gecko/netwerk/base/nsProtocolProxyService.cpp

2083 lines
66 KiB
C++

/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/* vim:set ts=4 sw=4 sts=4 et: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "mozilla/ArrayUtils.h"
#include "mozilla/Attributes.h"
#include "nsProtocolProxyService.h"
#include "nsProxyInfo.h"
#include "nsIClassInfoImpl.h"
#include "nsIIOService.h"
#include "nsIObserverService.h"
#include "nsIProtocolHandler.h"
#include "nsIProtocolProxyCallback.h"
#include "nsIChannel.h"
#include "nsICancelable.h"
#include "nsIDNSService.h"
#include "nsPIDNSService.h"
#include "nsIScriptSecurityManager.h"
#include "nsIPrefService.h"
#include "nsIPrefBranch.h"
#include "nsThreadUtils.h"
#include "nsString.h"
#include "nsNetUtil.h"
#include "nsNetCID.h"
#include "plstr.h"
#include "prnetdb.h"
#include "nsPACMan.h"
#include "nsProxyRelease.h"
#include "mozilla/Mutex.h"
#include "mozilla/CondVar.h"
#include "nsISystemProxySettings.h"
#include "nsINetworkLinkService.h"
#include "nsIHttpChannelInternal.h"
//----------------------------------------------------------------------------
namespace mozilla {
extern const char kProxyType_HTTP[];
extern const char kProxyType_HTTPS[];
extern const char kProxyType_SOCKS[];
extern const char kProxyType_SOCKS4[];
extern const char kProxyType_SOCKS5[];
extern const char kProxyType_DIRECT[];
} // namespace mozilla
using namespace mozilla;
#include "mozilla/Logging.h"
#undef LOG
#define LOG(args) MOZ_LOG(net::gProxyLog, mozilla::LogLevel::Debug, args)
//----------------------------------------------------------------------------
#define PROXY_PREF_BRANCH "network.proxy"
#define PROXY_PREF(x) PROXY_PREF_BRANCH "." x
#define WPAD_URL "http://wpad/wpad.dat"
//----------------------------------------------------------------------------
// This structure is intended to be allocated on the stack
struct nsProtocolInfo {
nsAutoCString scheme;
uint32_t flags;
int32_t defaultPort;
};
//----------------------------------------------------------------------------
// Return the channel's proxy URI, or if it doesn't exist, the
// channel's main URI.
static nsresult
GetProxyURI(nsIChannel *channel, nsIURI **aOut)
{
nsresult rv;
nsCOMPtr<nsIURI> proxyURI;
nsCOMPtr<nsIHttpChannelInternal> httpChannel(do_QueryInterface(channel));
if (httpChannel) {
rv = httpChannel->GetProxyURI(getter_AddRefs(proxyURI));
}
if (!proxyURI) {
rv = channel->GetURI(getter_AddRefs(proxyURI));
}
if (NS_FAILED(rv)) {
return rv;
}
proxyURI.forget(aOut);
return NS_OK;
}
//-----------------------------------------------------------------------------
// The nsPACManCallback portion of this implementation should be run
// on the main thread - so call nsPACMan::AsyncGetProxyForURI() with
// a true mainThreadResponse parameter.
class nsAsyncResolveRequest final : public nsIRunnable
, public nsPACManCallback
, public nsICancelable
{
public:
NS_DECL_THREADSAFE_ISUPPORTS
nsAsyncResolveRequest(nsProtocolProxyService *pps, nsIChannel *channel,
uint32_t aAppId, bool aIsInBrowser,
uint32_t aResolveFlags,
nsIProtocolProxyCallback *callback)
: mStatus(NS_OK)
, mDispatched(false)
, mResolveFlags(aResolveFlags)
, mPPS(pps)
, mXPComPPS(pps)
, mChannel(channel)
, mAppId(aAppId)
, mIsInBrowser(aIsInBrowser)
, mCallback(callback)
{
NS_ASSERTION(mCallback, "null callback");
}
private:
~nsAsyncResolveRequest()
{
if (!NS_IsMainThread()) {
// these xpcom pointers might need to be proxied back to the
// main thread to delete safely, but if this request had its
// callbacks called normally they will all be null and this is a nop
if (mChannel) {
NS_ReleaseOnMainThread(mChannel.forget());
}
if (mCallback) {
NS_ReleaseOnMainThread(mCallback.forget());
}
if (mProxyInfo) {
NS_ReleaseOnMainThread(mProxyInfo.forget());
}
if (mXPComPPS) {
NS_ReleaseOnMainThread(mXPComPPS.forget());
}
}
}
public:
void SetResult(nsresult status, nsIProxyInfo *pi)
{
mStatus = status;
mProxyInfo = pi;
}
NS_IMETHOD Run() override
{
if (mCallback)
DoCallback();
return NS_OK;
}
NS_IMETHOD Cancel(nsresult reason) override
{
NS_ENSURE_ARG(NS_FAILED(reason));
// If we've already called DoCallback then, nothing more to do.
if (!mCallback)
return NS_OK;
SetResult(reason, nullptr);
return DispatchCallback();
}
nsresult DispatchCallback()
{
if (mDispatched) // Only need to dispatch once
return NS_OK;
nsresult rv = NS_DispatchToCurrentThread(this);
if (NS_FAILED(rv))
NS_WARNING("unable to dispatch callback event");
else {
mDispatched = true;
return NS_OK;
}
mCallback = nullptr; // break possible reference cycle
return rv;
}
private:
// Called asynchronously, so we do not need to post another PLEvent
// before calling DoCallback.
void OnQueryComplete(nsresult status,
const nsCString &pacString,
const nsCString &newPACURL) override
{
// If we've already called DoCallback then, nothing more to do.
if (!mCallback)
return;
// Provided we haven't been canceled...
if (mStatus == NS_OK) {
mStatus = status;
mPACString = pacString;
mPACURL = newPACURL;
}
// In the cancelation case, we may still have another PLEvent in
// the queue that wants to call DoCallback. No need to wait for
// it, just run the callback now.
DoCallback();
}
void DoCallback()
{
if (mStatus == NS_ERROR_NOT_AVAILABLE && !mProxyInfo) {
// If the PAC service is not avail (e.g. failed pac load
// or shutdown) then we will be going direct. Make that
// mapping now so that any filters are still applied.
mPACString = NS_LITERAL_CSTRING("DIRECT;");
mStatus = NS_OK;
}
// Generate proxy info from the PAC string if appropriate
if (NS_SUCCEEDED(mStatus) && !mProxyInfo && !mPACString.IsEmpty()) {
mPPS->ProcessPACString(mPACString, mResolveFlags,
getter_AddRefs(mProxyInfo));
nsCOMPtr<nsIURI> proxyURI;
GetProxyURI(mChannel, getter_AddRefs(proxyURI));
// Now apply proxy filters
nsProtocolInfo info;
mStatus = mPPS->GetProtocolInfo(proxyURI, &info);
if (NS_SUCCEEDED(mStatus))
mPPS->ApplyFilters(mChannel, info, mProxyInfo);
else
mProxyInfo = nullptr;
LOG(("pac thread callback %s\n", mPACString.get()));
if (NS_SUCCEEDED(mStatus))
mPPS->MaybeDisableDNSPrefetch(mProxyInfo);
mCallback->OnProxyAvailable(this, mChannel, mProxyInfo, mStatus);
}
else if (NS_SUCCEEDED(mStatus) && !mPACURL.IsEmpty()) {
LOG(("pac thread callback indicates new pac file load\n"));
nsCOMPtr<nsIURI> proxyURI;
GetProxyURI(mChannel, getter_AddRefs(proxyURI));
// trigger load of new pac url
nsresult rv = mPPS->ConfigureFromPAC(mPACURL, false);
if (NS_SUCCEEDED(rv)) {
// now that the load is triggered, we can resubmit the query
RefPtr<nsAsyncResolveRequest> newRequest =
new nsAsyncResolveRequest(mPPS, mChannel, mAppId,
mIsInBrowser, mResolveFlags,
mCallback);
rv = mPPS->mPACMan->AsyncGetProxyForURI(proxyURI, mAppId,
mIsInBrowser,
newRequest,
true);
}
if (NS_FAILED(rv))
mCallback->OnProxyAvailable(this, mChannel, nullptr, rv);
// do not call onproxyavailable() in SUCCESS case - the newRequest will
// take care of that
}
else {
LOG(("pac thread callback did not provide information %X\n", mStatus));
if (NS_SUCCEEDED(mStatus))
mPPS->MaybeDisableDNSPrefetch(mProxyInfo);
mCallback->OnProxyAvailable(this, mChannel, mProxyInfo, mStatus);
}
// We are on the main thread now and don't need these any more so
// release them to avoid having to proxy them back to the main thread
// in the dtor
mCallback = nullptr; // in case the callback holds an owning ref to us
mPPS = nullptr;
mXPComPPS = nullptr;
mChannel = nullptr;
mProxyInfo = nullptr;
}
private:
nsresult mStatus;
nsCString mPACString;
nsCString mPACURL;
bool mDispatched;
uint32_t mResolveFlags;
nsProtocolProxyService *mPPS;
nsCOMPtr<nsIProtocolProxyService> mXPComPPS;
nsCOMPtr<nsIChannel> mChannel;
uint32_t mAppId;
bool mIsInBrowser;
nsCOMPtr<nsIProtocolProxyCallback> mCallback;
nsCOMPtr<nsIProxyInfo> mProxyInfo;
};
NS_IMPL_ISUPPORTS(nsAsyncResolveRequest, nsICancelable, nsIRunnable)
//----------------------------------------------------------------------------
#define IS_ASCII_SPACE(_c) ((_c) == ' ' || (_c) == '\t')
//
// apply mask to address (zeros out excluded bits).
