transmission/libtransmission/peer-msgs.c

2757 lines
74 KiB
C

/*
* This file Copyright (C) 2007-2014 Mnemosyne LLC
*
* It may be used under the GNU GPL versions 2 or 3
* or any future license endorsed by Mnemosyne LLC.
*
*/
#include <errno.h>
#include <stdarg.h>
#include <stdlib.h>
#include <string.h>
#include <event2/buffer.h>
#include <event2/bufferevent.h>
#include <event2/event.h>
#include "transmission.h"
#include "cache.h"
#include "completion.h"
#include "file.h"
#include "log.h"
#include "peer-io.h"
#include "peer-mgr.h"
#include "peer-msgs.h"
#include "session.h"
#include "torrent.h"
#include "torrent-magnet.h"
#include "tr-assert.h"
#include "tr-dht.h"
#include "utils.h"
#include "variant.h"
#include "version.h"
#ifndef EBADMSG
#define EBADMSG EINVAL
#endif
/**
***
**/
enum
{
BT_CHOKE = 0,
BT_UNCHOKE = 1,
BT_INTERESTED = 2,
BT_NOT_INTERESTED = 3,
BT_HAVE = 4,
BT_BITFIELD = 5,
BT_REQUEST = 6,
BT_PIECE = 7,
BT_CANCEL = 8,
BT_PORT = 9,
/* */
BT_FEXT_SUGGEST = 13,
BT_FEXT_HAVE_ALL = 14,
BT_FEXT_HAVE_NONE = 15,
BT_FEXT_REJECT = 16,
BT_FEXT_ALLOWED_FAST = 17,
/* */
BT_LTEP = 20,
/* */
LTEP_HANDSHAKE = 0,
/* */
UT_PEX_ID = 1,
UT_METADATA_ID = 3,
/* */
MAX_PEX_PEER_COUNT = 50,
/* */
MIN_CHOKE_PERIOD_SEC = 10,
/* idle seconds before we send a keepalive */
KEEPALIVE_INTERVAL_SECS = 100,
/* */
PEX_INTERVAL_SECS = 90, /* sec between sendPex() calls */
/* */
REQQ = 512,
/* */
METADATA_REQQ = 64,
/* */
MAGIC_NUMBER = 21549,
/* used in lowering the outMessages queue period */
IMMEDIATE_PRIORITY_INTERVAL_SECS = 0,
HIGH_PRIORITY_INTERVAL_SECS = 2,
LOW_PRIORITY_INTERVAL_SECS = 10,
/* number of pieces we'll allow in our fast set */
MAX_FAST_SET_SIZE = 3,
/* how many blocks to keep prefetched per peer */
PREFETCH_SIZE = 18,
/* when we're making requests from another peer,
batch them together to send enough requests to
meet our bandwidth goals for the next N seconds */
REQUEST_BUF_SECS = 10,
/* defined in BEP #9 */
METADATA_MSG_TYPE_REQUEST = 0,
METADATA_MSG_TYPE_DATA = 1,
METADATA_MSG_TYPE_REJECT = 2
};
enum
{
AWAITING_BT_LENGTH,
AWAITING_BT_ID,
AWAITING_BT_MESSAGE,
AWAITING_BT_PIECE
};
typedef enum
{
ENCRYPTION_PREFERENCE_UNKNOWN,
ENCRYPTION_PREFERENCE_YES,
ENCRYPTION_PREFERENCE_NO
}
encryption_preference_t;
/**
***
**/
struct peer_request
{
uint32_t index;
uint32_t offset;
uint32_t length;
};
static void blockToReq(tr_torrent const* tor, tr_block_index_t block, struct peer_request* setme)
{
tr_torrentGetBlockLocation(tor, block, &setme->index, &setme->offset, &setme->length);
}
/**
***
**/
/* this is raw, unchanged data from the peer regarding
* the current message that it's sending us. */
struct tr_incoming
{
uint8_t id;
uint32_t length; /* includes the +1 for id length */
struct peer_request blockReq; /* metadata for incoming blocks */
struct evbuffer* block; /* piece data for incoming blocks */
};
/**
* Low-level communication state information about a connected peer.
*
* This structure remembers the low-level protocol states that we're
* in with this peer, such as active requests, pex messages, and so on.
* Its fields are all private to peer-msgs.c.
*
* Data not directly involved with sending & receiving messages is
* stored in tr_peer, where it can be accessed by both peermsgs and
* the peer manager.
*
* @see struct peer_atom
* @see tr_peer
*/
struct tr_peerMsgs
{
struct tr_peer peer; /* parent */
uint16_t magic_number;
/* Whether or not we've choked this peer. */
bool peer_is_choked;
/* whether or not the peer has indicated it will download from us. */
bool peer_is_interested;
/* whether or not the peer is choking us. */
bool client_is_choked;
/* whether or not we've indicated to the peer that we would download from them if unchoked. */
bool client_is_interested;
bool peerSupportsPex;
bool peerSupportsMetadataXfer;
bool clientSentLtepHandshake;
bool peerSentLtepHandshake;
int desiredRequestCount;
int prefetchCount;
bool is_active[2];
/* how long the outMessages batch should be allowed to grow before
* it's flushed -- some messages (like requests >:) should be sent
* very quickly; others aren't as urgent. */
int8_t outMessagesBatchPeriod;
uint8_t state;
uint8_t ut_pex_id;
uint8_t ut_metadata_id;
uint16_t pexCount;
uint16_t pexCount6;
tr_port dht_port;
encryption_preference_t encryption_preference;
size_t metadata_size_hint;
#if 0
size_t fastsetSize;
tr_piece_index_t fastset[MAX_FAST_SET_SIZE];
#endif
tr_torrent* torrent;
tr_peer_callback callback;
void* callbackData;
struct evbuffer* outMessages; /* all the non-piece messages */
struct peer_request peerAskedFor[REQQ];
int peerAskedForMetadata[METADATA_REQQ];
int peerAskedForMetadataCount;
tr_pex* pex;
tr_pex* pex6;
time_t clientSentAnythingAt;
time_t chokeChangedAt;
/* when we started batching the outMessages */
time_t outMessagesBatchedAt;
struct tr_incoming incoming;
/* if the peer supports the Extension Protocol in BEP 10 and
supplied a reqq argument, it's stored here. Otherwise, the
value is zero and should be ignored. */
int64_t reqq;
struct event* pexTimer;
struct tr_peerIo* io;
};
/**
***
**/
static inline tr_session* getSession(struct tr_peerMsgs* msgs)
{
return msgs->torrent->session;
}
/**
***
**/
static void myDebug(char const* file, int line, struct tr_peerMsgs const* msgs, char const* fmt, ...) TR_GNUC_PRINTF(4, 5);
static void myDebug(char const* file, int line, struct tr_peerMsgs const* msgs, char const* fmt, ...)
