// Copyright (c) 2006-2008 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "net/base/ssl_client_socket.h"
#include <schnlsp.h>
#include "base/singleton.h"
#include "base/string_util.h"
#include "net/base/net_errors.h"
#include "net/base/ssl_info.h"
namespace net {
//-----------------------------------------------------------------------------
class SChannelLib {
public:
PSecurityFunctionTable funcs;
SChannelLib() : funcs(NULL) {
lib_ = LoadLibrary(L"secur32.dll");
if (lib_) {
INIT_SECURITY_INTERFACE init_security_interface =
reinterpret_cast<INIT_SECURITY_INTERFACE>(
GetProcAddress(lib_, "InitSecurityInterfaceW"));
if (init_security_interface)
funcs = init_security_interface();
}
}
~SChannelLib() {
if (lib_)
FreeLibrary(lib_);
}
private:
HMODULE lib_;
};
static inline PSecurityFunctionTable SChannel() {
return Singleton<SChannelLib>()->funcs;
}
//-----------------------------------------------------------------------------
// Size of recv_buffer_
//
// Ciphertext is decrypted one SSL record at a time, so recv_buffer_ needs to
// have room for a full SSL record, with the header and trailer. Here is the
// breakdown of the size:
// 5: SSL record header
// 16K: SSL record maximum size
// 64: >= SSL record trailer (16 or 20 have been observed)
static const int kRecvBufferSize = (5 + 16*1024 + 64);
SSLClientSocket::SSLClientSocket(ClientSocket* transport_socket,
const std::string& hostname)
#pragma warning(suppress: 4355)
: io_callback_(this, &SSLClientSocket::OnIOComplete),
transport_(transport_socket),
hostname_(hostname),
user_callback_(NULL),
user_buf_(NULL),
user_buf_len_(0),
next_state_(STATE_NONE),
payload_send_buffer_len_(0),
bytes_sent_(0),
decrypted_ptr_(NULL),
bytes_decrypted_(0),
received_ptr_(NULL),
bytes_received_(0),
completed_handshake_(false),
ignore_ok_result_(false) {
memset(&stream_sizes_, 0, sizeof(stream_sizes_));
memset(&send_buffer_, 0, sizeof(send_buffer_));
memset(&creds_, 0, sizeof(creds_));
memset(&ctxt_, 0, sizeof(ctxt_));
}
SSLClientSocket::~SSLClientSocket() {
Disconnect();
}
int SSLClientSocket::Connect(CompletionCallback* callback) {
DCHECK(transport_.get());
DCHECK(next_state_ == STATE_NONE);
DCHECK(!user_callback_);
next_state_ = STATE_CONNECT;
int rv = DoLoop(OK);
if (rv == ERR_IO_PENDING)
user_callback_ = callback;
return rv;
}
int SSLClientSocket::ReconnectIgnoringLastError(CompletionCallback* callback) {
// TODO(darin): implement me!
return ERR_FAILED;
}
void SSLClientSocket::Disconnect() {
// TODO(wtc): Send SSL close_notify alert.
completed_handshake_ = false;
transport_->Disconnect();
if (send_buffer_.pvBuffer) {
SChannel()->FreeContextBuffer(send_buffer_.pvBuffer);
memset(&send_buffer_, 0, sizeof(send_buffer_));
}
if (creds_.dwLower || creds_.dwUpper) {
SChannel()->FreeCredentialsHandle(&creds_);
memset(&creds_, 0, sizeof(creds_));
}
if (ctxt_.dwLower || ctxt_.dwUpper) {
SChannel()->DeleteSecurityContext(&ctxt_);
memset(&ctxt_, 0, sizeof(ctxt_));
}
// TODO(wtc): reset more members?
bytes_decrypted_ = 0;
bytes_received_ = 0;
}
bool SSLClientSocket::IsConnected() const {
return completed_handshake_ && transport_->IsConnected();
}
int SSLClientSocket::Read(char* buf, int buf_len,
CompletionCallback* callback) {
DCHECK(completed_handshake_);
DCHECK(next_state_ == STATE_NONE);
DCHECK(!user_callback_);
// If we have surplus decrypted plaintext, satisfy the Read with it without
// reading more ciphertext from the transport socket.
if (bytes_decrypted_ != 0) {
int len = std::min(buf_len, bytes_decrypted_);
memcpy(buf, decrypted_ptr_, len);
decrypted_ptr_ += len;
bytes_decrypted_ -= len;
if (bytes_decrypted_ == 0) {
decrypted_ptr_ = NULL;
if (bytes_received_ != 0) {
memmove(recv_buffer_.get(), received_ptr_, bytes_received_);
received_ptr_ = recv_buffer_.get();
}
}
return len;
}
user_buf_ = buf;
user_buf_len_ = buf_len;
if (bytes_received_ == 0) {
next_state_ = STATE_PAYLOAD_READ;
} else {
next_state_ = STATE_PAYLOAD_READ_COMPLETE;
ignore_ok_result_ = true; // OK doesn't mean EOF.
