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14e5b4668734e15ff15daeaf1cd70c73d63aa5fc
SingularityViewer/indra/llmessage/llurlrequest.cpp
Aleric Inglewood 14e5b46687 Fixed and adjusted remainders of isValid() code. 
Note that in the code, and still, has_curl_request was always false.
However, instead of deleting all code paths that are only executed
when has_curl_request would be true, I fixed the code to work as
intended with my current implementation; which also results in
LLCurlRequests to never expire. This way things won't break
unexpectedly when this ever changes.

Since on this branch isValid was only called still (the rest was
removed already) to check if the curl download expired, I took
the liberty to rename isValid to hasNotExpired.
2012-07-15 22:46:38 +02:00

809 lines
21 KiB
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/**
* @file llurlrequest.cpp
* @author Phoenix
* @date 2005-04-28
* @brief Implementation of the URLRequest class and related classes.
*
* $LicenseInfo:firstyear=2005&license=viewerlgpl$
* Second Life Viewer Source Code
* Copyright (C) 2010, Linden Research, Inc.
*
* This library 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;
* version 2.1 of the License only.
*
* This library 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 library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*
* Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA
* $/LicenseInfo$
*/
#include "linden_common.h"
#include "llurlrequest.h"
#ifdef CWDEBUG
#include <libcwd/buf2str.h>
#endif
#include <algorithm>
#include <openssl/x509_vfy.h>
#include <openssl/ssl.h>
#include "llcurl.h"
#include "llfasttimer.h"
#include "llioutil.h"
#include "llmemtype.h"
#include "llproxy.h"
#include "llpumpio.h"
#include "llsd.h"
#include "llstring.h"
#include "apr_env.h"
#include "llapr.h"
#include "llscopedvolatileaprpool.h"
static const U32 HTTP_STATUS_PIPE_ERROR = 499;
/**
* String constants
*/
const std::string CONTEXT_DEST_URI_SD_LABEL("dest_uri");
const std::string CONTEXT_TRANSFERED_BYTES("transfered_bytes");
static size_t headerCallback(char* data, size_t size, size_t nmemb, void* user);
/**
* class LLURLRequestDetail
*/
class LLURLRequestDetail
{
public:
LLURLRequestDetail();
~LLURLRequestDetail();
std::string mURL;
AICurlEasyRequest mCurlEasyRequest;
LLIOPipe::buffer_ptr_t mResponseBuffer;
LLChannelDescriptors mChannels;
U8* mLastRead;
U32 mBodyLimit;
S32 mByteAccumulator;
bool mIsBodyLimitSet;
LLURLRequest::SSLCertVerifyCallback mSSLVerifyCallback;
};
LLURLRequestDetail::LLURLRequestDetail() :
mCurlEasyRequest(false),
mLastRead(NULL),
mBodyLimit(0),
mByteAccumulator(0),
mIsBodyLimitSet(false),
mSSLVerifyCallback(NULL)
{
}
LLURLRequestDetail::~LLURLRequestDetail()
{
mLastRead = NULL;
}
void LLURLRequest::setSSLVerifyCallback(SSLCertVerifyCallback callback, void *param)
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
mDetail->mSSLVerifyCallback = callback;
AICurlEasyRequest_wat curlEasyRequest_w(*mDetail->mCurlEasyRequest);
curlEasyRequest_w->setSSLCtxCallback(LLURLRequest::_sslCtxCallback, (void *)this);
curlEasyRequest_w->setopt(CURLOPT_SSL_VERIFYPEER, true);
curlEasyRequest_w->setopt(CURLOPT_SSL_VERIFYHOST, 2);
}
// _sslCtxFunction
// Callback function called when an SSL Context is created via CURL
// used to configure the context for custom cert validation
CURLcode LLURLRequest::_sslCtxCallback(CURL * curl, void *sslctx, void *param)
{
LLURLRequest *req = (LLURLRequest *)param;
if(req == NULL || req->mDetail->mSSLVerifyCallback == NULL)
{
SSL_CTX_set_cert_verify_callback((SSL_CTX *)sslctx, NULL, NULL);
return CURLE_OK;
}
SSL_CTX * ctx = (SSL_CTX *) sslctx;
// disable any default verification for server certs
SSL_CTX_set_verify(ctx, SSL_VERIFY_NONE, NULL);
// set the verification callback.