//
// NOTE: we do the byte swapping here to minimize overall swapping.
//
static void
proxy_MaskIPv6Addr(PRIPv6Addr &addr, uint16_t mask_len)
{
if (mask_len == 128)
return;
if (mask_len > 96) {
addr.pr_s6_addr32[3] = PR_htonl(
PR_ntohl(addr.pr_s6_addr32[3]) & (~0L << (128 - mask_len)));
}
else if (mask_len > 64) {
addr.pr_s6_addr32[3] = 0;
addr.pr_s6_addr32[2] = PR_htonl(
PR_ntohl(addr.pr_s6_addr32[2]) & (~0L << (96 - mask_len)));
}
else if (mask_len > 32) {
addr.pr_s6_addr32[3] = 0;
addr.pr_s6_addr32[2] = 0;
addr.pr_s6_addr32[1] = PR_htonl(
PR_ntohl(addr.pr_s6_addr32[1]) & (~0L << (64 - mask_len)));
}
else {
addr.pr_s6_addr32[3] = 0;
addr.pr_s6_addr32[2] = 0;
addr.pr_s6_addr32[1] = 0;
addr.pr_s6_addr32[0] = PR_htonl(
PR_ntohl(addr.pr_s6_addr32[0]) & (~0L << (32 - mask_len)));
}
}
static void
proxy_GetStringPref(nsIPrefBranch *aPrefBranch,
const char *aPref,
nsCString &aResult)
{
nsXPIDLCString temp;
nsresult rv = aPrefBranch->GetCharPref(aPref, getter_Copies(temp));
if (NS_FAILED(rv))
aResult.Truncate();
else {
aResult.Assign(temp);
// all of our string prefs are hostnames, so we should remove any
// whitespace characters that the user might have unknowingly entered.
aResult.StripWhitespace();
}
}
static void
proxy_GetIntPref(nsIPrefBranch *aPrefBranch,
const char *aPref,
int32_t &aResult)
{
int32_t temp;
nsresult rv = aPrefBranch->GetIntPref(aPref, &temp);
if (NS_FAILED(rv))
aResult = -1;
else
aResult = temp;
}
static void
proxy_GetBoolPref(nsIPrefBranch *aPrefBranch,
const char *aPref,
bool &aResult)
{
bool temp;
nsresult rv = aPrefBranch->GetBoolPref(aPref, &temp);
if (NS_FAILED(rv))
aResult = false;
else
aResult = temp;
}
//----------------------------------------------------------------------------
static const int32_t PROXYCONFIG_DIRECT4X = 3;
static const int32_t PROXYCONFIG_COUNT = 6;
NS_IMPL_ADDREF(nsProtocolProxyService)
NS_IMPL_RELEASE(nsProtocolProxyService)
NS_IMPL_CLASSINFO(nsProtocolProxyService, nullptr, nsIClassInfo::SINGLETON,
NS_PROTOCOLPROXYSERVICE_CID)
// NS_IMPL_QUERY_INTERFACE_CI with the nsProtocolProxyService QI change
NS_INTERFACE_MAP_BEGIN(nsProtocolProxyService)
NS_INTERFACE_MAP_ENTRY(nsIProtocolProxyService)
NS_INTERFACE_MAP_ENTRY(nsIProtocolProxyService2)
NS_INTERFACE_MAP_ENTRY(nsIObserver)
if ( aIID.Equals(NS_GET_IID(nsProtocolProxyService)) ) foundInterface = static_cast<nsIProtocolProxyService2*>(this); else
NS_INTERFACE_MAP_ENTRY_AMBIGUOUS(nsISupports, nsIProtocolProxyService)
NS_IMPL_QUERY_CLASSINFO(nsProtocolProxyService)
NS_INTERFACE_MAP_END
NS_IMPL_CI_INTERFACE_GETTER(nsProtocolProxyService,
nsIProtocolProxyService,
nsIProtocolProxyService2)
nsProtocolProxyService::nsProtocolProxyService()
: mFilterLocalHosts(false)
, mFilters(nullptr)
, mProxyConfig(PROXYCONFIG_DIRECT)
, mHTTPProxyPort(-1)
, mFTPProxyPort(-1)
, mHTTPSProxyPort(-1)
, mSOCKSProxyPort(-1)
, mSOCKSProxyVersion(4)
, mSOCKSProxyRemoteDNS(false)
, mProxyOverTLS(true)
, mPACMan(nullptr)
, mSessionStart(PR_Now())
, mFailedProxyTimeout(30 * 60) // 30 minute default
{
}
nsProtocolProxyService::~nsProtocolProxyService()
{
// These should have been cleaned up in our Observe method.
NS_ASSERTION(mHostFiltersArray.Length() == 0 && mFilters == nullptr &&
mPACMan == nullptr, "what happened to xpcom-shutdown?");
}
// nsProtocolProxyService methods
nsresult
nsProtocolProxyService::Init()
{
// failure to access prefs is non-fatal
nsCOMPtr<nsIPrefBranch> prefBranch =
do_GetService(NS_PREFSERVICE_CONTRACTID);
if (prefBranch) {
// monitor proxy prefs
prefBranch->AddObserver(PROXY_PREF_BRANCH, this, false);
// read all prefs
PrefsChanged(prefBranch, nullptr);
}
nsCOMPtr<nsIObserverService> obs = mozilla::services::GetObserverService();
if (obs) {
// register for shutdown notification so we can clean ourselves up
// properly.
