);
if (user.isString()) {
Variant pass = f_parse_url(url, k_PHP_URL_PASS);
http.auth(user.toString().c_str(), pass.toString().c_str());
url = HHVM_FN(preg_replace)(
s_remove_user_pass_pattern,
s_remove_user_pass_replace,
url,
1
);
}
int code;
std::vector<String> responseHeaders;
if (m_get) {
code = http.get(url.c_str(), m_response, pHeaders, &responseHeaders);
} else {
code = http.post(url.c_str(), m_postData.data(), m_postData.size(),
m_response, pHeaders, &responseHeaders);
}
GlobalVariables *g = get_global_variables();
Variant &r = g->getRef(s_http_response_header);
r = Array::Create();
for (unsigned int i = 0; i < responseHeaders.size(); i++) {
r.append(responseHeaders[i]);
}
m_responseHeaders = r;
if (code == 200) {
m_name = (std::string) url;
m_data = const_cast<char*>(m_response.data());
m_len = m_response.size();
return true;
} else {
m_error = http.getLastError().c_str();
return false;
}
}
void init_global_variables() {
GlobalVariables *g = get_global_variables();
ThreadInfo::s_threadInfo->m_globals = g;
g->initialize();
}
Variant &GlobalVariables::getImpl(CStrRef s) {
GlobalVariables *g __attribute__((__unused__)) = this;
int64 hash = s->hash();
switch (hash & 31) {
case 1:
HASH_RETURN_NAMSTR(0x50645ABB5EE07801LL, s_ss5ee07801, g->GV(_POST),
5);
break;
case 3:
HASH_RETURN_NAMSTR(0x3760929554A51DA3LL, s_ss54a51da3, g->GV(_COOKIE),
7);
HASH_RETURN_NAMSTR(0x6649184C41356B03LL, s_ss41356b03, g->GV(HTTP_RAW_POST_DATA),
18);
break;
case 9:
HASH_RETURN_NAMSTR(0x0759FB4517508949LL, s_ss17508949, g->GV(_GET),
4);
HASH_RETURN_NAMSTR(0x230E7AD147721D89LL, s_ss47721d89, g->GV(end),
3);
break;
case 10:
HASH_RETURN_NAMSTR(0x15F2515C40B2980ALL, s_ss40b2980a, g->GV(elapsed_time),
12);
break;
case 14:
HASH_RETURN_NAMSTR(0x14297F74B68B58EELL, s_ss4974a712, g->GV(_SERVER),
7);
HASH_RETURN_NAMSTR(0x516FBD36FC674A0ELL, s_ss0398b5f2, g->GV(_FILES),
6);
break;
case 15:
HASH_RETURN_NAMSTR(0x587FF01B02607E8FLL, s_ss02607e8f, g->GV(argv),
4);
break;
case 16:
HASH_RETURN_NAMSTR(0x7320B4E3FF243290LL, s_ss00dbcd70, g->GV(_ENV),
4);
break;
case 17:
HASH_RETURN_NAMSTR(0x29DFC3A6DC027BD1LL, s_ss23fd842f, g->GV(_SESSION),
8);
break;
case 25:
HASH_RETURN_NAMSTR(0x532E5E517D32FCB9LL, s_ss7d32fcb9, g->GV(argc),
4);
break;
case 29:
HASH_RETURN_NAMSTR(0x35F78B4D0532F99DLL, s_ss0532f99d, g->GV(begin),
5);
break;
case 31:
HASH_RETURN_NAMSTR(0x1F878FB806A18D3FLL, s_ss06a18d3f, g->GV(_REQUEST),
8);
HASH_RETURN_NAMSTR(0x6359C77BCA89599FLL, s_ss3576a661, g->GV(http_response_header),
20);
break;
default:
break;
}
return LVariableTable::getImpl(s);
}