{
tr_sys_file_t const fp = tr_logGetFile();
if (fp != TR_BAD_SYS_FILE)
{
va_list args;
char timestr[64];
char addrstr[TR_ADDRSTRLEN];
struct evbuffer* buf = evbuffer_new();
char* base = tr_sys_path_basename(file, NULL);
char* message;
evbuffer_add_printf(buf, "[%s] %s - %s [%s]: ",
tr_logGetTimeStr(timestr, sizeof(timestr)),
tr_torrentName(msgs->torrent),
tr_peerIoGetAddrStr(msgs->io, addrstr, sizeof(addrstr)),
tr_quark_get_string(msgs->peer.client, NULL));
va_start(args, fmt);
evbuffer_add_vprintf(buf, fmt, args);
va_end(args);
evbuffer_add_printf(buf, " (%s:%d)", base, line);
message = evbuffer_free_to_str(buf, NULL);
tr_sys_file_write_line(fp, message, NULL);
tr_free(base);
tr_free(message);
}
}
#define dbgmsg(msgs, ...) \
do \
{ \
if (tr_logGetDeepEnabled()) \
{ \
myDebug(__FILE__, __LINE__, msgs, __VA_ARGS__); \
} \
} \
while (0)
/**
***
**/
static void pokeBatchPeriod(tr_peerMsgs* msgs, int interval)
{
if (msgs->outMessagesBatchPeriod > interval)
{
msgs->outMessagesBatchPeriod = interval;
dbgmsg(msgs, "lowering batch interval to %d seconds", interval);
}
}
static void dbgOutMessageLen(tr_peerMsgs* msgs)
{
dbgmsg(msgs, "outMessage size is now %zu", evbuffer_get_length(msgs->outMessages));
}
static void protocolSendReject(tr_peerMsgs* msgs, struct peer_request const* req)
{
TR_ASSERT(tr_peerIoSupportsFEXT(msgs->io));
struct evbuffer* out = msgs->outMessages;
evbuffer_add_uint32(out, sizeof(uint8_t) + 3 * sizeof(uint32_t));
evbuffer_add_uint8(out, BT_FEXT_REJECT);
evbuffer_add_uint32(out, req->index);
evbuffer_add_uint32(out, req->offset);
evbuffer_add_uint32(out, req->length);
dbgmsg(msgs, "rejecting %u:%u->%u...", req->index, req->offset, req->length);
dbgOutMessageLen(msgs);
}
static void protocolSendRequest(tr_peerMsgs* msgs, struct peer_request const* req)
{
struct evbuffer* out = msgs->outMessages;
evbuffer_add_uint32(out, sizeof(uint8_t) + 3 * sizeof(uint32_t));
evbuffer_add_uint8(out, BT_REQUEST);
evbuffer_add_uint32(out, req->index);
evbuffer_add_uint32(out, req->offset);
evbuffer_add_uint32(out, req->length);
dbgmsg(msgs, "requesting %u:%u->%u...", req->index, req->offset, req->length);
dbgOutMessageLen(msgs);
pokeBatchPeriod(msgs, IMMEDIATE_PRIORITY_INTERVAL_SECS);
}
static void protocolSendCancel(tr_peerMsgs* msgs, struct peer_request const* req)
{
struct evbuffer* out = msgs->outMessages;
evbuffer_add_uint32(out, sizeof(uint8_t) + 3 * sizeof(uint32_t));
evbuffer_add_uint8(out, BT_CANCEL);
evbuffer_add_uint32(out, req->index);
evbuffer_add_uint32(out, req->offset);
evbuffer_add_uint32(out, req->length);
dbgmsg(msgs, "cancelling %u:%u->%u...", req->index, req->offset, req->length);
dbgOutMessageLen(msgs);
pokeBatchPeriod(msgs, IMMEDIATE_PRIORITY_INTERVAL_SECS);
}
static void protocolSendPort(tr_peerMsgs* msgs, uint16_t port)
{
struct evbuffer* out = msgs->outMessages;
dbgmsg(msgs, "sending Port %u", port);
evbuffer_add_uint32(out, 3);
evbuffer_add_uint8(out, BT_PORT);
evbuffer_add_uint16(out, port);
}
static void protocolSendHave(tr_peerMsgs* msgs, uint32_t index)
{
struct evbuffer* out = msgs->outMessages;
evbuffer_add_uint32(out, sizeof(uint8_t) + sizeof(uint32_t));
evbuffer_add_uint8(out, BT_HAVE);
evbuffer_add_uint32(out, index);
dbgmsg(msgs, "sending Have %u", index);
dbgOutMessageLen(msgs);
pokeBatchPeriod(msgs, LOW_PRIORITY_INTERVAL_SECS);
}
#if 0
static void protocolSendAllowedFast(tr_peerMsgs* msgs, uint32_t pieceIndex)
{
TR_ASSERT(tr_peerIoSupportsFEXT(msgs->io));
tr_peerIo* io = msgs->io;
struct evbuffer* out = msgs->outMessages;
evbuffer_add_uint32(io, out, sizeof(uint8_t) + sizeof(uint32_t));
evbuffer_add_uint8(io, out, BT_FEXT_ALLOWED_FAST);
evbuffer_add_uint32(io, out, pieceIndex);
dbgmsg(msgs, "sending Allowed Fast %u...", pieceIndex);
dbgOutMessageLen(msgs);
}
#endif
static void protocolSendChoke(tr_peerMsgs* msgs, bool choke)
{
struct evbuffer* out = msgs->outMessages;
evbuffer_add_uint32(out, sizeof(uint8_t));
evbuffer_add_uint8(out, choke ? BT_CHOKE : BT_UNCHOKE);
dbgmsg(msgs, "sending %s...", choke ? "Choke" : "Unchoke");
dbgOutMessageLen(msgs);
pokeBatchPeriod(msgs, IMMEDIATE_PRIORITY_INTERVAL_SECS);
}
static void protocolSendHaveAll(tr_peerMsgs* msgs)
{
TR_ASSERT(tr_peerIoSupportsFEXT(msgs->io));
struct evbuffer* out = msgs->outMessages;
evbuffer_add_uint32(out, sizeof(uint8_t));
evbuffer_add_uint8(out, BT_FEXT_HAVE_ALL);
dbgmsg(msgs, "sending HAVE_ALL...");
dbgOutMessageLen(msgs);
pokeBatchPeriod(msgs, IMMEDIATE_PRIORITY_INTERVAL_SECS);
}
static void protocolSendHaveNone(tr_peerMsgs* msgs)
{
TR_ASSERT(tr_peerIoSupportsFEXT(msgs->io));
struct evbuffer* out = msgs->outMessages;
evbuffer_add_uint32(out, sizeof(uint8_t));
evbuffer_add_uint8(out, BT_FEXT_HAVE_NONE);
dbgmsg(msgs, "sending HAVE_NONE...");
dbgOutMessageLen(msgs);
pokeBatchPeriod(msgs, IMMEDIATE_PRIORITY_INTERVAL_SECS);
}
/**
*** EVENTS
**/
static void publish(tr_peerMsgs* msgs, tr_peer_event* e)
{
if (msgs->callback != NULL)
{
(*msgs->callback)(&msgs->peer, e, msgs->callbackData);
}
}
static void fireError(tr_peerMsgs* msgs, int err)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.eventType = TR_PEER_ERROR;
e.err = err;
publish(msgs, &e);
}
static void fireGotBlock(tr_peerMsgs* msgs, struct peer_request const* req)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.eventType = TR_PEER_CLIENT_GOT_BLOCK;
e.pieceIndex = req->index;
e.offset = req->offset;
e.length = req->length;
publish(msgs, &e);
}
static void fireGotRej(tr_peerMsgs* msgs, struct peer_request const* req)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.eventType = TR_PEER_CLIENT_GOT_REJ;
e.pieceIndex = req->index;
e.offset = req->offset;
e.length = req->length;
publish(msgs, &e);
}
static void fireGotChoke(tr_peerMsgs* msgs)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.eventType = TR_PEER_CLIENT_GOT_CHOKE;
publish(msgs, &e);
}
static void fireClientGotHaveAll(tr_peerMsgs* msgs)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.eventType = TR_PEER_CLIENT_GOT_HAVE_ALL;
publish(msgs, &e);
}
static void fireClientGotHaveNone(tr_peerMsgs* msgs)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.eventType = TR_PEER_CLIENT_GOT_HAVE_NONE;
publish(msgs, &e);
}
static void fireClientGotPieceData(tr_peerMsgs* msgs, uint32_t length)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.length = length;
e.eventType = TR_PEER_CLIENT_GOT_PIECE_DATA;
publish(msgs, &e);
}
static void firePeerGotPieceData(tr_peerMsgs* msgs, uint32_t length)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.length = length;
e.eventType = TR_PEER_PEER_GOT_PIECE_DATA;
publish(msgs, &e);
}
static void fireClientGotSuggest(tr_peerMsgs* msgs, uint32_t pieceIndex)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.eventType = TR_PEER_CLIENT_GOT_SUGGEST;
e.pieceIndex = pieceIndex;
publish(msgs, &e);
}
static void fireClientGotPort(tr_peerMsgs* msgs, tr_port port)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.eventType = TR_PEER_CLIENT_GOT_PORT;