SSL_CTX_set_cert_verify_callback(ctx, req->mDetail->mSSLVerifyCallback, (void *)req);
// the calls are void
return CURLE_OK;
}
/**
* class LLURLRequest
*/
// static
std::string LLURLRequest::actionAsVerb(LLURLRequest::ERequestAction action)
{
static const std::string VERBS[] =
{
"(invalid)",
"HEAD",
"GET",
"PUT",
"POST",
"DELETE",
"MOVE"
};
if(((S32)action <=0) || ((S32)action >= REQUEST_ACTION_COUNT))
{
return VERBS[0];
}
return VERBS[action];
}
LLURLRequest::LLURLRequest(LLURLRequest::ERequestAction action) :
mAction(action)
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
// This might throw AICurlNoEasyHandle.
initialize();
}
LLURLRequest::LLURLRequest(
LLURLRequest::ERequestAction action,
const std::string& url) :
mAction(action)
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
// This might throw AICurlNoEasyHandle.
initialize();
setURL(url);
}
LLURLRequest::~LLURLRequest()
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
{
AICurlEasyRequest_wat curl_easy_request_w(*mDetail->mCurlEasyRequest);
curl_easy_request_w->revokeCallbacks();
curl_easy_request_w->send_events_to(NULL);
}
delete mDetail;
}
void LLURLRequest::setURL(const std::string& url)
{
mDetail->mURL = url;
}
std::string LLURLRequest::getURL() const
{
return mDetail->mURL;
}
void LLURLRequest::addHeader(const char* header)
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
AICurlEasyRequest_wat curlEasyRequest_w(*mDetail->mCurlEasyRequest);
curlEasyRequest_w->addHeader(header);
}
void LLURLRequest::setBodyLimit(U32 size)
{
mDetail->mBodyLimit = size;
mDetail->mIsBodyLimitSet = true;
}
void LLURLRequest::setCallback(LLURLRequestComplete* callback)
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
mCompletionCallback = callback;
AICurlEasyRequest_wat curlEasyRequest_w(*mDetail->mCurlEasyRequest);
curlEasyRequest_w->setHeaderCallback(&headerCallback, (void*)callback);
}
// Added to mitigate the effect of libcurl looking
// for the ALL_PROXY and http_proxy env variables
// and deciding to insert a Pragma: no-cache
// header! The only usage of this method at the
// time of this writing is in llhttpclient.cpp
// in the request() method, where this method
// is called with use_proxy = FALSE
void LLURLRequest::useProxy(bool use_proxy)
{
static std::string env_proxy;
if (use_proxy && env_proxy.empty())
{
char* env_proxy_str;
LLScopedVolatileAPRPool scoped_pool;
apr_status_t status = apr_env_get(&env_proxy_str, "ALL_PROXY", scoped_pool);
if (status != APR_SUCCESS)
{
status = apr_env_get(&env_proxy_str, "http_proxy", scoped_pool);
}
if (status != APR_SUCCESS)
{
use_proxy = false;
}
else
{
// env_proxy_str is stored in the scoped_pool, so we have to make a copy.
env_proxy = env_proxy_str;
}
}
lldebugs << "use_proxy = " << (use_proxy?'Y':'N') << ", env_proxy = \"" << env_proxy << "\"" << llendl;
AICurlEasyRequest_wat curlEasyRequest_w(*mDetail->mCurlEasyRequest);
curlEasyRequest_w->setoptString(CURLOPT_PROXY, use_proxy ? env_proxy : std::string(""));
}
void LLURLRequest::useProxy(const std::string &proxy)
{
AICurlEasyRequest_wat curlEasyRequest_w(*mDetail->mCurlEasyRequest);
curlEasyRequest_w->setoptString(CURLOPT_PROXY, proxy);
}
void LLURLRequest::allowCookies()
{
AICurlEasyRequest_wat curlEasyRequest_w(*mDetail->mCurlEasyRequest);
curlEasyRequest_w->setoptString(CURLOPT_COOKIEFILE, "");
}
//virtual
bool LLURLRequest::hasExpiration(void) const
{
// Currently, this ALWAYS returns false -- because only AICurlEasyRequestStateMachine uses buffered
// AICurlEasyRequest objects, and LLURLRequest uses (unbuffered) AICurlEasyRequest directly, which
// have no expiration facility.