obs->AddObserver(this, NS_XPCOM_SHUTDOWN_OBSERVER_ID, false);
obs->AddObserver(this, NS_NETWORK_LINK_TOPIC, false);
}
return NS_OK;
}
// ReloadNetworkPAC() checks if there's a non-networked PAC in use then avoids
// to call ReloadPAC()
nsresult
nsProtocolProxyService::ReloadNetworkPAC()
{
nsCOMPtr<nsIPrefBranch> prefs =
do_GetService(NS_PREFSERVICE_CONTRACTID);
if (!prefs) {
return NS_OK;
}
int32_t type;
nsresult rv = prefs->GetIntPref(PROXY_PREF("type"), &type);
if (NS_FAILED(rv)) {
return NS_OK;
}
if (type == PROXYCONFIG_PAC) {
nsXPIDLCString pacSpec;
prefs->GetCharPref(PROXY_PREF("autoconfig_url"),
getter_Copies(pacSpec));
if (!pacSpec.IsEmpty()) {
nsCOMPtr<nsIURI> pacURI;
rv = NS_NewURI(getter_AddRefs(pacURI), pacSpec);
if(!NS_SUCCEEDED(rv)) {
return rv;
}
nsProtocolInfo pac;
rv = GetProtocolInfo(pacURI, &pac);
if(!NS_SUCCEEDED(rv)) {
return rv;
}
if (!pac.scheme.EqualsLiteral("file") &&
!pac.scheme.EqualsLiteral("data")) {
LOG((": received network changed event, reload PAC"));
ReloadPAC();
}
}
} else if ((type == PROXYCONFIG_WPAD) || (type == PROXYCONFIG_SYSTEM)) {
ReloadPAC();
}
return NS_OK;
}
NS_IMETHODIMP
nsProtocolProxyService::Observe(nsISupports *aSubject,
const char *aTopic,
const char16_t *aData)
{
if (strcmp(aTopic, NS_XPCOM_SHUTDOWN_OBSERVER_ID) == 0) {
// cleanup
if (mHostFiltersArray.Length() > 0) {
mHostFiltersArray.Clear();
}
if (mFilters) {
delete mFilters;
mFilters = nullptr;
}
if (mPACMan) {
mPACMan->Shutdown();
mPACMan = nullptr;
}
nsCOMPtr<nsIObserverService> obs = mozilla::services::GetObserverService();
if (obs) {
obs->RemoveObserver(this, NS_NETWORK_LINK_TOPIC);
obs->RemoveObserver(this, NS_XPCOM_SHUTDOWN_OBSERVER_ID);
}
} else if (strcmp(aTopic, NS_NETWORK_LINK_TOPIC) == 0) {
nsCString converted = NS_ConvertUTF16toUTF8(aData);
const char *state = converted.get();
if (!strcmp(state, NS_NETWORK_LINK_DATA_CHANGED)) {
ReloadNetworkPAC();
}
}
else {
NS_ASSERTION(strcmp(aTopic, NS_PREFBRANCH_PREFCHANGE_TOPIC_ID) == 0,
"what is this random observer event?");
nsCOMPtr<nsIPrefBranch> prefs = do_QueryInterface(aSubject);
if (prefs)
PrefsChanged(prefs, NS_LossyConvertUTF16toASCII(aData).get());
}
return NS_OK;
}
void
nsProtocolProxyService::PrefsChanged(nsIPrefBranch *prefBranch,
const char *pref)
{
nsresult rv = NS_OK;
bool reloadPAC = false;
nsXPIDLCString tempString;
if (!pref || !strcmp(pref, PROXY_PREF("type"))) {
int32_t type = -1;
rv = prefBranch->GetIntPref(PROXY_PREF("type"), &type);
if (NS_SUCCEEDED(rv)) {
// bug 115720 - for ns4.x backwards compatibility
if (type == PROXYCONFIG_DIRECT4X) {
type = PROXYCONFIG_DIRECT;
// Reset the type so that the dialog looks correct, and we
// don't have to handle this case everywhere else
// I'm paranoid about a loop of some sort - only do this
// if we're enumerating all prefs, and ignore any error
if (!pref)
prefBranch->SetIntPref(PROXY_PREF("type"), type);
} else if (type >= PROXYCONFIG_COUNT) {
LOG(("unknown proxy type: %lu; assuming direct\n", type));
type = PROXYCONFIG_DIRECT;
}
mProxyConfig = type;
reloadPAC = true;
}
if (mProxyConfig == PROXYCONFIG_SYSTEM) {
mSystemProxySettings = do_GetService(NS_SYSTEMPROXYSETTINGS_CONTRACTID);
if (!mSystemProxySettings)
mProxyConfig = PROXYCONFIG_DIRECT;
ResetPACThread();
} else {
if (mSystemProxySettings) {
mSystemProxySettings = nullptr;
ResetPACThread();
}
}
}
if (!pref || !strcmp(pref, PROXY_PREF("http")))
proxy_GetStringPref(prefBranch, PROXY_PREF("http"), mHTTPProxyHost);
if (!pref || !strcmp(pref, PROXY_PREF("http_port")))
proxy_GetIntPref(prefBranch, PROXY_PREF("http_port"), mHTTPProxyPort);
if (!pref || !strcmp(pref, PROXY_PREF("ssl")))
proxy_GetStringPref(prefBranch, PROXY_PREF("ssl"), mHTTPSProxyHost);
if (!pref || !strcmp(pref, PROXY_PREF("ssl_port")))
proxy_GetIntPref(prefBranch, PROXY_PREF("ssl_port"), mHTTPSProxyPort);
if (!pref || !strcmp(pref, PROXY_PREF("ftp")))
proxy_GetStringPref(prefBranch, PROXY_PREF("ftp"), mFTPProxyHost);
if (!pref || !strcmp(pref, PROXY_PREF("ftp_port")))
proxy_GetIntPref(prefBranch, PROXY_PREF("ftp_port"), mFTPProxyPort);
if (!pref || !strcmp(pref, PROXY_PREF("socks")))
proxy_GetStringPref(prefBranch, PROXY_PREF("socks"), mSOCKSProxyHost);
if (!pref || !strcmp(pref, PROXY_PREF("socks_port")))
proxy_GetIntPref(prefBranch, PROXY_PREF("socks_port"), mSOCKSProxyPort);
if (!pref || !strcmp(pref, PROXY_PREF("socks_version"))) {
int32_t version;
proxy_GetIntPref(prefBranch, PROXY_PREF("socks_version"), version);
// make sure this preference value remains sane
if (version == 5)
mSOCKSProxyVersion = 5;
else
mSOCKSProxyVersion = 4;
}
if (!pref || !strcmp(pref, PROXY_PREF("socks_remote_dns")))
proxy_GetBoolPref(prefBranch, PROXY_PREF("socks_remote_dns"),
mSOCKSProxyRemoteDNS);
if (!pref || !strcmp(pref, PROXY_PREF("proxy_over_tls"))) {
proxy_GetBoolPref(prefBranch, PROXY_PREF("proxy_over_tls"),
mProxyOverTLS);
}
if (!pref || !strcmp(pref, PROXY_PREF("failover_timeout")))
proxy_GetIntPref(prefBranch, PROXY_PREF("failover_timeout"),
mFailedProxyTimeout);
if (!pref || !strcmp(pref, PROXY_PREF("no_proxies_on"))) {
rv = prefBranch->GetCharPref(PROXY_PREF("no_proxies_on"),
getter_Copies(tempString));
if (NS_SUCCEEDED(rv))
LoadHostFilters(tempString.get());
}
// We're done if not using something that could give us a PAC URL
// (PAC, WPAD or System)
if (mProxyConfig != PROXYCONFIG_PAC && mProxyConfig != PROXYCONFIG_WPAD &&
mProxyConfig != PROXYCONFIG_SYSTEM)
return;
// OK, we need to reload the PAC file if:
// 1) network.proxy.type changed, or
// 2) network.proxy.autoconfig_url changed and PAC is configured
if (!pref || !strcmp(pref, PROXY_PREF("autoconfig_url")))
reloadPAC = true;
if (reloadPAC) {
tempString.Truncate();
if (mProxyConfig == PROXYCONFIG_PAC) {
prefBranch->GetCharPref(PROXY_PREF("autoconfig_url"),
getter_Copies(tempString));
if (mPACMan && !mPACMan->IsPACURI(tempString)) {
LOG(("PAC Thread URI Changed - Reset Pac Thread"));
ResetPACThread();
}
} else if (mProxyConfig == PROXYCONFIG_WPAD) {
// We diverge from the WPAD spec here in that we don't walk the
// hosts's FQDN, stripping components until we hit a TLD. Doing so
// is dangerous in the face of an incomplete list of TLDs, and TLDs
// get added over time. We could consider doing only a single
// substitution of the first component, if that proves to help
// compatibility.
tempString.AssignLiteral(WPAD_URL);
} else if (mSystemProxySettings) {
// Get System Proxy settings if available
mSystemProxySettings->GetPACURI(tempString);
}
if (!tempString.IsEmpty())
ConfigureFromPAC(tempString, false);
}
}
bool
nsProtocolProxyService::CanUseProxy(nsIURI *aURI, int32_t defaultPort)
{
if (mHostFiltersArray.Length() == 0)
return true;
int32_t port;
nsAutoCString host;
nsresult rv = aURI->GetAsciiHost(host);
if (NS_FAILED(rv) || host.IsEmpty())
return false;
rv = aURI->GetPort(&port);
if (NS_FAILED(rv))
return false;
if (port == -1)
port = defaultPort;
PRNetAddr addr;
bool is_ipaddr = (PR_StringToNetAddr(host.get(), &addr) == PR_SUCCESS);
PRIPv6Addr ipv6;
if (is_ipaddr) {
// convert parsed address to IPv6
if (addr.raw.family == PR_AF_INET) {
// convert to IPv4-mapped address
PR_ConvertIPv4AddrToIPv6(addr.inet.ip, &ipv6);
}
else if (addr.raw.family == PR_AF_INET6) {
// copy the address
memcpy(&ipv6, &addr.ipv6.ip, sizeof(PRIPv6Addr));
}
else {
NS_WARNING("unknown address family");
return true; // allow proxying
}
}
// Don't use proxy for local hosts (plain hostname, no dots)
if (!is_ipaddr && mFilterLocalHosts && !host.Contains('.')) {
LOG(("Not using proxy for this local host [%s]!\n", host.get()));
return false; // don't allow proxying
}
int32_t index = -1;
while (++index < int32_t(mHostFiltersArray.Length())) {
HostInfo *hinfo = mHostFiltersArray[index];
if (is_ipaddr != hinfo->is_ipaddr)
continue;
if (hinfo->port && hinfo->port != port)
continue;
if (is_ipaddr) {
// generate masked version of target IPv6 address
PRIPv6Addr masked;
memcpy(&masked, &ipv6, sizeof(PRIPv6Addr));
proxy_MaskIPv6Addr(masked, hinfo->ip.mask_len);
// check for a match
if (memcmp(&masked, &hinfo->ip.addr, sizeof(PRIPv6Addr)) == 0)
return false; // proxy disallowed
}
else {
uint32_t host_len = host.Length();
uint32_t filter_host_len = hinfo->name.host_len;
if (host_len >= filter_host_len) {
//
// compare last |filter_host_len| bytes of target hostname.