e.port = port;
publish(msgs, &e);
}
static void fireClientGotAllowedFast(tr_peerMsgs* msgs, uint32_t pieceIndex)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.eventType = TR_PEER_CLIENT_GOT_ALLOWED_FAST;
e.pieceIndex = pieceIndex;
publish(msgs, &e);
}
static void fireClientGotBitfield(tr_peerMsgs* msgs, tr_bitfield* bitfield)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.eventType = TR_PEER_CLIENT_GOT_BITFIELD;
e.bitfield = bitfield;
publish(msgs, &e);
}
static void fireClientGotHave(tr_peerMsgs* msgs, tr_piece_index_t index)
{
tr_peer_event e = TR_PEER_EVENT_INIT;
e.eventType = TR_PEER_CLIENT_GOT_HAVE;
e.pieceIndex = index;
publish(msgs, &e);
}
/**
*** ALLOWED FAST SET
*** For explanation, see http://www.bittorrent.org/beps/bep_0006.html
**/
#if 0
size_t tr_generateAllowedSet(tr_piece_index_t* setmePieces, size_t desiredSetSize, size_t pieceCount, uint8_t const* infohash,
tr_address const* addr)
{
TR_ASSERT(setmePieces != NULL);
TR_ASSERT(desiredSetSize <= pieceCount);
TR_ASSERT(desiredSetSize != 0);
TR_ASSERT(pieceCount != 0);
TR_ASSERT(infohash != NULL);
TR_ASSERT(addr != NULL);
size_t setSize = 0;
if (addr->type == TR_AF_INET)
{
uint8_t w[SHA_DIGEST_LENGTH + 4];
uint8_t* walk = w;
uint8_t x[SHA_DIGEST_LENGTH];
uint32_t ui32 = ntohl(htonl(addr->addr.addr4.s_addr) & 0xffffff00); /* (1) */
memcpy(w, &ui32, sizeof(uint32_t));
walk += sizeof(uint32_t);
memcpy(walk, infohash, SHA_DIGEST_LENGTH); /* (2) */
walk += SHA_DIGEST_LENGTH;
tr_sha1(x, w, walk - w, NULL); /* (3) */
TR_ASSERT(sizeof(w) == walk - w);
while (setSize < desiredSetSize)
{
for (int i = 0; i < 5 && setSize < desiredSetSize; ++i) /* (4) */
{
uint32_t j = i * 4; /* (5) */
uint32_t y = ntohl(*(uint32_t*)(x + j)); /* (6) */
uint32_t index = y % pieceCount; /* (7) */
bool found = false;
for (size_t k = 0; !found && k < setSize; ++k) /* (8) */
{
found = setmePieces[k] == index;
}
if (!found)
{
setmePieces[setSize++] = index; /* (9) */
}
}
tr_sha1(x, x, sizeof(x), NULL); /* (3) */
}
}
return setSize;
}
static void updateFastSet(tr_peerMsgs* msgs)
{
TR_UNUSED(msgs);
bool const fext = tr_peerIoSupportsFEXT(msgs->io);
bool const peerIsNeedy = msgs->peer->progress < 0.10;
if (fext && peerIsNeedy && !msgs->haveFastSet)
{
struct tr_address const* addr = tr_peerIoGetAddress(msgs->io, NULL);
tr_info const* inf = &msgs->torrent->info;
size_t const numwant = MIN(MAX_FAST_SET_SIZE, inf->pieceCount);
/* build the fast set */
msgs->fastsetSize = tr_generateAllowedSet(msgs->fastset, numwant, inf->pieceCount, inf->hash, addr);
msgs->haveFastSet = true;
/* send it to the peer */
for (size_t i = 0; i < msgs->fastsetSize; ++i)
{
protocolSendAllowedFast(msgs, msgs->fastset[i]);
}
}
}
#endif
/***
**** ACTIVE
***/
static bool tr_peerMsgsCalculateActive(tr_peerMsgs const* msgs, tr_direction direction)
{
TR_ASSERT(tr_isPeerMsgs(msgs));
TR_ASSERT(tr_isDirection(direction));
bool is_active;
if (direction == TR_CLIENT_TO_PEER)
{
is_active = tr_peerMsgsIsPeerInterested(msgs) && !tr_peerMsgsIsPeerChoked(msgs);
}
else /* TR_PEER_TO_CLIENT */
{
if (!tr_torrentHasMetadata(msgs->torrent))
{
is_active = true;
}
else
{
is_active = tr_peerMsgsIsClientInterested(msgs) && !tr_peerMsgsIsClientChoked(msgs);
if (is_active)
{
TR_ASSERT(!tr_torrentIsSeed(msgs->torrent));
}
}
}
return is_active;
}
bool tr_peerMsgsIsActive(tr_peerMsgs const* msgs, tr_direction direction)
{
TR_ASSERT(tr_isPeerMsgs(msgs));
TR_ASSERT(tr_isDirection(direction));
bool is_active = msgs->is_active[direction];
TR_ASSERT(is_active == tr_peerMsgsCalculateActive(msgs, direction));
return is_active;
}
static void tr_peerMsgsSetActive(tr_peerMsgs* msgs, tr_direction direction, bool is_active)
{
dbgmsg(msgs, "direction [%d] is_active [%d]", (int)direction, (int)is_active);
if (msgs->is_active[direction] != is_active)
{
msgs->is_active[direction] = is_active;
tr_swarmIncrementActivePeers(msgs->torrent->swarm, direction, is_active);
}
}
void tr_peerMsgsUpdateActive(tr_peerMsgs* msgs, tr_direction direction)
{
bool const is_active = tr_peerMsgsCalculateActive(msgs, direction);
tr_peerMsgsSetActive(msgs, direction, is_active);
}
/**
*** INTEREST
**/
static void sendInterest(tr_peerMsgs* msgs, bool b)
{
TR_ASSERT(msgs != NULL);
struct evbuffer* out = msgs->outMessages;
msgs->client_is_interested = b;
dbgmsg(msgs, "Sending %s", b ? "Interested" : "Not Interested");
evbuffer_add_uint32(out, sizeof(uint8_t));
evbuffer_add_uint8(out, b ? BT_INTERESTED : BT_NOT_INTERESTED);
pokeBatchPeriod(msgs, HIGH_PRIORITY_INTERVAL_SECS);
dbgOutMessageLen(msgs);
}
static void updateInterest(tr_peerMsgs* msgs)
{
TR_UNUSED(msgs);
/* FIXME -- might need to poke the mgr on startup */
}
void tr_peerMsgsSetInterested(tr_peerMsgs* msgs, bool b)
{
if (msgs->client_is_interested != b)
{
sendInterest(msgs, b);
tr_peerMsgsUpdateActive(msgs, TR_PEER_TO_CLIENT);
}
}
static bool popNextMetadataRequest(tr_peerMsgs* msgs, int* piece)
{
if (msgs->peerAskedForMetadataCount == 0)
{
return false;
}
*piece = msgs->peerAskedForMetadata[0];
tr_removeElementFromArray(msgs->peerAskedForMetadata, 0, sizeof(int), msgs->peerAskedForMetadataCount);
--msgs->peerAskedForMetadataCount;
return true;
}
static bool popNextRequest(tr_peerMsgs* msgs, struct peer_request* setme)
{
if (msgs->peer.pendingReqsToClient == 0)
{
return false;
}
*setme = msgs->peerAskedFor[0];
tr_removeElementFromArray(msgs->peerAskedFor, 0, sizeof(struct peer_request), msgs->peer.pendingReqsToClient);
--msgs->peer.pendingReqsToClient;
return true;
}
static void cancelAllRequestsToClient(tr_peerMsgs* msgs)
{
struct peer_request req;
bool const mustSendCancel = tr_peerIoSupportsFEXT(msgs->io);
while (popNextRequest(msgs, &req))
{
if (mustSendCancel)
{
protocolSendReject(msgs, &req);
}
}
}
void tr_peerMsgsSetChoke(tr_peerMsgs* msgs, bool peer_is_choked)
{
TR_ASSERT(msgs != NULL);
time_t const now = tr_time();
time_t const fibrillationTime = now - MIN_CHOKE_PERIOD_SEC;
if (msgs->chokeChangedAt > fibrillationTime)
{
dbgmsg(msgs, "Not changing choke to %d to avoid fibrillation", peer_is_choked);
}
else if (msgs->peer_is_choked != peer_is_choked)
{
msgs->peer_is_choked = peer_is_choked;
if (peer_is_choked)
{
cancelAllRequestsToClient(msgs);
}
protocolSendChoke(msgs, peer_is_choked);
msgs->chokeChangedAt = now;
tr_peerMsgsUpdateActive(msgs, TR_CLIENT_TO_PEER);
}
}
/**
***
**/
void tr_peerMsgsHave(tr_peerMsgs* msgs, uint32_t index)
{
protocolSendHave(msgs, index);
/* since we have more pieces now, we might not be interested in this peer */
updateInterest(msgs);
}
/**
***
**/
static bool reqIsValid(tr_peerMsgs const* peer, uint32_t index, uint32_t offset, uint32_t length)
{
return tr_torrentReqIsValid(peer->torrent, index, offset, length);
}
static bool requestIsValid(tr_peerMsgs const* msgs, struct peer_request const* req)
{
return reqIsValid(msgs, req->index, req->offset, req->length);
}