return mDetail->mCurlEasyRequest.isBuffered();
}
//virtual
bool LLURLRequest::hasNotExpired(void) const
{
if (!mDetail->mCurlEasyRequest.isBuffered())
return true;
AICurlEasyRequest_wat buffered_easy_request_w(*mDetail->mCurlEasyRequest);
AICurlResponderBuffer_wat buffer_w(*mDetail->mCurlEasyRequest);
return buffer_w->isValid();
}
// virtual
LLIOPipe::EStatus LLURLRequest::handleError(
LLIOPipe::EStatus status,
LLPumpIO* pump)
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
if(!hasNotExpired())
{
return STATUS_EXPIRED ;
}
if(mCompletionCallback && pump)
{
LLURLRequestComplete* complete = NULL;
complete = (LLURLRequestComplete*)mCompletionCallback.get();
complete->httpStatus(
HTTP_STATUS_PIPE_ERROR,
LLIOPipe::lookupStatusString(status));
complete->responseStatus(status);
pump->respond(complete);
mCompletionCallback = NULL;
}
return status;
}
void LLURLRequest::added_to_multi_handle(AICurlEasyRequest_wat&)
{
}
void LLURLRequest::finished(AICurlEasyRequest_wat&)
{
}
void LLURLRequest::removed_from_multi_handle(AICurlEasyRequest_wat&)
{
mRemoved = true;
}
static LLFastTimer::DeclareTimer FTM_PROCESS_URL_REQUEST("URL Request");
// virtual
LLIOPipe::EStatus LLURLRequest::process_impl(
const LLChannelDescriptors& channels,
buffer_ptr_t& buffer,
bool& eos,
LLSD& context,
LLPumpIO* pump)
{
LLFastTimer t(FTM_PROCESS_URL_REQUEST);
PUMP_DEBUG;
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
//llinfos << "LLURLRequest::process_impl()" << llendl;
if (!buffer) return STATUS_ERROR;
// we're still waiting or processing, check how many
// bytes we have accumulated.
const S32 MIN_ACCUMULATION = 100000;
if(pump && (mDetail->mByteAccumulator > MIN_ACCUMULATION))
{
static LLFastTimer::DeclareTimer FTM_URL_ADJUST_TIMEOUT("Adjust Timeout");
LLFastTimer t(FTM_URL_ADJUST_TIMEOUT);
// This is a pretty sloppy calculation, but this
// tries to make the gross assumption that if data
// is coming in at 56kb/s, then this transfer will
// probably succeed. So, if we're accumlated
// 100,000 bytes (MIN_ACCUMULATION) then let's
// give this client another 2s to complete.
const F32 TIMEOUT_ADJUSTMENT = 2.0f;
mDetail->mByteAccumulator = 0;
pump->adjustTimeoutSeconds(TIMEOUT_ADJUSTMENT);
lldebugs << "LLURLRequest adjustTimeoutSeconds for request: " << mDetail->mURL << llendl;
if (mState == STATE_INITIALIZED)
{
llinfos << "LLURLRequest adjustTimeoutSeconds called during upload" << llendl;
}
}
switch(mState)
{
case STATE_INITIALIZED:
{
PUMP_DEBUG;
// We only need to wait for input if we are uploading
// something.
if(((HTTP_PUT == mAction) || (HTTP_POST == mAction)) && !eos)
{
// we're waiting to get all of the information
return STATUS_BREAK;
}
// *FIX: bit of a hack, but it should work. The configure and
// callback method expect this information to be ready.
mDetail->mResponseBuffer = buffer;
mDetail->mChannels = channels;
if(!configure())
{
return STATUS_ERROR;
}
mRemoved = false;
mState = STATE_WAITING_FOR_RESPONSE;
mDetail->mCurlEasyRequest.addRequest(); // Add easy handle to multi handle.
return STATUS_BREAK;
}
case STATE_WAITING_FOR_RESPONSE:
case STATE_PROCESSING_RESPONSE:
{
if (!mRemoved) // Not removed from multi handle yet?