//
const char *host_tail = host.get() + host_len - filter_host_len;
if (!PL_strncasecmp(host_tail, hinfo->name.host, filter_host_len)) {
// If the tail of the host string matches the filter
if (filter_host_len > 0 && hinfo->name.host[0] == '.') {
// If the filter was of the form .foo.bar.tld, all such
// matches are correct
return false; // proxy disallowed
}
// abc-def.example.org should not match def.example.org
// however, *.def.example.org should match .def.example.org
// We check that the filter doesn't start with a `.`. If it does,
// then the strncasecmp above should suffice. If it doesn't,
// then we should only consider it a match if the strncasecmp happened
// at a subdomain boundary
if (host_len > filter_host_len && *(host_tail - 1) == '.') {
// If the host was something.foo.bar.tld and the filter
// was foo.bar.tld, it's still a match.
// the character right before the tail must be a
// `.` for this to work
return false; // proxy disallowed
}
if (host_len == filter_host_len) {
// If the host and filter are of the same length,
// they should match
return false; // proxy disallowed
}
}
}
}
}
return true;
}
// kProxyType\* may be referred to externally in
// nsProxyInfo in order to compare by string pointer
namespace mozilla {
const char kProxyType_HTTP[] = "http";
const char kProxyType_HTTPS[] = "https";
const char kProxyType_PROXY[] = "proxy";
const char kProxyType_SOCKS[] = "socks";
const char kProxyType_SOCKS4[] = "socks4";
const char kProxyType_SOCKS5[] = "socks5";
const char kProxyType_DIRECT[] = "direct";
} // namespace mozilla
const char *
nsProtocolProxyService::ExtractProxyInfo(const char *start,
uint32_t aResolveFlags,
nsProxyInfo **result)
{
*result = nullptr;
uint32_t flags = 0;
// see BNF in ProxyAutoConfig.h and notes in nsISystemProxySettings.idl
// find end of proxy info delimiter
const char *end = start;
while (*end && *end != ';') ++end;
// find end of proxy type delimiter
const char *sp = start;
while (sp < end && *sp != ' ' && *sp != '\t') ++sp;
uint32_t len = sp - start;
const char *type = nullptr;
switch (len) {
case 4:
if (PL_strncasecmp(start, kProxyType_HTTP, 5) == 0) {
type = kProxyType_HTTP;
}
break;
case 5:
if (PL_strncasecmp(start, kProxyType_PROXY, 5) == 0) {
type = kProxyType_HTTP;
} else if (PL_strncasecmp(start, kProxyType_SOCKS, 5) == 0) {
type = kProxyType_SOCKS4; // assume v4 for 4x compat
} else if (PL_strncasecmp(start, kProxyType_HTTPS, 5) == 0) {
type = kProxyType_HTTPS;
}
break;
case 6:
if (PL_strncasecmp(start, kProxyType_DIRECT, 6) == 0)
type = kProxyType_DIRECT;
else if (PL_strncasecmp(start, kProxyType_SOCKS4, 6) == 0)
type = kProxyType_SOCKS4;
else if (PL_strncasecmp(start, kProxyType_SOCKS5, 6) == 0)
// map "SOCKS5" to "socks" to match contract-id of registered
// SOCKS-v5 socket provider.
type = kProxyType_SOCKS;
break;
}
if (type) {
const char *host = nullptr, *hostEnd = nullptr;
int32_t port = -1;
// If it's a SOCKS5 proxy, do name resolution on the server side.
// We could use this with SOCKS4a servers too, but they might not
// support it.
if (type == kProxyType_SOCKS || mSOCKSProxyRemoteDNS)
flags |= nsIProxyInfo::TRANSPARENT_PROXY_RESOLVES_HOST;
// extract host:port
start = sp;
while ((*start == ' ' || *start == '\t') && start < end)
start++;
// port defaults
if (type == kProxyType_HTTP) {
port = 80;
} else if (type == kProxyType_HTTPS) {
port = 443;
} else {
port = 1080;
}
nsProxyInfo *pi = new nsProxyInfo();
pi->mType = type;
pi->mFlags = flags;
pi->mResolveFlags = aResolveFlags;
pi->mTimeout = mFailedProxyTimeout;
// www.foo.com:8080 and http://www.foo.com:8080
nsDependentCSubstring maybeURL(start, end - start);
nsCOMPtr<nsIURI> pacURI;
nsAutoCString urlHost;
if (NS_SUCCEEDED(NS_NewURI(getter_AddRefs(pacURI), maybeURL)) &&
NS_SUCCEEDED(pacURI->GetAsciiHost(urlHost)) &&
!urlHost.IsEmpty()) {
// http://www.example.com:8080
pi->mHost = urlHost;
int32_t tPort;
if (NS_SUCCEEDED(pacURI->GetPort(&tPort)) && tPort != -1) {
port = tPort;
}
pi->mPort = port;
}
else {
// www.example.com:8080
if (start < end) {
host = start;
hostEnd = strchr(host, ':');
if (!hostEnd || hostEnd > end) {
hostEnd = end;
// no port, so assume default
}
else {
port = atoi(hostEnd + 1);
}
}
// YES, it is ok to specify a null proxy host.
if (host) {
pi->mHost.Assign(host, hostEnd - host);
pi->mPort = port;
}
}
NS_ADDREF(*result = pi);
}
while (*end == ';' || *end == ' ' || *end == '\t')
++end;
return end;
}
void
nsProtocolProxyService::GetProxyKey(nsProxyInfo *pi, nsCString &key)
{
key.AssignASCII(pi->mType);
if (!pi->mHost.IsEmpty()) {
key.Append(' ');
key.Append(pi->mHost);
key.Append(':');
key.AppendInt(pi->mPort);
}
}
uint32_t
nsProtocolProxyService::SecondsSinceSessionStart()
{
PRTime now = PR_Now();
// get time elapsed since session start
int64_t diff = now - mSessionStart;
// convert microseconds to seconds
diff /= PR_USEC_PER_SEC;
// return converted 32 bit value
return uint32_t(diff);
}
void
nsProtocolProxyService::EnableProxy(nsProxyInfo *pi)
{
nsAutoCString key;
GetProxyKey(pi, key);
mFailedProxies.Remove(key);
}
void
nsProtocolProxyService::DisableProxy(nsProxyInfo *pi)
{
nsAutoCString key;
GetProxyKey(pi, key);
uint32_t dsec = SecondsSinceSessionStart();
// Add timeout to interval (this is the time when the proxy can
// be tried again).
dsec += pi->mTimeout;
// NOTE: The classic codebase would increase the timeout value
// incrementally each time a subsequent failure occurred.
// We could do the same, but it would require that we not
// remove proxy entries in IsProxyDisabled or otherwise
// change the way we are recording disabled proxies.
// Simpler is probably better for now, and at least the
// user can tune the timeout setting via preferences.