void tr_peerMsgsCancel(tr_peerMsgs* msgs, tr_block_index_t block)
{
struct peer_request req;
blockToReq(msgs->torrent, block, &req);
protocolSendCancel(msgs, &req);
}
/**
***
**/
static void sendLtepHandshake(tr_peerMsgs* msgs)
{
tr_variant val;
bool allow_pex;
struct evbuffer* payload;
struct evbuffer* out = msgs->outMessages;
unsigned char const* ipv6 = tr_globalIPv6();
static tr_quark version_quark = 0;
if (msgs->clientSentLtepHandshake)
{
return;
}
if (version_quark == 0)
{
version_quark = tr_quark_new(TR_NAME " " USERAGENT_PREFIX, TR_BAD_SIZE);
}
dbgmsg(msgs, "sending an ltep handshake");
msgs->clientSentLtepHandshake = true;
/* decide if we want to advertise metadata xfer support (BEP 9) */
bool const allow_metadata_xfer = !tr_torrentIsPrivate(msgs->torrent);
/* decide if we want to advertise pex support */
if (!tr_torrentAllowsPex(msgs->torrent))
{
allow_pex = false;
}
else if (msgs->peerSentLtepHandshake)
{
allow_pex = msgs->peerSupportsPex;
}
else
{
allow_pex = true;
}
tr_variantInitDict(&val, 8);
tr_variantDictAddBool(&val, TR_KEY_e, getSession(msgs)->encryptionMode != TR_CLEAR_PREFERRED);
if (ipv6 != NULL)
{
tr_variantDictAddRaw(&val, TR_KEY_ipv6, ipv6, 16);
}
if (allow_metadata_xfer && tr_torrentHasMetadata(msgs->torrent) && msgs->torrent->infoDictLength > 0)
{
tr_variantDictAddInt(&val, TR_KEY_metadata_size, msgs->torrent->infoDictLength);
}
tr_variantDictAddInt(&val, TR_KEY_p, tr_sessionGetPublicPeerPort(getSession(msgs)));
tr_variantDictAddInt(&val, TR_KEY_reqq, REQQ);
tr_variantDictAddBool(&val, TR_KEY_upload_only, tr_torrentIsSeed(msgs->torrent));
tr_variantDictAddQuark(&val, TR_KEY_v, version_quark);
if (allow_metadata_xfer || allow_pex)
{
tr_variant* m = tr_variantDictAddDict(&val, TR_KEY_m, 2);
if (allow_metadata_xfer)
{
tr_variantDictAddInt(m, TR_KEY_ut_metadata, UT_METADATA_ID);
}
if (allow_pex)
{
tr_variantDictAddInt(m, TR_KEY_ut_pex, UT_PEX_ID);
}
}
payload = tr_variantToBuf(&val, TR_VARIANT_FMT_BENC);
evbuffer_add_uint32(out, 2 * sizeof(uint8_t) + evbuffer_get_length(payload));
evbuffer_add_uint8(out, BT_LTEP);
evbuffer_add_uint8(out, LTEP_HANDSHAKE);
evbuffer_add_buffer(out, payload);
pokeBatchPeriod(msgs, IMMEDIATE_PRIORITY_INTERVAL_SECS);
dbgOutMessageLen(msgs);
/* cleanup */
evbuffer_free(payload);
tr_variantFree(&val);
}
static void parseLtepHandshake(tr_peerMsgs* msgs, uint32_t len, struct evbuffer* inbuf)
{
int64_t i;
tr_variant val;
tr_variant* sub;
uint8_t* tmp = tr_new(uint8_t, len);
uint8_t const* addr;
size_t addr_len;
tr_pex pex;
int8_t seedProbability = -1;
memset(&pex, 0, sizeof(tr_pex));
tr_peerIoReadBytes(msgs->io, inbuf, tmp, len);
msgs->peerSentLtepHandshake = true;
if (tr_variantFromBenc(&val, tmp, len) != 0 || !tr_variantIsDict(&val))
{
dbgmsg(msgs, "GET extended-handshake, couldn't get dictionary");
tr_free(tmp);
return;
}
/* arbitrary limit, should be more than enough */
if (len <= 4096)
{
dbgmsg(msgs, "here is the handshake: [%*.*s]", (int)len, (int)len, tmp);
}
else
{
dbgmsg(msgs, "handshake length is too big (%" PRIu32 "), printing skipped", len);
}
/* does the peer prefer encrypted connections? */
if (tr_variantDictFindInt(&val, TR_KEY_e, &i))
{
msgs->encryption_preference = i != 0 ? ENCRYPTION_PREFERENCE_YES : ENCRYPTION_PREFERENCE_NO;
if (i != 0)
{
pex.flags |= ADDED_F_ENCRYPTION_FLAG;
}
}
/* check supported messages for utorrent pex */
msgs->peerSupportsPex = false;
msgs->peerSupportsMetadataXfer = false;
if (tr_variantDictFindDict(&val, TR_KEY_m, &sub))
{
if (tr_variantDictFindInt(sub, TR_KEY_ut_pex, &i))
{
msgs->peerSupportsPex = i != 0;
msgs->ut_pex_id = (uint8_t)i;
dbgmsg(msgs, "msgs->ut_pex is %d", (int)msgs->ut_pex_id);
}
if (tr_variantDictFindInt(sub, TR_KEY_ut_metadata, &i))
{
msgs->peerSupportsMetadataXfer = i != 0;
msgs->ut_metadata_id = (uint8_t)i;
dbgmsg(msgs, "msgs->ut_metadata_id is %d", (int)msgs->ut_metadata_id);
}
if (tr_variantDictFindInt(sub, TR_KEY_ut_holepunch, &i))
{
/* Mysterious µTorrent extension that we don't grok. However,
it implies support for µTP, so use it to indicate that. */
tr_peerMgrSetUtpFailed(msgs->torrent, tr_peerIoGetAddress(msgs->io, NULL), false);
}
}
/* look for metainfo size (BEP 9) */
if (tr_variantDictFindInt(&val, TR_KEY_metadata_size, &i) &&
tr_torrentSetMetadataSizeHint(msgs->torrent, i))
{
msgs->metadata_size_hint = (size_t)i;
}
/* look for upload_only (BEP 21) */
if (tr_variantDictFindInt(&val, TR_KEY_upload_only, &i))
{
seedProbability = i == 0 ? 0 : 100;
}
/* get peer's listening port */
if (tr_variantDictFindInt(&val, TR_KEY_p, &i))
{
pex.port = htons((uint16_t)i);
fireClientGotPort(msgs, pex.port);
dbgmsg(msgs, "peer's port is now %d", (int)i);
}
if (tr_peerIoIsIncoming(msgs->io) &&
tr_variantDictFindRaw(&val, TR_KEY_ipv4, &addr, &addr_len) &&
addr_len == 4)
{
pex.addr.type = TR_AF_INET;
memcpy(&pex.addr.addr.addr4, addr, 4);
tr_peerMgrAddPex(msgs->torrent, TR_PEER_FROM_LTEP, &pex, seedProbability);
}
if (tr_peerIoIsIncoming(msgs->io) &&
tr_variantDictFindRaw(&val, TR_KEY_ipv6, &addr, &addr_len) &&
addr_len == 16)
{
pex.addr.type = TR_AF_INET6;
memcpy(&pex.addr.addr.addr6, addr, 16);
tr_peerMgrAddPex(msgs->torrent, TR_PEER_FROM_LTEP, &pex, seedProbability);
}
/* get peer's maximum request queue size */
if (tr_variantDictFindInt(&val, TR_KEY_reqq, &i))
{
msgs->reqq = i;
}
tr_variantFree(&val);
tr_free(tmp);
}
static void parseUtMetadata(tr_peerMsgs* msgs, uint32_t msglen, struct evbuffer* inbuf)
{
int64_t msg_type = -1;
int64_t piece = -1;
int64_t total_size = 0;
uint8_t* const tmp = tr_new(uint8_t, msglen);
tr_peerIoReadBytes(msgs->io, inbuf, tmp, msglen);
char const* const msg_end = (char const*)tmp + msglen;
tr_variant dict;
char const* benc_end;
if (tr_variantFromBencFull(&dict, tmp, msglen, NULL, &benc_end) == 0)
{
(void)tr_variantDictFindInt(&dict, TR_KEY_msg_type, &msg_type);
(void)tr_variantDictFindInt(&dict, TR_KEY_piece, &piece);
(void)tr_variantDictFindInt(&dict, TR_KEY_total_size, &total_size);
tr_variantFree(&dict);
}
dbgmsg(msgs, "got ut_metadata msg: type %d, piece %d, total_size %d", (int)msg_type, (int)piece, (int)total_size);
if (msg_type == METADATA_MSG_TYPE_REJECT)
{
/* NOOP */
}
if (msg_type == METADATA_MSG_TYPE_DATA && !tr_torrentHasMetadata(msgs->torrent) &&
msg_end - benc_end <= METADATA_PIECE_SIZE && piece * METADATA_PIECE_SIZE + (msg_end - benc_end) <= total_size)
{
int const pieceLen = msg_end - benc_end;
tr_torrentSetMetadataPiece(msgs->torrent, piece, benc_end, pieceLen);
}
if (msg_type == METADATA_MSG_TYPE_REQUEST)
{
if (piece >= 0 && tr_torrentHasMetadata(msgs->torrent) && !tr_torrentIsPrivate(msgs->torrent) &&
msgs->peerAskedForMetadataCount < METADATA_REQQ)
{
msgs->peerAskedForMetadata[msgs->peerAskedForMetadataCount++] = piece;
}
else
{
tr_variant v;
struct evbuffer* payload;
struct evbuffer* out = msgs->outMessages;
/* build the rejection message */
tr_variantInitDict(&v, 2);
tr_variantDictAddInt(&v, TR_KEY_msg_type, METADATA_MSG_TYPE_REJECT);