{
// Easy handle is still being processed.
return STATUS_BREAK;
}
// Curl thread finished with this easy handle.
mState = STATE_CURL_FINISHED;
}
case STATE_CURL_FINISHED:
{
PUMP_DEBUG;
LLIOPipe::EStatus status = STATUS_NO_CONNECTION; // Catch-all failure code.
// Left braces in order not to change indentation.
{
CURLcode result;
static LLFastTimer::DeclareTimer FTM_PROCESS_URL_REQUEST_GET_RESULT("Get Result");
AICurlEasyRequest_wat(*mDetail->mCurlEasyRequest)->getResult(&result);
mState = STATE_HAVE_RESPONSE;
context[CONTEXT_REQUEST][CONTEXT_TRANSFERED_BYTES] = mRequestTransferedBytes;
context[CONTEXT_RESPONSE][CONTEXT_TRANSFERED_BYTES] = mResponseTransferedBytes;
lldebugs << this << "Setting context to " << context << llendl;
switch(result)
{
case CURLE_OK:
case CURLE_WRITE_ERROR:
// NB: The error indication means that we stopped the
// writing due the body limit being reached
if(mCompletionCallback && pump)
{
LLURLRequestComplete* complete = NULL;
complete = (LLURLRequestComplete*)
mCompletionCallback.get();
complete->responseStatus(
result == CURLE_OK
? STATUS_OK : STATUS_STOP);
LLPumpIO::links_t chain;
LLPumpIO::LLLinkInfo link;
link.mPipe = mCompletionCallback;
link.mChannels = LLBufferArray::makeChannelConsumer(
channels);
chain.push_back(link);
static LLFastTimer::DeclareTimer FTM_PROCESS_URL_PUMP_RESPOND("Pump Respond");
{
LLFastTimer t(FTM_PROCESS_URL_PUMP_RESPOND);
pump->respond(chain, buffer, context);
}
mCompletionCallback = NULL;
}
status = STATUS_BREAK; // This is what the old code returned. Does it make sense?
break;
case CURLE_FAILED_INIT:
case CURLE_COULDNT_CONNECT:
status = STATUS_NO_CONNECTION;
break;
default:
llwarns << "URLRequest Error: " << result
<< ", "
<< LLCurl::strerror(result)
<< ", "
<< (mDetail->mURL.empty() ? "<EMPTY URL>" : mDetail->mURL)
<< llendl;
status = STATUS_ERROR;
break;
}
}
return status;
}
case STATE_HAVE_RESPONSE:
PUMP_DEBUG;
// we already stuffed everything into channel in in the curl
// callback, so we are done.
eos = true;
context[CONTEXT_REQUEST][CONTEXT_TRANSFERED_BYTES] = mRequestTransferedBytes;
context[CONTEXT_RESPONSE][CONTEXT_TRANSFERED_BYTES] = mResponseTransferedBytes;
lldebugs << this << "Setting context to " << context << llendl;
return STATUS_DONE;
default:
PUMP_DEBUG;
context[CONTEXT_REQUEST][CONTEXT_TRANSFERED_BYTES] = mRequestTransferedBytes;
context[CONTEXT_RESPONSE][CONTEXT_TRANSFERED_BYTES] = mResponseTransferedBytes;
lldebugs << this << "Setting context to " << context << llendl;
return STATUS_ERROR;
}
}
void LLURLRequest::initialize()
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
mState = STATE_INITIALIZED;
// This might throw AICurlNoEasyHandle.