LOG(("DisableProxy %s %d\n", key.get(), dsec));
// If this fails, oh well... means we don't have enough memory
// to remember the failed proxy.
mFailedProxies.Put(key, dsec);
}
bool
nsProtocolProxyService::IsProxyDisabled(nsProxyInfo *pi)
{
nsAutoCString key;
GetProxyKey(pi, key);
uint32_t val;
if (!mFailedProxies.Get(key, &val))
return false;
uint32_t dsec = SecondsSinceSessionStart();
// if time passed has exceeded interval, then try proxy again.
if (dsec > val) {
mFailedProxies.Remove(key);
return false;
}
return true;
}
nsresult
nsProtocolProxyService::SetupPACThread()
{
if (mPACMan)
return NS_OK;
mPACMan = new nsPACMan();
bool mainThreadOnly;
nsresult rv;
if (mSystemProxySettings &&
NS_SUCCEEDED(mSystemProxySettings->GetMainThreadOnly(&mainThreadOnly)) &&
!mainThreadOnly) {
rv = mPACMan->Init(mSystemProxySettings);
}
else {
rv = mPACMan->Init(nullptr);
}
if (NS_FAILED(rv))
mPACMan = nullptr;
return rv;
}
nsresult
nsProtocolProxyService::ResetPACThread()
{
if (!mPACMan)
return NS_OK;
mPACMan->Shutdown();
mPACMan = nullptr;
return SetupPACThread();
}
nsresult
nsProtocolProxyService::ConfigureFromPAC(const nsCString &spec,
bool forceReload)
{
SetupPACThread();
if (mPACMan->IsPACURI(spec) && !forceReload)
return NS_OK;
mFailedProxies.Clear();
return mPACMan->LoadPACFromURI(spec);
}
void
nsProtocolProxyService::ProcessPACString(const nsCString &pacString,
uint32_t aResolveFlags,
nsIProxyInfo **result)
{
if (pacString.IsEmpty()) {
*result = nullptr;
return;
}
const char *proxies = pacString.get();
nsProxyInfo *pi = nullptr, *first = nullptr, *last = nullptr;
while (*proxies) {
proxies = ExtractProxyInfo(proxies, aResolveFlags, &pi);
if (pi && (pi->mType == kProxyType_HTTPS) && !mProxyOverTLS) {
delete pi;
pi = nullptr;
}
if (pi) {
if (last) {
NS_ASSERTION(last->mNext == nullptr, "leaking nsProxyInfo");
last->mNext = pi;
}
else
first = pi;
last = pi;
}
}
*result = first;
}
// nsIProtocolProxyService2
NS_IMETHODIMP
nsProtocolProxyService::ReloadPAC()
{
nsCOMPtr<nsIPrefBranch> prefs = do_GetService(NS_PREFSERVICE_CONTRACTID);
if (!prefs)
return NS_OK;
int32_t type;
nsresult rv = prefs->GetIntPref(PROXY_PREF("type"), &type);
if (NS_FAILED(rv))
return NS_OK;
nsXPIDLCString pacSpec;
if (type == PROXYCONFIG_PAC)
prefs->GetCharPref(PROXY_PREF("autoconfig_url"), getter_Copies(pacSpec));
else if (type == PROXYCONFIG_WPAD)
pacSpec.AssignLiteral(WPAD_URL);
if (!pacSpec.IsEmpty())
ConfigureFromPAC(pacSpec, true);
return NS_OK;
}
// When sync interface is removed this can go away too
// The nsPACManCallback portion of this implementation should be run
// off the main thread, because it uses a condvar for signaling and
// the main thread is blocking on that condvar -
// so call nsPACMan::AsyncGetProxyForURI() with
// a false mainThreadResponse parameter.
class nsAsyncBridgeRequest final : public nsPACManCallback
{
NS_DECL_THREADSAFE_ISUPPORTS
nsAsyncBridgeRequest()
: mMutex("nsDeprecatedCallback")
, mCondVar(mMutex, "nsDeprecatedCallback")
, mCompleted(false)
{
}
void OnQueryComplete(nsresult status,
const nsCString &pacString,
const nsCString &newPACURL) override
{
MutexAutoLock lock(mMutex);
mCompleted = true;
mStatus = status;
mPACString = pacString;
mPACURL = newPACURL;
mCondVar.Notify();
}
void Lock() { mMutex.Lock(); }
void Unlock() { mMutex.Unlock(); }
void Wait() { mCondVar.Wait(PR_SecondsToInterval(3)); }
private:
~nsAsyncBridgeRequest()
{
}
friend class nsProtocolProxyService;
Mutex mMutex;
CondVar mCondVar;
nsresult mStatus;
nsCString mPACString;
nsCString mPACURL;
bool mCompleted;
};
NS_IMPL_ISUPPORTS0(nsAsyncBridgeRequest)
// nsProtocolProxyService
nsresult
nsProtocolProxyService::DeprecatedBlockingResolve(nsIChannel *aChannel,
uint32_t aFlags,
nsIProxyInfo **retval)
{
NS_ENSURE_ARG_POINTER(aChannel);
nsCOMPtr<nsIURI> uri;
nsresult rv = GetProxyURI(aChannel, getter_AddRefs(uri));
if (NS_FAILED(rv)) return rv;
nsProtocolInfo info;
rv = GetProtocolInfo(uri, &info);
if (NS_FAILED(rv))
return rv;
nsCOMPtr<nsIProxyInfo> pi;
bool usePACThread;
// SystemProxySettings and PAC files can block the main thread
// but if neither of them are in use, we can just do the work
// right here and directly invoke the callback
rv = Resolve_Internal(aChannel, NECKO_NO_APP_ID, false, info, aFlags,
&usePACThread, getter_AddRefs(pi));
if (NS_FAILED(rv))
return rv;
if (!usePACThread || !mPACMan) {
ApplyFilters(aChannel, info, pi);
pi.forget(retval);
return NS_OK;
}
// Use the PAC thread to do the work, so we don't have to reimplement that
// code, but block this thread on that completion.
RefPtr<nsAsyncBridgeRequest> ctx = new nsAsyncBridgeRequest();
ctx->Lock();
if (NS_SUCCEEDED(mPACMan->AsyncGetProxyForURI(uri, NECKO_NO_APP_ID, false,
ctx, false))) {
// this can really block the main thread, so cap it at 3 seconds
ctx->Wait();
}
ctx->Unlock();
if (!ctx->mCompleted)
return NS_ERROR_FAILURE;
if (NS_FAILED(ctx->mStatus))
return ctx->mStatus;
// pretty much duplicate real DoCallback logic
// Generate proxy info from the PAC string if appropriate
if (!ctx->mPACString.IsEmpty()) {
LOG(("sync pac thread callback %s\n", ctx->mPACString.get()));
ProcessPACString(ctx->mPACString, 0, getter_AddRefs(pi));
ApplyFilters(aChannel, info, pi);
pi.forget(retval);
return NS_OK;
}
if (!ctx->mPACURL.IsEmpty()) {
NS_WARNING("sync pac thread callback indicates new pac file load\n");
// This is a problem and is one of the reasons this blocking interface
// is deprecated. The main loop needs to spin to make this reload happen. So
// we are going to kick off the reload and return an error - it will work
// next time. Because this sync interface is only used in the java plugin it
// is extremely likely that the pac file has already been loaded anyhow.