}
int rv = DoLoop(OK);
if (rv == ERR_IO_PENDING)
user_callback_ = callback;
return rv;
}
int SSLClientSocket::Write(const char* buf, int buf_len,
CompletionCallback* callback) {
DCHECK(completed_handshake_);
DCHECK(next_state_ == STATE_NONE);
DCHECK(!user_callback_);
user_buf_ = const_cast<char*>(buf);
user_buf_len_ = buf_len;
next_state_ = STATE_PAYLOAD_ENCRYPT;
int rv = DoLoop(OK);
if (rv == ERR_IO_PENDING)
user_callback_ = callback;
return rv;
}
void SSLClientSocket::GetSSLInfo(SSLInfo* ssl_info) {
SECURITY_STATUS status;
PCCERT_CONTEXT server_cert = NULL;
status = SChannel()->QueryContextAttributes(&ctxt_,
SECPKG_ATTR_REMOTE_CERT_CONTEXT,
&server_cert);
if (status == SEC_E_OK) {
DCHECK(server_cert);
ssl_info->cert = X509Certificate::CreateFromHandle(server_cert);
}
SecPkgContext_ConnectionInfo connection_info;
status = SChannel()->QueryContextAttributes(&ctxt_,
SECPKG_ATTR_CONNECTION_INFO,
&connection_info);
if (status == SEC_E_OK) {
// TODO(wtc): compute the overall security strength, taking into account
// dwExchStrength and dwHashStrength. dwExchStrength needs to be
// normalized.
ssl_info->security_bits = connection_info.dwCipherStrength;
}
ssl_info->cert_status = 0;
}
void SSLClientSocket::DoCallback(int rv) {
DCHECK(rv != ERR_IO_PENDING);
DCHECK(user_callback_);
// since Run may result in Read being called, clear user_callback_ up front.
CompletionCallback* c = user_callback_;
user_callback_ = NULL;
c->Run(rv);
}
void SSLClientSocket::OnIOComplete(int result) {
int rv = DoLoop(result);
if (rv != ERR_IO_PENDING)
DoCallback(rv);
}
int SSLClientSocket::DoLoop(int last_io_result) {
DCHECK(next_state_ != STATE_NONE);
int rv = last_io_result;
do {
State state = next_state_;
next_state_ = STATE_NONE;
switch (state) {
case STATE_CONNECT:
rv = DoConnect();
break;
case STATE_CONNECT_COMPLETE:
rv = DoConnectComplete(rv);
break;
case STATE_HANDSHAKE_READ:
rv = DoHandshakeRead();
break;
case STATE_HANDSHAKE_READ_COMPLETE:
rv = DoHandshakeReadComplete(rv);
break;
case STATE_HANDSHAKE_WRITE:
rv = DoHandshakeWrite();
break;
case STATE_HANDSHAKE_WRITE_COMPLETE:
rv = DoHandshakeWriteComplete(rv);
break;
case STATE_PAYLOAD_READ:
rv = DoPayloadRead();
break;
case STATE_PAYLOAD_READ_COMPLETE:
rv = DoPayloadReadComplete(rv);
break;
case STATE_PAYLOAD_ENCRYPT:
rv = DoPayloadEncrypt();
break;
case STATE_PAYLOAD_WRITE:
rv = DoPayloadWrite();
break;
case STATE_PAYLOAD_WRITE_COMPLETE:
rv = DoPayloadWriteComplete(rv);
break;
default:
rv = ERR_FAILED;
NOTREACHED() << "unexpected state";
}
} while (rv != ERR_IO_PENDING && next_state_ != STATE_NONE);
return rv;
}
int SSLClientSocket::DoConnect() {
next_state_ = STATE_CONNECT_COMPLETE;
return transport_->Connect(&io_callback_);
}
int SSLClientSocket::DoConnectComplete(int result) {
if (result < 0)
return result;
memset(&ctxt_, 0, sizeof(ctxt_));
memset(&creds_, 0, sizeof(creds_));
SCHANNEL_CRED schannel_cred = {0};
schannel_cred.dwVersion = SCHANNEL_CRED_VERSION;
// TODO(wtc): This should be configurable. Hardcoded to do SSL 3.0 and
// TLS 1.0 for now. The default (0) means Schannel selects the protocol.