mDetail = new LLURLRequestDetail;
{
AICurlEasyRequest_wat curlEasyRequest_w(*mDetail->mCurlEasyRequest);
curlEasyRequest_w->setWriteCallback(&downCallback, (void*)this);
curlEasyRequest_w->setReadCallback(&upCallback, (void*)this);
}
mRequestTransferedBytes = 0;
mResponseTransferedBytes = 0;
}
static LLFastTimer::DeclareTimer FTM_URL_REQUEST_CONFIGURE("URL Configure");
bool LLURLRequest::configure()
{
LLFastTimer t(FTM_URL_REQUEST_CONFIGURE);
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
bool rv = false;
S32 bytes = mDetail->mResponseBuffer->countAfter(
mDetail->mChannels.in(),
NULL);
{
AICurlEasyRequest_wat curlEasyRequest_w(*mDetail->mCurlEasyRequest);
switch(mAction)
{
case HTTP_HEAD:
curlEasyRequest_w->setopt(CURLOPT_HEADER, 1);
curlEasyRequest_w->setopt(CURLOPT_NOBODY, 1);
curlEasyRequest_w->setopt(CURLOPT_FOLLOWLOCATION, 1);
rv = true;
break;
case HTTP_GET:
curlEasyRequest_w->setopt(CURLOPT_HTTPGET, 1);
curlEasyRequest_w->setopt(CURLOPT_FOLLOWLOCATION, 1);
// Set Accept-Encoding to allow response compression
curlEasyRequest_w->setoptString(CURLOPT_ENCODING, "");
rv = true;
break;
case HTTP_PUT:
// Disable the expect http 1.1 extension. POST and PUT default
// to turning this on, and I am not too sure what it means.
addHeader("Expect:");
curlEasyRequest_w->setopt(CURLOPT_UPLOAD, 1);
curlEasyRequest_w->setopt(CURLOPT_INFILESIZE, bytes);
rv = true;
break;
case HTTP_POST:
// Disable the expect http 1.1 extension. POST and PUT default
// to turning this on, and I am not too sure what it means.
addHeader("Expect:");
// Disable the content type http header.
// *FIX: what should it be?
addHeader("Content-Type:");
// Set the handle for an http post
curlEasyRequest_w->setPost(NULL, bytes);
// Set Accept-Encoding to allow response compression
curlEasyRequest_w->setoptString(CURLOPT_ENCODING, "");
rv = true;
break;
case HTTP_DELETE:
// Set the handle for an http post
curlEasyRequest_w->setoptString(CURLOPT_CUSTOMREQUEST, "DELETE");
rv = true;
break;
case HTTP_MOVE:
// Set the handle for an http post
curlEasyRequest_w->setoptString(CURLOPT_CUSTOMREQUEST, "MOVE");
// *NOTE: should we check for the Destination header?
rv = true;
break;
default:
llwarns << "Unhandled URLRequest action: " << mAction << llendl;
break;
}
if(rv)
{
curlEasyRequest_w->finalizeRequest(mDetail->mURL);
curlEasyRequest_w->send_events_to(this);
}
}
return rv;
}
// static
size_t LLURLRequest::downCallback(
char* data,
size_t size,
size_t nmemb,
void* user)
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
LLURLRequest* req = (LLURLRequest*)user;
if(STATE_WAITING_FOR_RESPONSE == req->mState)
{
req->mState = STATE_PROCESSING_RESPONSE;
}
U32 bytes = size * nmemb;
if (req->mDetail->mIsBodyLimitSet)
{
if (bytes > req->mDetail->mBodyLimit)
{
bytes = req->mDetail->mBodyLimit;
req->mDetail->mBodyLimit = 0;
}
else
{
req->mDetail->mBodyLimit -= bytes;
}
}
req->mDetail->mResponseBuffer->append(
req->mDetail->mChannels.out(),
(U8*)data,
bytes);
req->mResponseTransferedBytes += bytes;
req->mDetail->mByteAccumulator += bytes;
return bytes;
}
// static
size_t LLURLRequest::upCallback(
char* data,
size_t size,
size_t nmemb,
void* user)
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
LLURLRequest* req = (LLURLRequest*)user;
S32 bytes = llmin(
(S32)(size * nmemb),
req->mDetail->mResponseBuffer->countAfter(
req->mDetail->mChannels.in(),
req->mDetail->mLastRead));
req->mDetail->mLastRead = req->mDetail->mResponseBuffer->readAfter(
req->mDetail->mChannels.in(),
req->mDetail->mLastRead,
(U8*)data,
bytes);
req->mRequestTransferedBytes += bytes;
return bytes;
}
static size_t headerCallback(char* header_line, size_t size, size_t nmemb, void* user)
{
size_t header_len = size * nmemb;
LLURLRequestComplete* complete = (LLURLRequestComplete*)user;
if (!complete || !header_line)
{
return header_len;
}
// *TODO: This should be a utility in llstring.h: isascii()
for (size_t i = 0; i < header_len; ++i)
{
if (header_line[i] < 0)
{
return header_len;
}
}
std::string header(header_line, header_len);
// Per HTTP spec the first header line must be the status line.