rv = ConfigureFromPAC(ctx->mPACURL, false);
if (NS_FAILED(rv))
return rv;
return NS_ERROR_NOT_AVAILABLE;
}
*retval = nullptr;
return NS_OK;
}
nsresult
nsProtocolProxyService::AsyncResolveInternal(nsIChannel *channel, uint32_t flags,
nsIProtocolProxyCallback *callback,
nsICancelable **result,
bool isSyncOK)
{
NS_ENSURE_ARG_POINTER(channel);
NS_ENSURE_ARG_POINTER(callback);
nsCOMPtr<nsIURI> uri;
nsresult rv = GetProxyURI(channel, getter_AddRefs(uri));
if (NS_FAILED(rv)) return rv;
uint32_t appId = NECKO_NO_APP_ID;
bool isInBrowser = false;
NS_GetAppInfo(channel, &appId, &isInBrowser);
*result = nullptr;
RefPtr<nsAsyncResolveRequest> ctx =
new nsAsyncResolveRequest(this, channel, appId, isInBrowser, flags,
callback);
nsProtocolInfo info;
rv = GetProtocolInfo(uri, &info);
if (NS_FAILED(rv))
return rv;
nsCOMPtr<nsIProxyInfo> pi;
bool usePACThread;
// SystemProxySettings and PAC files can block the main thread
// but if neither of them are in use, we can just do the work
// right here and directly invoke the callback
rv = Resolve_Internal(channel, appId, isInBrowser, info, flags,
&usePACThread, getter_AddRefs(pi));
if (NS_FAILED(rv))
return rv;
if (!usePACThread || !mPACMan) {
// we can do it locally
ApplyFilters(channel, info, pi);
ctx->SetResult(NS_OK, pi);
if (isSyncOK) {
ctx->Run();
return NS_OK;
}
rv = ctx->DispatchCallback();
if (NS_SUCCEEDED(rv))
ctx.forget(result);
return rv;
}
// else kick off a PAC thread query
rv = mPACMan->AsyncGetProxyForURI(uri, appId, isInBrowser, ctx, true);
if (NS_SUCCEEDED(rv))
ctx.forget(result);
return rv;
}
// nsIProtocolProxyService
NS_IMETHODIMP
nsProtocolProxyService::AsyncResolve2(nsIChannel *channel, uint32_t flags,
nsIProtocolProxyCallback *callback,
nsICancelable **result)
{
return AsyncResolveInternal(channel, flags, callback, result, true);
}
NS_IMETHODIMP
nsProtocolProxyService::AsyncResolve(nsISupports *channelOrURI, uint32_t flags,
nsIProtocolProxyCallback *callback,
nsICancelable **result)
{
nsresult rv;
// Check if we got a channel:
nsCOMPtr<nsIChannel> channel = do_QueryInterface(channelOrURI);
if (!channel) {
nsCOMPtr<nsIURI> uri = do_QueryInterface(channelOrURI);
if (!uri) {
return NS_ERROR_NO_INTERFACE;
}
nsCOMPtr<nsIScriptSecurityManager> secMan(
do_GetService(NS_SCRIPTSECURITYMANAGER_CONTRACTID, &rv));
NS_ENSURE_SUCCESS(rv, rv);
nsCOMPtr<nsIPrincipal> systemPrincipal;
rv = secMan->GetSystemPrincipal(getter_AddRefs(systemPrincipal));
NS_ENSURE_SUCCESS(rv, rv);
// creating a temporary channel from the URI which is not
// used to perform any network loads, hence its safe to
// use systemPrincipal as the loadingPrincipal.
rv = NS_NewChannel(getter_AddRefs(channel),
uri,
systemPrincipal,
nsILoadInfo::SEC_NORMAL,
nsIContentPolicy::TYPE_OTHER);
NS_ENSURE_SUCCESS(rv, rv);
}
return AsyncResolveInternal(channel, flags, callback, result, false);
}
NS_IMETHODIMP
nsProtocolProxyService::NewProxyInfo(const nsACString &aType,
const nsACString &aHost,
int32_t aPort,
uint32_t aFlags,
uint32_t aFailoverTimeout,
nsIProxyInfo *aFailoverProxy,
nsIProxyInfo **aResult)
{
return NewProxyInfoWithAuth(aType, aHost, aPort,
EmptyCString(), EmptyCString(),
aFlags, aFailoverTimeout,
aFailoverProxy, aResult);
}
NS_IMETHODIMP
nsProtocolProxyService::NewProxyInfoWithAuth(const nsACString &aType,
const nsACString &aHost,
int32_t aPort,
const nsACString &aUsername,
const nsACString &aPassword,
uint32_t aFlags,
uint32_t aFailoverTimeout,
nsIProxyInfo *aFailoverProxy,
nsIProxyInfo **aResult)
{
static const char *types[] = {
kProxyType_HTTP,
kProxyType_HTTPS,
kProxyType_SOCKS,
kProxyType_SOCKS4,
kProxyType_DIRECT
};
// resolve type; this allows us to avoid copying the type string into each
// proxy info instance. we just reference the string literals directly :)
const char *type = nullptr;
for (uint32_t i = 0; i < ArrayLength(types); ++i) {
if (aType.LowerCaseEqualsASCII(types[i])) {
type = types[i];
break;
}
}
NS_ENSURE_TRUE(type, NS_ERROR_INVALID_ARG);
// We have only implemented username/password for SOCKS proxies.
if ((!aUsername.IsEmpty() || !aPassword.IsEmpty()) &&
!aType.LowerCaseEqualsASCII(kProxyType_SOCKS) &&
!aType.LowerCaseEqualsASCII(kProxyType_SOCKS4)) {
return NS_ERROR_NOT_IMPLEMENTED;
}
return NewProxyInfo_Internal(type, aHost, aPort,
aUsername, aPassword,
aFlags, aFailoverTimeout,
aFailoverProxy, 0, aResult);
}
NS_IMETHODIMP
nsProtocolProxyService::GetFailoverForProxy(nsIProxyInfo *aProxy,
nsIURI *aURI,
nsresult aStatus,
nsIProxyInfo **aResult)
{
// We only support failover when a PAC file is configured, either
// directly or via system settings
if (mProxyConfig != PROXYCONFIG_PAC && mProxyConfig != PROXYCONFIG_WPAD &&
mProxyConfig != PROXYCONFIG_SYSTEM)
return NS_ERROR_NOT_AVAILABLE;
// Verify that |aProxy| is one of our nsProxyInfo objects.
nsCOMPtr<nsProxyInfo> pi = do_QueryInterface(aProxy);
NS_ENSURE_ARG(pi);
// OK, the QI checked out. We can proceed.
// Remember that this proxy is down.
DisableProxy(pi);
// NOTE: At this point, we might want to prompt the user if we have
// not already tried going DIRECT. This is something that the
// classic codebase supported; however, IE6 does not prompt.
if (!pi->mNext)
return NS_ERROR_NOT_AVAILABLE;
LOG(("PAC failover from %s %s:%d to %s %s:%d\n",
pi->mType, pi->mHost.get(), pi->mPort,
pi->mNext->mType, pi->mNext->mHost.get(), pi->mNext->mPort));
NS_ADDREF(*aResult = pi->mNext);
return NS_OK;
}
nsresult
nsProtocolProxyService::InsertFilterLink(FilterLink *link, uint32_t position)
{
if (!mFilters) {
mFilters = link;
return NS_OK;
}
// insert into mFilters in sorted order
FilterLink *last = nullptr;
for (FilterLink *iter = mFilters; iter; iter = iter->next) {
if (position < iter->position) {
if (last) {
link->next = last->next;
last->next = link;
}
else {
link->next = mFilters;
mFilters = link;
}
return NS_OK;
}
last = iter;
}
// our position is equal to or greater than the last link in the list
last->next = link;
return NS_OK;
}
NS_IMETHODIMP
nsProtocolProxyService::RegisterFilter(nsIProtocolProxyFilter *filter,
uint32_t position)
{
UnregisterFilter(filter); // remove this filter if we already have it
FilterLink *link = new FilterLink(position, filter);
if (!link) {
return NS_ERROR_OUT_OF_MEMORY;
}
return InsertFilterLink(link, position);
}
NS_IMETHODIMP
nsProtocolProxyService::RegisterChannelFilter(nsIProtocolProxyChannelFilter *channelFilter,
uint32_t position)
{
UnregisterChannelFilter(channelFilter); // remove this filter if we already have it
FilterLink *link = new FilterLink(position, channelFilter);
if (!link) {
return NS_ERROR_OUT_OF_MEMORY;
}
return InsertFilterLink(link, position);
}
nsresult
nsProtocolProxyService::RemoveFilterLink(nsISupports* givenObject)
{
FilterLink *last = nullptr;
for (FilterLink *iter = mFilters; iter; iter = iter->next) {
nsCOMPtr<nsISupports> object = do_QueryInterface(iter->filter);
nsCOMPtr<nsISupports> object2 = do_QueryInterface(iter->channelFilter);
if (object == givenObject || object2 == givenObject) {
if (last)
last->next = iter->next;
else
mFilters = iter->next;
iter->next = nullptr;
delete iter;
return NS_OK;
}
last = iter;
}
// No need to throw an exception in this case.
return NS_OK;
}
NS_IMETHODIMP
nsProtocolProxyService::UnregisterFilter(nsIProtocolProxyFilter *filter) {
// QI to nsISupports so we can safely test object identity.
nsCOMPtr<nsISupports> givenObject = do_QueryInterface(filter);
return RemoveFilterLink(givenObject);
}
NS_IMETHODIMP
nsProtocolProxyService::UnregisterChannelFilter(nsIProtocolProxyChannelFilter *channelFilter) {
// QI to nsISupports so we can safely test object identity.
nsCOMPtr<nsISupports> givenObject = do_QueryInterface(channelFilter);
return RemoveFilterLink(givenObject);
}
NS_IMETHODIMP
nsProtocolProxyService::GetProxyConfigType(uint32_t* aProxyConfigType)
{
*aProxyConfigType = mProxyConfig;
return NS_OK;
}
void
nsProtocolProxyService::LoadHostFilters(const char *filters)
{
// check to see the owners flag? /!?/ TODO
if (mHostFiltersArray.Length() > 0) {
mHostFiltersArray.Clear();
}
if (!filters)
return; // fail silently...