tr_variantDictAddInt(&v, TR_KEY_piece, piece);
payload = tr_variantToBuf(&v, TR_VARIANT_FMT_BENC);
/* write it out as a LTEP message to our outMessages buffer */
evbuffer_add_uint32(out, 2 * sizeof(uint8_t) + evbuffer_get_length(payload));
evbuffer_add_uint8(out, BT_LTEP);
evbuffer_add_uint8(out, msgs->ut_metadata_id);
evbuffer_add_buffer(out, payload);
pokeBatchPeriod(msgs, HIGH_PRIORITY_INTERVAL_SECS);
dbgOutMessageLen(msgs);
/* cleanup */
evbuffer_free(payload);
tr_variantFree(&v);
}
}
tr_free(tmp);
}
static void parseUtPex(tr_peerMsgs* msgs, uint32_t msglen, struct evbuffer* inbuf)
{
tr_torrent* tor = msgs->torrent;
if (!tr_torrentAllowsPex(tor))
{
return;
}
uint8_t* tmp = tr_new(uint8_t, msglen);
tr_peerIoReadBytes(msgs->io, inbuf, tmp, msglen);
tr_variant val;
bool const loaded = tr_variantFromBenc(&val, tmp, msglen) == 0;
tr_free(tmp);
if (!loaded)
{
return;
}
uint8_t const* added;
size_t added_len;
if (tr_variantDictFindRaw(&val, TR_KEY_added, &added, &added_len))
{
tr_pex* pex;
size_t n;
size_t added_f_len;
uint8_t const* added_f;
if (!tr_variantDictFindRaw(&val, TR_KEY_added_f, &added_f, &added_f_len))
{
added_f_len = 0;
added_f = NULL;
}
pex = tr_peerMgrCompactToPex(added, added_len, added_f, added_f_len, &n);
n = MIN(n, MAX_PEX_PEER_COUNT);
for (size_t i = 0; i < n; ++i)
{
int seedProbability = -1;
if (i < added_f_len)
{
seedProbability = (added_f[i] & ADDED_F_SEED_FLAG) != 0 ? 100 : 0;
}
tr_peerMgrAddPex(tor, TR_PEER_FROM_PEX, pex + i, seedProbability);
}
tr_free(pex);
}
if (tr_variantDictFindRaw(&val, TR_KEY_added6, &added, &added_len))
{
tr_pex* pex;
size_t n;
size_t added_f_len;
uint8_t const* added_f;
if (!tr_variantDictFindRaw(&val, TR_KEY_added6_f, &added_f, &added_f_len))
{
added_f_len = 0;
added_f = NULL;
}
pex = tr_peerMgrCompact6ToPex(added, added_len, added_f, added_f_len, &n);
n = MIN(n, MAX_PEX_PEER_COUNT);
for (size_t i = 0; i < n; ++i)
{
int seedProbability = -1;
if (i < added_f_len)
{
seedProbability = (added_f[i] & ADDED_F_SEED_FLAG) != 0 ? 100 : 0;
}
tr_peerMgrAddPex(tor, TR_PEER_FROM_PEX, pex + i, seedProbability);
}
tr_free(pex);
}
tr_variantFree(&val);
}
static void sendPex(tr_peerMsgs* msgs);
static void parseLtep(tr_peerMsgs* msgs, uint32_t msglen, struct evbuffer* inbuf)
{
TR_ASSERT(msglen > 0);
uint8_t ltep_msgid;
tr_peerIoReadUint8(msgs->io, inbuf, &ltep_msgid);
msglen--;
if (ltep_msgid == LTEP_HANDSHAKE)
{
dbgmsg(msgs, "got ltep handshake");
parseLtepHandshake(msgs, msglen, inbuf);
if (tr_peerIoSupportsLTEP(msgs->io))
{
sendLtepHandshake(msgs);
sendPex(msgs);
}
}
else if (ltep_msgid == UT_PEX_ID)
{
dbgmsg(msgs, "got ut pex");
msgs->peerSupportsPex = true;
parseUtPex(msgs, msglen, inbuf);
}
else if (ltep_msgid == UT_METADATA_ID)
{
dbgmsg(msgs, "got ut metadata");
msgs->peerSupportsMetadataXfer = true;
parseUtMetadata(msgs, msglen, inbuf);
}
else
{
dbgmsg(msgs, "skipping unknown ltep message (%d)", (int)ltep_msgid);
evbuffer_drain(inbuf, msglen);
}
}
static int readBtLength(tr_peerMsgs* msgs, struct evbuffer* inbuf, size_t inlen)
{
uint32_t len;
if (inlen < sizeof(len))
{
return READ_LATER;
}
tr_peerIoReadUint32(msgs->io, inbuf, &len);
if (len == 0) /* peer sent us a keepalive message */
{
dbgmsg(msgs, "got KeepAlive");
}
else
{
msgs->incoming.length = len;
msgs->state = AWAITING_BT_ID;
}
return READ_NOW;
}
static int readBtMessage(tr_peerMsgs*, struct evbuffer*, size_t);
static int readBtId(tr_peerMsgs* msgs, struct evbuffer* inbuf, size_t inlen)
{
uint8_t id;
if (inlen < sizeof(uint8_t))
{
return READ_LATER;
}
tr_peerIoReadUint8(msgs->io, inbuf, &id);
msgs->incoming.id = id;
dbgmsg(msgs, "msgs->incoming.id is now %d; msgs->incoming.length is %zu", id, (size_t)msgs->incoming.length);
if (id == BT_PIECE)
{
msgs->state = AWAITING_BT_PIECE;
return READ_NOW;
}
else if (msgs->incoming.length != 1)
{
msgs->state = AWAITING_BT_MESSAGE;
return READ_NOW;
}
else
{
return readBtMessage(msgs, inbuf, inlen - 1);
}
}
static void updatePeerProgress(tr_peerMsgs* msgs)
{
tr_peerUpdateProgress(msgs->torrent, &msgs->peer);
updateInterest(msgs);
}
static void prefetchPieces(tr_peerMsgs* msgs)
{
if (!getSession(msgs)->isPrefetchEnabled)
{
return;
}
for (int i = msgs->prefetchCount; i < msgs->peer.pendingReqsToClient && i < PREFETCH_SIZE; ++i)
{
struct peer_request const* req = msgs->peerAskedFor + i;
if (requestIsValid(msgs, req))
{
tr_cachePrefetchBlock(getSession(msgs)->cache, msgs->torrent, req->index, req->offset, req->length);
++msgs->prefetchCount;
}
}
}
static void peerMadeRequest(tr_peerMsgs* msgs, struct peer_request const* req)
{
bool const fext = tr_peerIoSupportsFEXT(msgs->io);
bool const reqIsValid = requestIsValid(msgs, req);
bool const clientHasPiece = reqIsValid && tr_torrentPieceIsComplete(msgs->torrent, req->index);
bool const peerIsChoked = msgs->peer_is_choked;
bool allow = false;
if (!reqIsValid)
{
dbgmsg(msgs, "rejecting an invalid request.");
}
else if (!clientHasPiece)
{
dbgmsg(msgs, "rejecting request for a piece we don't have.");
}
else if (peerIsChoked)
{
dbgmsg(msgs, "rejecting request from choked peer");
}
else if (msgs->peer.pendingReqsToClient + 1 >= REQQ)
{
dbgmsg(msgs, "rejecting request ... reqq is full");
}
else
{
allow = true;
}
if (allow)
{
msgs->peerAskedFor[msgs->peer.pendingReqsToClient++] = *req;
prefetchPieces(msgs);
}
else if (fext)
{
protocolSendReject(msgs, req);
}
}
static bool messageLengthIsCorrect(tr_peerMsgs const* msg, uint8_t id, uint32_t len)
{
switch (id)
{
case BT_CHOKE:
case BT_UNCHOKE:
case BT_INTERESTED:
case BT_NOT_INTERESTED:
case BT_FEXT_HAVE_ALL:
case BT_FEXT_HAVE_NONE:
return len == 1;
case BT_HAVE:
case BT_FEXT_SUGGEST:
case BT_FEXT_ALLOWED_FAST:
return len == 5;
case BT_BITFIELD:
if (tr_torrentHasMetadata(msg->torrent))
{
return len == (msg->torrent->info.pieceCount >> 3) + ((msg->torrent->info.pieceCount & 7) != 0 ? 1 : 0) + 1U;
}
/* we don't know the piece count yet,
so we can only guess whether to send true or false */
if (msg->metadata_size_hint > 0)
{
return len <= msg->metadata_size_hint;
}
return true;
case BT_REQUEST:
case BT_CANCEL:
case BT_FEXT_REJECT:
return len == 13;
case BT_PIECE:
return len > 9 && len <= 16393;
case BT_PORT:
return len == 3;
case BT_LTEP:
return len >= 2;
default:
return false;
}
}
static int clientGotBlock(tr_peerMsgs* msgs, struct evbuffer* block, struct peer_request const* req);
static int readBtPiece(tr_peerMsgs* msgs, struct evbuffer* inbuf, size_t inlen, size_t* setme_piece_bytes_read)
{
TR_ASSERT(evbuffer_get_length(inbuf) >= inlen);
dbgmsg(msgs, "In readBtPiece");
struct peer_request* req = &msgs->incoming.blockReq;
if (req->length == 0)
{
if (inlen < 8)
{
return READ_LATER;
}
tr_peerIoReadUint32(msgs->io, inbuf, &req->index);
tr_peerIoReadUint32(msgs->io, inbuf, &req->offset);
req->length = msgs->incoming.length - 9;
dbgmsg(msgs, "got incoming block header %u:%u->%u", req->index, req->offset, req->length);
return READ_NOW;