// The global system registry settings take precedence over this value.
schannel_cred.grbitEnabledProtocols = SP_PROT_SSL3TLS1;
// The default session lifetime is 36000000 milliseconds (ten hours). Set
// schannel_cred.dwSessionLifespan to change the number of milliseconds that
// Schannel keeps the session in its session cache.
// We can set the key exchange algorithms (RSA or DH) in
// schannel_cred.{cSupportedAlgs,palgSupportedAlgs}.
// TODO(wtc): We may need to use SCH_CRED_IGNORE_NO_REVOCATION_CHECK and
// SCH_CRED_IGNORE_REVOCATION_OFFLINE, but only after getting the
// CRYPT_E_NO_REVOCATION_CHECK and CRYPT_E_REVOCATION_OFFLINE errors.
//
// Look into undocumented or poorly documented flags:
// SCH_CRED_RESTRICTED_ROOTS
// SCH_CRED_REVOCATION_CHECK_CACHE_ONLY
// SCH_CRED_CACHE_ONLY_URL_RETRIEVAL
// SCH_CRED_MEMORY_STORE_CERT
// SCH_CRED_CACHE_ONLY_URL_RETRIEVAL_ON_CREATE
//
// SCH_CRED_NO_SERVERNAME_CHECK can be useful during testing.
schannel_cred.dwFlags |= SCH_CRED_NO_DEFAULT_CREDS |
SCH_CRED_NO_SERVERNAME_CHECK | // Remove me!
SCH_CRED_AUTO_CRED_VALIDATION |
SCH_CRED_REVOCATION_CHECK_CHAIN_EXCLUDE_ROOT;
TimeStamp expiry;
SECURITY_STATUS status;
status = SChannel()->AcquireCredentialsHandle(
NULL, // Not used
UNISP_NAME, // Microsoft Unified Security Protocol Provider
SECPKG_CRED_OUTBOUND,
NULL, // Not used
&schannel_cred,
NULL, // Not used
NULL, // Not used
&creds_,
&expiry); // Optional
if (status != SEC_E_OK) {
DLOG(ERROR) << "AcquireCredentialsHandle failed: " << status;
return ERR_FAILED; // TODO(wtc): map SEC_E_xxx error codes.
}
SecBufferDesc buffer_desc;
DWORD out_flags;
DWORD flags = ISC_REQ_SEQUENCE_DETECT |
ISC_REQ_REPLAY_DETECT |
ISC_REQ_CONFIDENTIALITY |
ISC_RET_EXTENDED_ERROR |
ISC_REQ_ALLOCATE_MEMORY |
ISC_REQ_STREAM;
send_buffer_.pvBuffer = NULL;
send_buffer_.BufferType = SECBUFFER_TOKEN;
send_buffer_.cbBuffer = 0;
buffer_desc.cBuffers = 1;
buffer_desc.pBuffers = &send_buffer_;
buffer_desc.ulVersion = SECBUFFER_VERSION;
status = SChannel()->InitializeSecurityContext(
&creds_,
NULL, // NULL on the first call
const_cast<wchar_t*>(ASCIIToWide(hostname_).c_str()),
flags,
0, // Reserved
SECURITY_NATIVE_DREP, // TODO(wtc): MSDN says this should be set to 0.
NULL, // NULL on the first call
0, // Reserved
&ctxt_, // Receives the new context handle
&buffer_desc,
&out_flags,
&expiry);
if (status != SEC_I_CONTINUE_NEEDED) {
DLOG(ERROR) << "InitializeSecurityContext failed: " << status;
return ERR_FAILED; // TODO(wtc): map SEC_E_xxx error codes.