if (header.substr(0,5) == "HTTP/")
{
std::string::iterator end = header.end();
std::string::iterator pos1 = std::find(header.begin(), end, ' ');
if (pos1 != end) ++pos1;
std::string::iterator pos2 = std::find(pos1, end, ' ');
if (pos2 != end) ++pos2;
std::string::iterator pos3 = std::find(pos2, end, '\r');
std::string version(header.begin(), pos1);
std::string status(pos1, pos2);
std::string reason(pos2, pos3);
S32 status_code = atoi(status.c_str());
if (status_code > 0)
{
complete->httpStatus((U32)status_code, reason);
return header_len;
}
}
std::string::iterator sep = std::find(header.begin(),header.end(),':');
if (sep != header.end())
{
std::string key(header.begin(), sep);
std::string value(sep + 1, header.end());
key = utf8str_tolower(utf8str_trim(key));
value = utf8str_trim(value);
complete->header(key, value);
}
else
{
LLStringUtil::trim(header);
if (!header.empty())
{
llwarns << "Unable to parse header: " << header << llendl;
}
}
return header_len;
}
static LLFastTimer::DeclareTimer FTM_PROCESS_URL_EXTRACTOR("URL Extractor");
/**
* LLContextURLExtractor
*/
// virtual
LLIOPipe::EStatus LLContextURLExtractor::process_impl(
const LLChannelDescriptors& channels,
buffer_ptr_t& buffer,
bool& eos,
LLSD& context,
LLPumpIO* pump)
{
LLFastTimer t(FTM_PROCESS_URL_EXTRACTOR);
PUMP_DEBUG;
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
// The destination host is in the context.
if(context.isUndefined() || !mRequest)
{
return STATUS_PRECONDITION_NOT_MET;
}
// copy in to out, since this just extract the URL and does not
// actually change the data.
LLChangeChannel change(channels.in(), channels.out());
std::for_each(buffer->beginSegment(), buffer->endSegment(), change);
// find the context url
if(context.has(CONTEXT_DEST_URI_SD_LABEL))
{
mRequest->setURL(context[CONTEXT_DEST_URI_SD_LABEL].asString());
return STATUS_DONE;
}
return STATUS_ERROR;
}
/**
* LLURLRequestComplete
*/
LLURLRequestComplete::LLURLRequestComplete() :
mRequestStatus(LLIOPipe::STATUS_ERROR)
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
}
// virtual
LLURLRequestComplete::~LLURLRequestComplete()
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
}
//virtual
void LLURLRequestComplete::header(const std::string& header, const std::string& value)
{
}
//virtual
void LLURLRequestComplete::complete(const LLChannelDescriptors& channels,
const buffer_ptr_t& buffer)
{
if(STATUS_OK == mRequestStatus)
{
response(channels, buffer);
}
else
{
noResponse();
}
}
//virtual
void LLURLRequestComplete::response(const LLChannelDescriptors& channels,
const buffer_ptr_t& buffer)
{
llwarns << "LLURLRequestComplete::response default implementation called"
<< llendl;
}
//virtual
void LLURLRequestComplete::noResponse()
{
llwarns << "LLURLRequestComplete::noResponse default implementation called"
<< llendl;
}
void LLURLRequestComplete::responseStatus(LLIOPipe::EStatus status)
{
LLMemType m1(LLMemType::MTYPE_IO_URL_REQUEST);
mRequestStatus = status;
}
static LLFastTimer::DeclareTimer FTM_PROCESS_URL_COMPLETE("URL Complete");
// virtual
LLIOPipe::EStatus LLURLRequestComplete::process_impl(
const LLChannelDescriptors& channels,
buffer_ptr_t& buffer,
bool& eos,
LLSD& context,
LLPumpIO* pump)
{
LLFastTimer t(FTM_PROCESS_URL_COMPLETE);
PUMP_DEBUG;
complete(channels, buffer);
return STATUS_OK;
}
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