}
else
{
int err;
size_t n;
size_t nLeft;
struct evbuffer* block_buffer;
if (msgs->incoming.block == NULL)
{
msgs->incoming.block = evbuffer_new();
}
block_buffer = msgs->incoming.block;
/* read in another chunk of data */
nLeft = req->length - evbuffer_get_length(block_buffer);
n = MIN(nLeft, inlen);
tr_peerIoReadBytesToBuf(msgs->io, inbuf, block_buffer, n);
fireClientGotPieceData(msgs, n);
*setme_piece_bytes_read += n;
dbgmsg(msgs, "got %zu bytes for block %u:%u->%u ... %d remain", n, req->index, req->offset, req->length,
(int)(req->length - evbuffer_get_length(block_buffer)));
if (evbuffer_get_length(block_buffer) < req->length)
{
return READ_LATER;
}
/* pass the block along... */
err = clientGotBlock(msgs, block_buffer, req);
evbuffer_drain(block_buffer, evbuffer_get_length(block_buffer));
/* cleanup */
req->length = 0;
msgs->state = AWAITING_BT_LENGTH;
return err != 0 ? READ_ERR : READ_NOW;
}
}
static void updateDesiredRequestCount(tr_peerMsgs* msgs);
static int readBtMessage(tr_peerMsgs* msgs, struct evbuffer* inbuf, size_t inlen)
{
uint8_t const id = msgs->incoming.id;
#ifdef TR_ENABLE_ASSERTS
size_t const startBufLen = evbuffer_get_length(inbuf);
#endif
bool const fext = tr_peerIoSupportsFEXT(msgs->io);
uint32_t ui32;
uint32_t msglen = msgs->incoming.length;
TR_ASSERT(msglen > 0);
--msglen; /* id length */
dbgmsg(msgs, "got BT id %d, len %d, buffer size is %zu", (int)id, (int)msglen, inlen);
if (inlen < msglen)
{
return READ_LATER;
}
if (!messageLengthIsCorrect(msgs, id, msglen + 1))
{
dbgmsg(msgs, "bad packet - BT message #%d with a length of %d", (int)id, (int)msglen);
fireError(msgs, EMSGSIZE);
return READ_ERR;
}
switch (id)
{
case BT_CHOKE:
dbgmsg(msgs, "got Choke");
msgs->client_is_choked = true;
if (!fext)
{
fireGotChoke(msgs);
}
tr_peerMsgsUpdateActive(msgs, TR_PEER_TO_CLIENT);
break;
case BT_UNCHOKE:
dbgmsg(msgs, "got Unchoke");
msgs->client_is_choked = false;
tr_peerMsgsUpdateActive(msgs, TR_PEER_TO_CLIENT);
updateDesiredRequestCount(msgs);
break;
case BT_INTERESTED:
dbgmsg(msgs, "got Interested");
msgs->peer_is_interested = true;
tr_peerMsgsUpdateActive(msgs, TR_CLIENT_TO_PEER);
break;
case BT_NOT_INTERESTED:
dbgmsg(msgs, "got Not Interested");
msgs->peer_is_interested = false;
tr_peerMsgsUpdateActive(msgs, TR_CLIENT_TO_PEER);
break;
case BT_HAVE:
tr_peerIoReadUint32(msgs->io, inbuf, &ui32);
dbgmsg(msgs, "got Have: %u", ui32);
if (tr_torrentHasMetadata(msgs->torrent) && ui32 >= msgs->torrent->info.pieceCount)
{
fireError(msgs, ERANGE);
return READ_ERR;
}
/* a peer can send the same HAVE message twice... */
if (!tr_bitfieldHas(&msgs->peer.have, ui32))
{
tr_bitfieldAdd(&msgs->peer.have, ui32);
fireClientGotHave(msgs, ui32);
}
updatePeerProgress(msgs);
break;
case BT_BITFIELD:
{
uint8_t* tmp = tr_new(uint8_t, msglen);
dbgmsg(msgs, "got a bitfield");
tr_peerIoReadBytes(msgs->io, inbuf, tmp, msglen);
tr_bitfieldSetRaw(&msgs->peer.have, tmp, msglen, tr_torrentHasMetadata(msgs->torrent));
fireClientGotBitfield(msgs, &msgs->peer.have);
updatePeerProgress(msgs);
tr_free(tmp);
break;
}
case BT_REQUEST:
{
struct peer_request r;
tr_peerIoReadUint32(msgs->io, inbuf, &r.index);
tr_peerIoReadUint32(msgs->io, inbuf, &r.offset);
tr_peerIoReadUint32(msgs->io, inbuf, &r.length);
dbgmsg(msgs, "got Request: %u:%u->%u", r.index, r.offset, r.length);
peerMadeRequest(msgs, &r);
break;
}
case BT_CANCEL:
{
struct peer_request r;
tr_peerIoReadUint32(msgs->io, inbuf, &r.index);
tr_peerIoReadUint32(msgs->io, inbuf, &r.offset);
tr_peerIoReadUint32(msgs->io, inbuf, &r.length);
tr_historyAdd(&msgs->peer.cancelsSentToClient, tr_time(), 1);
dbgmsg(msgs, "got a Cancel %u:%u->%u", r.index, r.offset, r.length);
for (int i = 0; i < msgs->peer.pendingReqsToClient; ++i)
{
struct peer_request const* req = msgs->peerAskedFor + i;
if (req->index == r.index && req->offset == r.offset && req->length == r.length)
{
tr_removeElementFromArray(msgs->peerAskedFor, i, sizeof(struct peer_request),
msgs->peer.pendingReqsToClient);
--msgs->peer.pendingReqsToClient;
break;
}
}
break;
}
case BT_PIECE:
TR_ASSERT(false); /* handled elsewhere! */
break;
case BT_PORT:
dbgmsg(msgs, "Got a BT_PORT");
tr_peerIoReadUint16(msgs->io, inbuf, &msgs->dht_port);
if (msgs->dht_port > 0)
{
tr_dhtAddNode(getSession(msgs), tr_peerAddress(&msgs->peer), msgs->dht_port, false);
}
break;
case BT_FEXT_SUGGEST:
dbgmsg(msgs, "Got a BT_FEXT_SUGGEST");
tr_peerIoReadUint32(msgs->io, inbuf, &ui32);
if (fext)
{
fireClientGotSuggest(msgs, ui32);
}
else
{
fireError(msgs, EMSGSIZE);
return READ_ERR;
}
break;
case BT_FEXT_ALLOWED_FAST:
dbgmsg(msgs, "Got a BT_FEXT_ALLOWED_FAST");
tr_peerIoReadUint32(msgs->io, inbuf, &ui32);
if (fext)
{
fireClientGotAllowedFast(msgs, ui32);
}
else
{
fireError(msgs, EMSGSIZE);
return READ_ERR;
}
break;
case BT_FEXT_HAVE_ALL:
dbgmsg(msgs, "Got a BT_FEXT_HAVE_ALL");
if (fext)
{
tr_bitfieldSetHasAll(&msgs->peer.have);
TR_ASSERT(tr_bitfieldHasAll(&msgs->peer.have));
fireClientGotHaveAll(msgs);
updatePeerProgress(msgs);
}
else
{
fireError(msgs, EMSGSIZE);
return READ_ERR;
}
break;
case BT_FEXT_HAVE_NONE:
dbgmsg(msgs, "Got a BT_FEXT_HAVE_NONE");
if (fext)
{
tr_bitfieldSetHasNone(&msgs->peer.have);
fireClientGotHaveNone(msgs);
updatePeerProgress(msgs);
}
else
{
fireError(msgs, EMSGSIZE);
return READ_ERR;
}
break;
case BT_FEXT_REJECT:
{
struct peer_request r;
dbgmsg(msgs, "Got a BT_FEXT_REJECT");
tr_peerIoReadUint32(msgs->io, inbuf, &r.index);
tr_peerIoReadUint32(msgs->io, inbuf, &r.offset);
tr_peerIoReadUint32(msgs->io, inbuf, &r.length);
if (fext)
{
fireGotRej(msgs, &r);
}
else
{
fireError(msgs, EMSGSIZE);
return READ_ERR;
}
break;
}
case BT_LTEP:
dbgmsg(msgs, "Got a BT_LTEP");
parseLtep(msgs, msglen, inbuf);
break;
default:
dbgmsg(msgs, "peer sent us an UNKNOWN: %d", (int)id);
tr_peerIoDrain(msgs->io, inbuf, msglen);
break;
}
TR_ASSERT(msglen + 1 == msgs->incoming.length);
TR_ASSERT(evbuffer_get_length(inbuf) == startBufLen - msglen);
msgs->state = AWAITING_BT_LENGTH;
return READ_NOW;
}
/* returns 0 on success, or an errno on failure */
static int clientGotBlock(tr_peerMsgs* msgs, struct evbuffer* data, struct peer_request const* req)
{
TR_ASSERT(msgs != NULL);
TR_ASSERT(req != NULL);
int err;
tr_torrent* tor = msgs->torrent;
tr_block_index_t const block = _tr_block(tor, req->index, req->offset);
if (!requestIsValid(msgs, req))
{
dbgmsg(msgs, "dropping invalid block %u:%u->%u", req->index, req->offset, req->length);
return EBADMSG;
}
if (req->length != tr_torBlockCountBytes(msgs->torrent, block))
{
dbgmsg(msgs, "wrong block size -- expected %u, got %d", tr_torBlockCountBytes(msgs->torrent, block), req->length);
return EMSGSIZE;
}
dbgmsg(msgs, "got block %u:%u->%u", req->index, req->offset, req->length);
if (!tr_peerMgrDidPeerRequest(msgs->torrent, &msgs->peer, block))
{
dbgmsg(msgs, "we didn't ask for this message...");
return 0;
}
if (tr_torrentPieceIsComplete(msgs->torrent, req->index))
{