}
next_state_ = STATE_HANDSHAKE_WRITE;
return OK;
}
int SSLClientSocket::DoHandshakeRead() {
next_state_ = STATE_HANDSHAKE_READ_COMPLETE;
if (!recv_buffer_.get())
recv_buffer_.reset(new char[kRecvBufferSize]);
char* buf = recv_buffer_.get() + bytes_received_;
int buf_len = kRecvBufferSize - bytes_received_;
if (buf_len <= 0) {
NOTREACHED() << "Receive buffer is too small!";
return ERR_FAILED;
}
return transport_->Read(buf, buf_len, &io_callback_);
}
int SSLClientSocket::DoHandshakeReadComplete(int result) {
if (result < 0)
return result;
if (result == 0 && !ignore_ok_result_)
return ERR_FAILED; // Incomplete response :(
ignore_ok_result_ = false;
bytes_received_ += result;
// Process the contents of recv_buffer_.
SECURITY_STATUS status;
TimeStamp expiry;
DWORD out_flags;
DWORD flags = ISC_REQ_SEQUENCE_DETECT |
ISC_REQ_REPLAY_DETECT |
ISC_REQ_CONFIDENTIALITY |
ISC_RET_EXTENDED_ERROR |
ISC_REQ_ALLOCATE_MEMORY |
ISC_REQ_STREAM;
SecBufferDesc in_buffer_desc, out_buffer_desc;
SecBuffer in_buffers[2];
in_buffer_desc.cBuffers = 2;
in_buffer_desc.pBuffers = in_buffers;
in_buffer_desc.ulVersion = SECBUFFER_VERSION;
in_buffers[0].pvBuffer = &recv_buffer_[0];
in_buffers[0].cbBuffer = bytes_received_;
in_buffers[0].BufferType = SECBUFFER_TOKEN;
in_buffers[1].pvBuffer = NULL;
in_buffers[1].cbBuffer = 0;
in_buffers[1].BufferType = SECBUFFER_EMPTY;
out_buffer_desc.cBuffers = 1;
out_buffer_desc.pBuffers = &send_buffer_;
out_buffer_desc.ulVersion = SECBUFFER_VERSION;
send_buffer_.pvBuffer = NULL;
send_buffer_.BufferType = SECBUFFER_TOKEN;
send_buffer_.cbBuffer = 0;
status = SChannel()->InitializeSecurityContext(
&creds_,
&ctxt_,
NULL,
flags,
0,
SECURITY_NATIVE_DREP,
&in_buffer_desc,
0,
NULL,
&out_buffer_desc,
&out_flags,
&expiry);
if (status == SEC_E_INCOMPLETE_MESSAGE) {
DCHECK(FAILED(status));
DCHECK(send_buffer_.cbBuffer == 0 ||
!(out_flags & ISC_RET_EXTENDED_ERROR));
next_state_ = STATE_HANDSHAKE_READ;
return OK;
}
if (send_buffer_.cbBuffer != 0 &&
(status == SEC_E_OK ||
status == SEC_I_CONTINUE_NEEDED ||
FAILED(status) && (out_flags & ISC_RET_EXTENDED_ERROR))) {
// TODO(wtc): if status is SEC_E_OK, we should finish the handshake
// successfully after sending send_buffer_.
// If FAILED(status) is true, we should terminate the connection after
// sending send_buffer_.
DCHECK(status == SEC_I_CONTINUE_NEEDED); // We only handle this case
// correctly.
next_state_ = STATE_HANDSHAKE_WRITE;
bytes_received_ = 0;
return OK;
}
if (status == SEC_E_OK) {
if (in_buffers[1].BufferType == SECBUFFER_EXTRA) {
// TODO(darin) need to save this data for later.
NOTREACHED() << "should not occur for HTTPS traffic";
return ERR_FAILED;
}
bytes_received_ = 0;
return DidCompleteHandshake();
}
if (FAILED(status))
return ERR_FAILED; // TODO(wtc): map error codes, in particular cert
// errors such as SEC_E_UNTRUSTED_ROOT.
DCHECK(status == SEC_I_CONTINUE_NEEDED);
if (in_buffers[1].BufferType == SECBUFFER_EXTRA) {
memmove(&recv_buffer_[0],
&recv_buffer_[0] + (bytes_received_ - in_buffers[1].cbBuffer),
in_buffers[1].cbBuffer);
bytes_received_ = in_buffers[1].cbBuffer;
next_state_ = STATE_HANDSHAKE_READ_COMPLETE;
ignore_ok_result_ = true; // OK doesn't mean EOF.
return OK;
}
bytes_received_ = 0;
next_state_ = STATE_HANDSHAKE_READ;
return OK;
}
int SSLClientSocket::DoHandshakeWrite() {
next_state_ = STATE_HANDSHAKE_WRITE_COMPLETE;
// We should have something to send.