//
// filter = ( host | domain | ipaddr ["/" mask] ) [":" port]
// filters = filter *( "," LWS filter)
//
// Reset mFilterLocalHosts - will be set to true if "<local>" is in pref string
mFilterLocalHosts = false;
while (*filters) {
// skip over spaces and ,
while (*filters && (*filters == ',' || IS_ASCII_SPACE(*filters)))
filters++;
const char *starthost = filters;
const char *endhost = filters + 1; // at least that...
const char *portLocation = 0;
const char *maskLocation = 0;
while (*endhost && (*endhost != ',' && !IS_ASCII_SPACE(*endhost))) {
if (*endhost == ':')
portLocation = endhost;
else if (*endhost == '/')
maskLocation = endhost;
else if (*endhost == ']') // IPv6 address literals
portLocation = 0;
endhost++;
}
filters = endhost; // advance iterator up front
// locate end of host
const char *end = maskLocation ? maskLocation :
portLocation ? portLocation :
endhost;
nsAutoCString str(starthost, end - starthost);
// If the current host filter is "<local>", then all local (i.e.
// no dots in the hostname) hosts should bypass the proxy
if (str.EqualsIgnoreCase("<local>")) {
mFilterLocalHosts = true;
LOG(("loaded filter for local hosts "
"(plain host names, no dots)\n"));
// Continue to next host filter;
continue;
}
// For all other host filters, create HostInfo object and add to list
HostInfo *hinfo = new HostInfo();
hinfo->port = portLocation ? atoi(portLocation + 1) : 0;
PRNetAddr addr;
if (PR_StringToNetAddr(str.get(), &addr) == PR_SUCCESS) {
hinfo->is_ipaddr = true;
hinfo->ip.family = PR_AF_INET6; // we always store address as IPv6
hinfo->ip.mask_len = maskLocation ? atoi(maskLocation + 1) : 128;
if (hinfo->ip.mask_len == 0) {
NS_WARNING("invalid mask");
goto loser;
}
if (addr.raw.family == PR_AF_INET) {
// convert to IPv4-mapped address
PR_ConvertIPv4AddrToIPv6(addr.inet.ip, &hinfo->ip.addr);
// adjust mask_len accordingly
if (hinfo->ip.mask_len <= 32)
hinfo->ip.mask_len += 96;
}
else if (addr.raw.family == PR_AF_INET6) {
// copy the address
memcpy(&hinfo->ip.addr, &addr.ipv6.ip, sizeof(PRIPv6Addr));
}
else {
NS_WARNING("unknown address family");
goto loser;
}
// apply mask to IPv6 address
proxy_MaskIPv6Addr(hinfo->ip.addr, hinfo->ip.mask_len);
}
else {
uint32_t startIndex, endIndex;
if (str.First() == '*')
startIndex = 1; // *.domain -> .domain
else
startIndex = 0;
endIndex = (portLocation ? portLocation : endhost) - starthost;
hinfo->is_ipaddr = false;
hinfo->name.host = ToNewCString(Substring(str, startIndex, endIndex));
if (!hinfo->name.host)
goto loser;
hinfo->name.host_len = endIndex - startIndex;
}
//#define DEBUG_DUMP_FILTERS
#ifdef DEBUG_DUMP_FILTERS
printf("loaded filter[%u]:\n", mHostFiltersArray.Length());
printf(" is_ipaddr = %u\n", hinfo->is_ipaddr);
printf(" port = %u\n", hinfo->port);
if (hinfo->is_ipaddr) {
printf(" ip.family = %x\n", hinfo->ip.family);
printf(" ip.mask_len = %u\n", hinfo->ip.mask_len);
PRNetAddr netAddr;
PR_SetNetAddr(PR_IpAddrNull, PR_AF_INET6, 0, &netAddr);
memcpy(&netAddr.ipv6.ip, &hinfo->ip.addr, sizeof(hinfo->ip.addr));
char buf[256];
PR_NetAddrToString(&netAddr, buf, sizeof(buf));
printf(" ip.addr = %s\n", buf);
}
else {
printf(" name.host = %s\n", hinfo->name.host);
}
#endif
mHostFiltersArray.AppendElement(hinfo);
hinfo = nullptr;
loser:
delete hinfo;
}
}
nsresult
nsProtocolProxyService::GetProtocolInfo(nsIURI *uri, nsProtocolInfo *info)
{
NS_PRECONDITION(uri, "URI is null");
NS_PRECONDITION(info, "info is null");
nsresult rv;
rv = uri->GetScheme(info->scheme);
if (NS_FAILED(rv))
return rv;
nsCOMPtr<nsIIOService> ios = do_GetIOService(&rv);
if (NS_FAILED(rv))
return rv;
nsCOMPtr<nsIProtocolHandler> handler;
rv = ios->GetProtocolHandler(info->scheme.get(), getter_AddRefs(handler));
if (NS_FAILED(rv))
return rv;
rv = handler->DoGetProtocolFlags(uri, &info->flags);
if (NS_FAILED(rv))
return rv;
rv = handler->GetDefaultPort(&info->defaultPort);
return rv;
}
nsresult
nsProtocolProxyService::NewProxyInfo_Internal(const char *aType,
const nsACString &aHost,
int32_t aPort,
const nsACString &aUsername,
const nsACString &aPassword,
uint32_t aFlags,
uint32_t aFailoverTimeout,
nsIProxyInfo *aFailoverProxy,
uint32_t aResolveFlags,
nsIProxyInfo **aResult)
{
if (aPort <= 0)
aPort = -1;
nsCOMPtr<nsProxyInfo> failover;
if (aFailoverProxy) {
failover = do_QueryInterface(aFailoverProxy);
NS_ENSURE_ARG(failover);
}
nsProxyInfo *proxyInfo = new nsProxyInfo();
if (!proxyInfo)
return NS_ERROR_OUT_OF_MEMORY;
proxyInfo->mType = aType;
proxyInfo->mHost = aHost;
proxyInfo->mPort = aPort;
proxyInfo->mUsername = aUsername;
proxyInfo->mPassword = aPassword;
proxyInfo->mFlags = aFlags;
proxyInfo->mResolveFlags = aResolveFlags;
proxyInfo->mTimeout = aFailoverTimeout == UINT32_MAX
? mFailedProxyTimeout : aFailoverTimeout;
failover.swap(proxyInfo->mNext);
NS_ADDREF(*aResult = proxyInfo);
return NS_OK;
}
nsresult
nsProtocolProxyService::Resolve_Internal(nsIChannel *channel,
uint32_t appId,
bool isInBrowser,
const nsProtocolInfo &info,
uint32_t flags,
bool *usePACThread,
nsIProxyInfo **result)
{
NS_ENSURE_ARG_POINTER(channel);
nsresult rv = SetupPACThread();
if (NS_FAILED(rv))
return rv;
*usePACThread = false;
*result = nullptr;
if (!(info.flags & nsIProtocolHandler::ALLOWS_PROXY))
return NS_OK; // Can't proxy this (filters may not override)
nsCOMPtr<nsIURI> uri;
rv = GetProxyURI(channel, getter_AddRefs(uri));
if (NS_FAILED(rv)) return rv;
// See bug #586908.
// Avoid endless loop if |uri| is the current PAC-URI. Returning OK
// here means that we will not use a proxy for this connection.
if (mPACMan && mPACMan->IsPACURI(uri))
return NS_OK;
bool mainThreadOnly;
if (mSystemProxySettings &&
mProxyConfig == PROXYCONFIG_SYSTEM &&
NS_SUCCEEDED(mSystemProxySettings->GetMainThreadOnly(&mainThreadOnly)) &&
!mainThreadOnly) {
*usePACThread = true;
return NS_OK;
}
if (mSystemProxySettings && mProxyConfig == PROXYCONFIG_SYSTEM) {
// If the system proxy setting implementation is not threadsafe (e.g
// linux gconf), we'll do it inline here. Such implementations promise
// not to block
nsAutoCString PACURI;
nsAutoCString pacString;
if (NS_SUCCEEDED(mSystemProxySettings->GetPACURI(PACURI)) &&
!PACURI.IsEmpty()) {
// There is a PAC URI configured. If it is unchanged, then
// just execute the PAC thread. If it is changed then load
// the new value
if (mPACMan && mPACMan->IsPACURI(PACURI)) {
// unchanged
*usePACThread = true;
return NS_OK;
}
ConfigureFromPAC(PACURI, false);
return NS_OK;
}
nsAutoCString spec;
nsAutoCString host;
nsAutoCString scheme;
int32_t port = -1;
uri->GetAsciiSpec(spec);
uri->GetAsciiHost(host);
uri->GetScheme(scheme);
uri->GetPort(&port);
// now try the system proxy settings for this particular url
if (NS_SUCCEEDED(mSystemProxySettings->
GetProxyForURI(spec, scheme, host, port,
pacString))) {
ProcessPACString(pacString, 0, result);
return NS_OK;
}
}
// if proxies are enabled and this host:port combo is supposed to use a
// proxy, check for a proxy.
if (mProxyConfig == PROXYCONFIG_DIRECT ||
(mProxyConfig == PROXYCONFIG_MANUAL &&
!CanUseProxy(uri, info.defaultPort)))
return NS_OK;
// Proxy auto config magic...
if (mProxyConfig == PROXYCONFIG_PAC || mProxyConfig == PROXYCONFIG_WPAD) {
// Do not query PAC now.