dbgmsg(msgs, "we did ask for this message, but the piece is already complete...");
return 0;
}
/**
*** Save the block
**/
if ((err = tr_cacheWriteBlock(getSession(msgs)->cache, tor, req->index, req->offset, req->length, data)) != 0)
{
return err;
}
tr_bitfieldAdd(&msgs->peer.blame, req->index);
fireGotBlock(msgs, req);
return 0;
}
static void peerPulse(void* vmsgs);
static void didWrite(tr_peerIo* io, size_t bytesWritten, bool wasPieceData, void* vmsgs)
{
tr_peerMsgs* msgs = vmsgs;
if (wasPieceData)
{
firePeerGotPieceData(msgs, bytesWritten);
}
if (tr_isPeerIo(io) && io->userData != NULL)
{
peerPulse(msgs);
}
}
static ReadState canRead(tr_peerIo* io, void* vmsgs, size_t* piece)
{
ReadState ret;
tr_peerMsgs* msgs = vmsgs;
struct evbuffer* in = tr_peerIoGetReadBuffer(io);
size_t const inlen = evbuffer_get_length(in);
dbgmsg(msgs, "canRead: inlen is %zu, msgs->state is %d", inlen, msgs->state);
if (inlen == 0)
{
ret = READ_LATER;
}
else if (msgs->state == AWAITING_BT_PIECE)
{
ret = readBtPiece(msgs, in, inlen, piece);
}
else
{
switch (msgs->state)
{
case AWAITING_BT_LENGTH:
ret = readBtLength(msgs, in, inlen);
break;
case AWAITING_BT_ID:
ret = readBtId(msgs, in, inlen);
break;
case AWAITING_BT_MESSAGE:
ret = readBtMessage(msgs, in, inlen);
break;
default:
ret = READ_ERR;
TR_ASSERT_MSG(false, "unhandled peer messages state %d", (int)msgs->state);
}
}
dbgmsg(msgs, "canRead: ret is %d", (int)ret);
return ret;
}
bool tr_peerMsgsIsReadingBlock(tr_peerMsgs const* msgs, tr_block_index_t block)
{
if (msgs->state != AWAITING_BT_PIECE)
{
return false;
}
return block == _tr_block(msgs->torrent, msgs->incoming.blockReq.index, msgs->incoming.blockReq.offset);
}
/**
***
**/
static void updateDesiredRequestCount(tr_peerMsgs* msgs)
{
tr_torrent const* const torrent = msgs->torrent;
/* there are lots of reasons we might not want to request any blocks... */
if (tr_torrentIsSeed(torrent) || !tr_torrentHasMetadata(torrent) || msgs->client_is_choked || !msgs->client_is_interested)
{
msgs->desiredRequestCount = 0;
}
else
{
int estimatedBlocksInPeriod;
unsigned int rate_Bps;
unsigned int irate_Bps;
int const floor = 4;
int const seconds = REQUEST_BUF_SECS;
uint64_t const now = tr_time_msec();
/* Get the rate limit we should use.
* FIXME: this needs to consider all the other peers as well... */
rate_Bps = tr_peerGetPieceSpeed_Bps(&msgs->peer, now, TR_PEER_TO_CLIENT);
if (tr_torrentUsesSpeedLimit(torrent, TR_PEER_TO_CLIENT))
{
rate_Bps = MIN(rate_Bps, tr_torrentGetSpeedLimit_Bps(torrent, TR_PEER_TO_CLIENT));
}
/* honor the session limits, if enabled */
if (tr_torrentUsesSessionLimits(torrent) &&
tr_sessionGetActiveSpeedLimit_Bps(torrent->session, TR_PEER_TO_CLIENT, &irate_Bps))
{
rate_Bps = MIN(rate_Bps, irate_Bps);
}
/* use this desired rate to figure out how
* many requests we should send to this peer */
estimatedBlocksInPeriod = (rate_Bps * seconds) / torrent->blockSize;
msgs->desiredRequestCount = MAX(floor, estimatedBlocksInPeriod);
/* honor the peer's maximum request count, if specified */
if ((msgs->reqq > 0) && (msgs->desiredRequestCount > msgs->reqq))
{
msgs->desiredRequestCount = msgs->reqq;
}
}
}
static void updateMetadataRequests(tr_peerMsgs* msgs, time_t now)
{
int piece;
if (msgs->peerSupportsMetadataXfer && tr_torrentGetNextMetadataRequest(msgs->torrent, now, &piece))
{
tr_variant tmp;
struct evbuffer* payload;
struct evbuffer* out = msgs->outMessages;
/* build the data message */
tr_variantInitDict(&tmp, 3);
tr_variantDictAddInt(&tmp, TR_KEY_msg_type, METADATA_MSG_TYPE_REQUEST);
tr_variantDictAddInt(&tmp, TR_KEY_piece, piece);
payload = tr_variantToBuf(&tmp, TR_VARIANT_FMT_BENC);
dbgmsg(msgs, "requesting metadata piece #%d", piece);
/* write it out as a LTEP message to our outMessages buffer */
evbuffer_add_uint32(out, 2 * sizeof(uint8_t) + evbuffer_get_length(payload));
evbuffer_add_uint8(out, BT_LTEP);
evbuffer_add_uint8(out, msgs->ut_metadata_id);
evbuffer_add_buffer(out, payload);
pokeBatchPeriod(msgs, HIGH_PRIORITY_INTERVAL_SECS);
dbgOutMessageLen(msgs);
/* cleanup */
evbuffer_free(payload);
tr_variantFree(&tmp);
}
}
static void updateBlockRequests(tr_peerMsgs* msgs)
{
if (tr_torrentIsPieceTransferAllowed(msgs->torrent, TR_PEER_TO_CLIENT) && msgs->desiredRequestCount > 0 &&
msgs->peer.pendingReqsToPeer <= msgs->desiredRequestCount * 0.66)
{
TR_ASSERT(tr_peerMsgsIsClientInterested(msgs));
TR_ASSERT(!tr_peerMsgsIsClientChoked(msgs));
int n;
tr_block_index_t* blocks;
int const numwant = msgs->desiredRequestCount - msgs->peer.pendingReqsToPeer;
blocks = tr_new(tr_block_index_t, numwant);
tr_peerMgrGetNextRequests(msgs->torrent, &msgs->peer, numwant, blocks, &n, false);
for (int i = 0; i < n; ++i)
{
struct peer_request req;
blockToReq(msgs->torrent, blocks[i], &req);
protocolSendRequest(msgs, &req);
}
tr_free(blocks);
}
}
static size_t fillOutputBuffer(tr_peerMsgs* msgs, time_t now)
{
int piece;
size_t bytesWritten = 0;
struct peer_request req;
bool const haveMessages = evbuffer_get_length(msgs->outMessages) != 0;
bool const fext = tr_peerIoSupportsFEXT(msgs->io);
/**
*** Protocol messages
**/
if (haveMessages && msgs->outMessagesBatchedAt == 0) /* fresh batch */
{
dbgmsg(msgs, "started an outMessages batch (length is %zu)", evbuffer_get_length(msgs->outMessages));
msgs->outMessagesBatchedAt = now;
}
else if (haveMessages && now - msgs->outMessagesBatchedAt >= msgs->outMessagesBatchPeriod)
{
size_t const len = evbuffer_get_length(msgs->outMessages);
/* flush the protocol messages */
dbgmsg(msgs, "flushing outMessages... to %p (length is %zu)", (void*)msgs->io, len);
tr_peerIoWriteBuf(msgs->io, msgs->outMessages, false);
msgs->clientSentAnythingAt = now;
msgs->outMessagesBatchedAt = 0;
msgs->outMessagesBatchPeriod = LOW_PRIORITY_INTERVAL_SECS;
bytesWritten += len;
}
/**
*** Metadata Pieces
**/
if (tr_peerIoGetWriteBufferSpace(msgs->io, now) >= METADATA_PIECE_SIZE && popNextMetadataRequest(msgs, &piece))
{
char* data;
size_t dataLen;
bool ok = false;
data = tr_torrentGetMetadataPiece(msgs->torrent, piece, &dataLen);
if (data != NULL)
{
tr_variant tmp;
struct evbuffer* payload;
struct evbuffer* out = msgs->outMessages;
/* build the data message */
tr_variantInitDict(&tmp, 3);
tr_variantDictAddInt(&tmp, TR_KEY_msg_type, METADATA_MSG_TYPE_DATA);
tr_variantDictAddInt(&tmp, TR_KEY_piece, piece);
tr_variantDictAddInt(&tmp, TR_KEY_total_size, msgs->torrent->infoDictLength);
payload = tr_variantToBuf(&tmp, TR_VARIANT_FMT_BENC);
/* write it out as a LTEP message to our outMessages buffer */
evbuffer_add_uint32(out, 2 * sizeof(uint8_t) + evbuffer_get_length(payload) + dataLen);
evbuffer_add_uint8(out, BT_LTEP);
evbuffer_add_uint8(out, msgs->ut_metadata_id);
evbuffer_add_buffer(out, payload);
evbuffer_add(out, data, dataLen);
pokeBatchPeriod(msgs, HIGH_PRIORITY_INTERVAL_SECS);
dbgOutMessageLen(msgs);
evbuffer_free(payload);
tr_variantFree(&tmp);
tr_free(data);
ok = true;
}