DCHECK(send_buffer_.pvBuffer);
DCHECK(send_buffer_.cbBuffer > 0);
const char* buf = static_cast<char*>(send_buffer_.pvBuffer) + bytes_sent_;
int buf_len = send_buffer_.cbBuffer - bytes_sent_;
return transport_->Write(buf, buf_len, &io_callback_);
}
int SSLClientSocket::DoHandshakeWriteComplete(int result) {
if (result < 0)
return result;
DCHECK(result != 0);
bytes_sent_ += result;
DCHECK(bytes_sent_ <= static_cast<int>(send_buffer_.cbBuffer));
if (bytes_sent_ >= static_cast<int>(send_buffer_.cbBuffer)) {
bool overflow = (bytes_sent_ > static_cast<int>(send_buffer_.cbBuffer));
SECURITY_STATUS status =
SChannel()->FreeContextBuffer(send_buffer_.pvBuffer);
DCHECK(status == SEC_E_OK);
memset(&send_buffer_, 0, sizeof(send_buffer_));
bytes_sent_ = 0;
if (overflow) // Bug!
return ERR_UNEXPECTED;
next_state_ = STATE_HANDSHAKE_READ;
} else {
// Send the remaining bytes.
next_state_ = STATE_HANDSHAKE_WRITE;
}
return OK;
}
int SSLClientSocket::DoPayloadRead() {
next_state_ = STATE_PAYLOAD_READ_COMPLETE;
DCHECK(recv_buffer_.get());
char* buf = recv_buffer_.get() + bytes_received_;
int buf_len = kRecvBufferSize - bytes_received_;
if (buf_len <= 0) {
NOTREACHED() << "Receive buffer is too small!";
return ERR_FAILED;
}
return transport_->Read(buf, buf_len, &io_callback_);
}
int SSLClientSocket::DoPayloadReadComplete(int result) {
if (result < 0)
return result;
if (result == 0 && !ignore_ok_result_) {
// TODO(wtc): Unless we have received the close_notify alert, we need to
// return an error code indicating that the SSL connection ended
// uncleanly, a potential truncation attack.
if (bytes_received_ != 0)
return ERR_FAILED;
return OK;
}
ignore_ok_result_ = false;
bytes_received_ += result;
// Process the contents of recv_buffer_.
SecBuffer buffers[4];
buffers[0].pvBuffer = recv_buffer_.get();
buffers[0].cbBuffer = bytes_received_;
buffers[0].BufferType = SECBUFFER_DATA;
buffers[1].BufferType = SECBUFFER_EMPTY;
buffers[2].BufferType = SECBUFFER_EMPTY;
buffers[3].BufferType = SECBUFFER_EMPTY;
SecBufferDesc buffer_desc;
buffer_desc.cBuffers = 4;
buffer_desc.pBuffers = buffers;
buffer_desc.ulVersion = SECBUFFER_VERSION;
SECURITY_STATUS status;
status = SChannel()->DecryptMessage(&ctxt_, &buffer_desc, 0, NULL);
if (status == SEC_E_INCOMPLETE_MESSAGE) {
next_state_ = STATE_PAYLOAD_READ;
return OK;
}
if (status == SEC_I_CONTEXT_EXPIRED) {
// Received the close_notify alert.
bytes_received_ = 0;
return OK;
}
if (status != SEC_E_OK && status != SEC_I_RENEGOTIATE) {
DCHECK(status != SEC_E_MESSAGE_ALTERED);
return ERR_FAILED; // TODO(wtc): map error code
}
// The received ciphertext was decrypted in place in recv_buffer_. Remember
// the location and length of the decrypted plaintext and any unused
// ciphertext.