*usePACThread = true;
return NS_OK;
}
// If we aren't in manual proxy configuration mode then we don't
// want to honor any manual specific prefs that might be still set
if (mProxyConfig != PROXYCONFIG_MANUAL)
return NS_OK;
// proxy info values for manual configuration mode
const char *type = nullptr;
const nsACString *host = nullptr;
int32_t port = -1;
uint32_t proxyFlags = 0;
if ((flags & RESOLVE_PREFER_SOCKS_PROXY) &&
!mSOCKSProxyHost.IsEmpty() && mSOCKSProxyPort > 0) {
host = &mSOCKSProxyHost;
if (mSOCKSProxyVersion == 4)
type = kProxyType_SOCKS4;
else
type = kProxyType_SOCKS;
port = mSOCKSProxyPort;
if (mSOCKSProxyRemoteDNS)
proxyFlags |= nsIProxyInfo::TRANSPARENT_PROXY_RESOLVES_HOST;
}
else if ((flags & RESOLVE_PREFER_HTTPS_PROXY) &&
!mHTTPSProxyHost.IsEmpty() && mHTTPSProxyPort > 0) {
host = &mHTTPSProxyHost;
type = kProxyType_HTTP;
port = mHTTPSProxyPort;
}
else if (!mHTTPProxyHost.IsEmpty() && mHTTPProxyPort > 0 &&
((flags & RESOLVE_IGNORE_URI_SCHEME) ||
info.scheme.EqualsLiteral("http"))) {
host = &mHTTPProxyHost;
type = kProxyType_HTTP;
port = mHTTPProxyPort;
}
else if (!mHTTPSProxyHost.IsEmpty() && mHTTPSProxyPort > 0 &&
!(flags & RESOLVE_IGNORE_URI_SCHEME) &&
info.scheme.EqualsLiteral("https")) {
host = &mHTTPSProxyHost;
type = kProxyType_HTTP;
port = mHTTPSProxyPort;
}
else if (!mFTPProxyHost.IsEmpty() && mFTPProxyPort > 0 &&
!(flags & RESOLVE_IGNORE_URI_SCHEME) &&
info.scheme.EqualsLiteral("ftp")) {
host = &mFTPProxyHost;
type = kProxyType_HTTP;
port = mFTPProxyPort;
}
else if (!mSOCKSProxyHost.IsEmpty() && mSOCKSProxyPort > 0) {
host = &mSOCKSProxyHost;
if (mSOCKSProxyVersion == 4)
type = kProxyType_SOCKS4;
else
type = kProxyType_SOCKS;
port = mSOCKSProxyPort;
if (mSOCKSProxyRemoteDNS)
proxyFlags |= nsIProxyInfo::TRANSPARENT_PROXY_RESOLVES_HOST;
}
if (type) {
rv = NewProxyInfo_Internal(type, *host, port,
EmptyCString(), EmptyCString(),
proxyFlags, UINT32_MAX, nullptr, flags,
result);
if (NS_FAILED(rv))
return rv;
}
return NS_OK;
}
void
nsProtocolProxyService::MaybeDisableDNSPrefetch(nsIProxyInfo *aProxy)
{
// Disable Prefetch in the DNS service if a proxy is in use.
if (!aProxy)
return;
nsCOMPtr<nsProxyInfo> pi = do_QueryInterface(aProxy);
if (!pi ||
!pi->mType ||
pi->mType == kProxyType_DIRECT)
return;
nsCOMPtr<nsIDNSService> dns = do_GetService(NS_DNSSERVICE_CONTRACTID);
if (!dns)
return;
nsCOMPtr<nsPIDNSService> pdns = do_QueryInterface(dns);
if (!pdns)
return;
// We lose the prefetch optimization for the life of the dns service.
pdns->SetPrefetchEnabled(false);
}
void
nsProtocolProxyService::ApplyFilters(nsIChannel *channel,
const nsProtocolInfo &info,
nsIProxyInfo **list)
{
if (!(info.flags & nsIProtocolHandler::ALLOWS_PROXY))
return;
// We prune the proxy list prior to invoking each filter. This may be
// somewhat inefficient, but it seems like a good idea since we want each
// filter to "see" a valid proxy list.
nsCOMPtr<nsIProxyInfo> result;
for (FilterLink *iter = mFilters; iter; iter = iter->next) {
PruneProxyInfo(info, list);
nsresult rv = NS_OK;
if (iter->filter) {
nsCOMPtr<nsIURI> uri;
rv = GetProxyURI(channel, getter_AddRefs(uri));
if (uri) {
rv = iter->filter->ApplyFilter(this, uri, *list,
getter_AddRefs(result));
}
} else if (iter->channelFilter) {
rv = iter->channelFilter->ApplyFilter(this, channel, *list,
getter_AddRefs(result));
}
if (NS_FAILED(rv))
continue;
result.swap(*list);
}
PruneProxyInfo(info, list);
}
void
nsProtocolProxyService::PruneProxyInfo(const nsProtocolInfo &info,
nsIProxyInfo **list)
{
if (!*list)
return;
nsProxyInfo *head = nullptr;
CallQueryInterface(*list, &head);
if (!head) {
NS_NOTREACHED("nsIProxyInfo must QI to nsProxyInfo");
return;
}
NS_RELEASE(*list);
// Pruning of disabled proxies works like this:
// - If all proxies are disabled, return the full list
// - Otherwise, remove the disabled proxies.
//
// Pruning of disallowed proxies works like this:
// - If the protocol handler disallows the proxy, then we disallow it.
// Start by removing all disallowed proxies if required:
if (!(info.flags & nsIProtocolHandler::ALLOWS_PROXY_HTTP)) {
nsProxyInfo *last = nullptr, *iter = head;
while (iter) {
if ((iter->Type() == kProxyType_HTTP) ||
(iter->Type() == kProxyType_HTTPS)) {
// reject!
if (last)
last->mNext = iter->mNext;
else
head = iter->mNext;
nsProxyInfo *next = iter->mNext;
iter->mNext = nullptr;
iter->Release();
iter = next;
} else {
last = iter;
iter = iter->mNext;
}
}
if (!head)
return;
}
// Now, scan to see if all remaining proxies are disabled. If so, then
// we'll just bail and return them all. Otherwise, we'll go and prune the
// disabled ones.
bool allDisabled = true;
nsProxyInfo *iter;
for (iter = head; iter; iter = iter->mNext) {
if (!IsProxyDisabled(iter)) {
allDisabled = false;
break;
}
}
if (allDisabled)
LOG(("All proxies are disabled, so trying all again"));
else {
// remove any disabled proxies.
nsProxyInfo *last = nullptr;
for (iter = head; iter; ) {
if (IsProxyDisabled(iter)) {
// reject!
nsProxyInfo *reject = iter;
iter = iter->mNext;
if (last)
last->mNext = iter;
else
head = iter;
reject->mNext = nullptr;
NS_RELEASE(reject);
continue;
}
// since we are about to use this proxy, make sure it is not on
// the disabled proxy list. we'll add it back to that list if
// we have to (in GetFailoverForProxy).
//
// XXX(darin): It might be better to do this as a final pass.
//
EnableProxy(iter);
last = iter;
iter = iter->mNext;
}
}
// if only DIRECT was specified then return no proxy info, and we're done.
if (head && !head->mNext && head->mType == kProxyType_DIRECT)
NS_RELEASE(head);
*list = head; // Transfer ownership
}