decrypted_ptr_ = NULL;
bytes_decrypted_ = 0;
received_ptr_ = NULL;
bytes_received_ = 0;
for (int i = 1; i < 4; i++) {
if (!decrypted_ptr_ && buffers[i].BufferType == SECBUFFER_DATA) {
decrypted_ptr_ = static_cast<char*>(buffers[i].pvBuffer);
bytes_decrypted_ = buffers[i].cbBuffer;
}
if (!received_ptr_ && buffers[i].BufferType == SECBUFFER_EXTRA) {
received_ptr_ = static_cast<char*>(buffers[i].pvBuffer);
bytes_received_ = buffers[i].cbBuffer;
}
}
int len = 0;
if (bytes_decrypted_ != 0) {
len = std::min(user_buf_len_, bytes_decrypted_);
memcpy(user_buf_, decrypted_ptr_, len);
decrypted_ptr_ += len;
bytes_decrypted_ -= len;
}
if (bytes_decrypted_ == 0) {
decrypted_ptr_ = NULL;
if (bytes_received_ != 0) {
memmove(recv_buffer_.get(), received_ptr_, bytes_received_);
received_ptr_ = recv_buffer_.get();
}
}
// TODO(wtc): need to handle SEC_I_RENEGOTIATE.
DCHECK(status == SEC_E_OK);
return len;
}
int SSLClientSocket::DoPayloadEncrypt() {
DCHECK(user_buf_);
DCHECK(user_buf_len_ > 0);
ULONG message_len = std::min(
stream_sizes_.cbMaximumMessage, static_cast<ULONG>(user_buf_len_));
ULONG alloc_len =
message_len + stream_sizes_.cbHeader + stream_sizes_.cbTrailer;
user_buf_len_ = message_len;
payload_send_buffer_.reset(new char[alloc_len]);
memcpy(&payload_send_buffer_[stream_sizes_.cbHeader],
user_buf_, message_len);
SecBuffer buffers[4];
buffers[0].pvBuffer = payload_send_buffer_.get();
buffers[0].cbBuffer = stream_sizes_.cbHeader;
buffers[0].BufferType = SECBUFFER_STREAM_HEADER;
buffers[1].pvBuffer = &payload_send_buffer_[stream_sizes_.cbHeader];
buffers[1].cbBuffer = message_len;
buffers[1].BufferType = SECBUFFER_DATA;
buffers[2].pvBuffer = &payload_send_buffer_[stream_sizes_.cbHeader +
message_len];
buffers[2].cbBuffer = stream_sizes_.cbTrailer;
buffers[2].BufferType = SECBUFFER_STREAM_TRAILER;
buffers[3].BufferType = SECBUFFER_EMPTY;
SecBufferDesc buffer_desc;
buffer_desc.cBuffers = 4;
buffer_desc.pBuffers = buffers;
buffer_desc.ulVersion = SECBUFFER_VERSION;
SECURITY_STATUS status = SChannel()->EncryptMessage(
&ctxt_, 0, &buffer_desc, 0);
if (FAILED(status))
return ERR_FAILED;
payload_send_buffer_len_ = buffers[0].cbBuffer +
buffers[1].cbBuffer +
buffers[2].cbBuffer;
DCHECK(bytes_sent_ == 0);
next_state_ = STATE_PAYLOAD_WRITE;
return OK;
}
int SSLClientSocket::DoPayloadWrite() {
next_state_ = STATE_PAYLOAD_WRITE_COMPLETE;
// We should have something to send.
DCHECK(payload_send_buffer_.get());
DCHECK(payload_send_buffer_len_ > 0);
const char* buf = payload_send_buffer_.get() + bytes_sent_;
int buf_len = payload_send_buffer_len_ - bytes_sent_;
return transport_->Write(buf, buf_len, &io_callback_);
}
int SSLClientSocket::DoPayloadWriteComplete(int result) {
if (result < 0)
return result;
DCHECK(result != 0);
bytes_sent_ += result;
DCHECK(bytes_sent_ <= payload_send_buffer_len_);
if (bytes_sent_ >= payload_send_buffer_len_) {
bool overflow = (bytes_sent_ > payload_send_buffer_len_);
payload_send_buffer_.reset();
payload_send_buffer_len_ = 0;
bytes_sent_ = 0;
if (overflow) // Bug!
return ERR_UNEXPECTED;
// Done
return user_buf_len_;
}
// Send the remaining bytes.
next_state_ = STATE_PAYLOAD_WRITE;
return OK;
}
int SSLClientSocket::DidCompleteHandshake() {
SECURITY_STATUS status = SChannel()->QueryContextAttributes(
&ctxt_, SECPKG_ATTR_STREAM_SIZES, &stream_sizes_);
if (status != SEC_E_OK) {
DLOG(ERROR) << "QueryContextAttributes failed: " << status;
return ERR_FAILED;
}
completed_handshake_ = true;
return OK;
}
} // namespace net