if (!ok) /* send a rejection message */
{
tr_variant tmp;
struct evbuffer* payload;
struct evbuffer* out = msgs->outMessages;
/* build the rejection message */
tr_variantInitDict(&tmp, 2);
tr_variantDictAddInt(&tmp, TR_KEY_msg_type, METADATA_MSG_TYPE_REJECT);
tr_variantDictAddInt(&tmp, TR_KEY_piece, piece);
payload = tr_variantToBuf(&tmp, TR_VARIANT_FMT_BENC);
/* write it out as a LTEP message to our outMessages buffer */
evbuffer_add_uint32(out, 2 * sizeof(uint8_t) + evbuffer_get_length(payload));
evbuffer_add_uint8(out, BT_LTEP);
evbuffer_add_uint8(out, msgs->ut_metadata_id);
evbuffer_add_buffer(out, payload);
pokeBatchPeriod(msgs, HIGH_PRIORITY_INTERVAL_SECS);
dbgOutMessageLen(msgs);
evbuffer_free(payload);
tr_variantFree(&tmp);
}
}
/**
*** Data Blocks
**/
if (tr_peerIoGetWriteBufferSpace(msgs->io, now) >= msgs->torrent->blockSize && popNextRequest(msgs, &req))
{
--msgs->prefetchCount;
if (requestIsValid(msgs, &req) && tr_torrentPieceIsComplete(msgs->torrent, req.index))
{
bool err;
uint32_t const msglen = 4 + 1 + 4 + 4 + req.length;
struct evbuffer* out;
struct evbuffer_iovec iovec[1];
out = evbuffer_new();
evbuffer_expand(out, msglen);
evbuffer_add_uint32(out, sizeof(uint8_t) + 2 * sizeof(uint32_t) + req.length);
evbuffer_add_uint8(out, BT_PIECE);
evbuffer_add_uint32(out, req.index);
evbuffer_add_uint32(out, req.offset);
evbuffer_reserve_space(out, req.length, iovec, 1);
err = tr_cacheReadBlock(getSession(msgs)->cache, msgs->torrent, req.index, req.offset, req.length,
iovec[0].iov_base) != 0;
iovec[0].iov_len = req.length;
evbuffer_commit_space(out, iovec, 1);
/* check the piece if it needs checking... */
if (!err && tr_torrentPieceNeedsCheck(msgs->torrent, req.index))
{
err = !tr_torrentCheckPiece(msgs->torrent, req.index);
if (err)
{
tr_torrentSetLocalError(msgs->torrent, _("Please Verify Local Data! Piece #%zu is corrupt."),
(size_t)req.index);
}
}
if (err)
{
if (fext)
{
protocolSendReject(msgs, &req);
}
}
else
{
size_t const n = evbuffer_get_length(out);
dbgmsg(msgs, "sending block %u:%u->%u", req.index, req.offset, req.length);
TR_ASSERT(n == msglen);
tr_peerIoWriteBuf(msgs->io, out, true);
bytesWritten += n;
msgs->clientSentAnythingAt = now;
tr_historyAdd(&msgs->peer.blocksSentToPeer, tr_time(), 1);
}
evbuffer_free(out);
if (err)
{
bytesWritten = 0;
msgs = NULL;
}
}
else if (fext) /* peer needs a reject message */
{
protocolSendReject(msgs, &req);
}
if (msgs != NULL)
{
prefetchPieces(msgs);
}
}
/**
*** Keepalive
**/
if (msgs != NULL && msgs->clientSentAnythingAt != 0 && now - msgs->clientSentAnythingAt > KEEPALIVE_INTERVAL_SECS)
{
dbgmsg(msgs, "sending a keepalive message");
evbuffer_add_uint32(msgs->outMessages, 0);
pokeBatchPeriod(msgs, IMMEDIATE_PRIORITY_INTERVAL_SECS);
}
return bytesWritten;
}
static void peerPulse(void* vmsgs)
{
tr_peerMsgs* msgs = vmsgs;
time_t const now = tr_time();
if (tr_isPeerIo(msgs->io))
{
updateDesiredRequestCount(msgs);
updateBlockRequests(msgs);
updateMetadataRequests(msgs, now);
}
for (;;)
{
if (fillOutputBuffer(msgs, now) < 1)
{
break;
}
}
}
void tr_peerMsgsPulse(tr_peerMsgs* msgs)
{
if (msgs != NULL)
{
peerPulse(msgs);
}
}
static void gotError(tr_peerIo* io, short what, void* vmsgs)
{
TR_UNUSED(io);
if ((what & BEV_EVENT_TIMEOUT) != 0)
{
dbgmsg(vmsgs, "libevent got a timeout, what=%hd", what);
}
if ((what & (BEV_EVENT_EOF | BEV_EVENT_ERROR)) != 0)
{
dbgmsg(vmsgs, "libevent got an error! what=%hd, errno=%d (%s)", what, errno, tr_strerror(errno));
}
fireError(vmsgs, ENOTCONN);
}
static void sendBitfield(tr_peerMsgs* msgs)
{
TR_ASSERT(tr_torrentHasMetadata(msgs->torrent));
void* bytes;
size_t byte_count = 0;
struct evbuffer* out = msgs->outMessages;
bytes = tr_torrentCreatePieceBitfield(msgs->torrent, &byte_count);
evbuffer_add_uint32(out, sizeof(uint8_t) + byte_count);
evbuffer_add_uint8(out, BT_BITFIELD);
evbuffer_add(out, bytes, byte_count);
dbgmsg(msgs, "sending bitfield... outMessage size is now %zu", evbuffer_get_length(out));
pokeBatchPeriod(msgs, IMMEDIATE_PRIORITY_INTERVAL_SECS);
tr_free(bytes);
}
static void tellPeerWhatWeHave(tr_peerMsgs* msgs)
{
bool const fext = tr_peerIoSupportsFEXT(msgs->io);
if (fext && tr_torrentHasAll(msgs->torrent))
{
protocolSendHaveAll(msgs);
}
else if (fext && tr_torrentHasNone(msgs->torrent))
{
protocolSendHaveNone(msgs);
}
else if (!tr_torrentHasNone(msgs->torrent))
{
sendBitfield(msgs);
}
}
/**
***
**/
/* some peers give us error messages if we send
more than this many peers in a single pex message
http://wiki.theory.org/BitTorrentPeerExchangeConventions */
#define MAX_PEX_ADDED 50
#define MAX_PEX_DROPPED 50
typedef struct
{
tr_pex* added;
tr_pex* dropped;
tr_pex* elements;
int addedCount;
int droppedCount;
int elementCount;
}
PexDiffs;
static void pexAddedCb(void const* vpex, void* userData)
{
PexDiffs* diffs = userData;
tr_pex const* pex = vpex;
if (diffs->addedCount < MAX_PEX_ADDED)
{
diffs->added[diffs->addedCount++] = *pex;
diffs->elements[diffs->elementCount++] = *pex;
}
}
static inline void pexDroppedCb(void const* vpex, void* userData)
{
PexDiffs* diffs = userData;
tr_pex const* pex = vpex;
if (diffs->droppedCount < MAX_PEX_DROPPED)
{
diffs->dropped[diffs->droppedCount++] = *pex;
}
}
static inline void pexElementCb(void const* vpex, void* userData)
{
PexDiffs* diffs = userData;
tr_pex const* pex = vpex;
diffs->elements[diffs->elementCount++] = *pex;
}
typedef void (* tr_set_func)(void const* element, void* userData);
/**
* @brief find the differences and commonalities in two sorted sets
* @param a the first set
* @param aCount the number of elements in the set 'a'
* @param b the second set
* @param bCount the number of elements in the set 'b'
* @param compare the sorting method for both sets
* @param elementSize the sizeof the element in the two sorted sets
* @param in_a called for items in set 'a' but not set 'b'
* @param in_b called for items in set 'b' but not set 'a'
* @param in_both called for items that are in both sets
* @param userData user data passed along to in_a, in_b, and in_both
*/
static void tr_set_compare(void const* va, size_t aCount, void const* vb, size_t bCount, tr_voidptr_compare_func compare,
size_t elementSize, tr_set_func in_a_cb, tr_set_func in_b_cb, tr_set_func in_both_cb, void* userData)
{
uint8_t const* a = va;
uint8_t const* b = vb;
uint8_t const* aend = a + elementSize * aCount;
uint8_t const* bend = b + elementSize * bCount;
while (a != aend || b != bend)
{
if (a == aend)
{
(*in_b_cb)(b, userData);
b += elementSize;
}
else if (b == bend)
{
(*in_a_cb)(a, userData);
a += elementSize;
}
else
{
int const val = (*compare)(a, b);
if (val == 0)
{
(*in_both_cb)(a, userData);
a += elementSize;
b += elementSize;
}
else if (val < 0)
{
(*in_a_cb)(a, userData);
a += elementSize;
}
else if (val > 0)
{
(*in_b_cb)(b, userData);
b += elementSize;
}
}
}
}
static void sendPex(tr_peerMsgs* msgs)
{
if (msgs->peerSupportsPex && tr_torrentAllowsPex(msgs->torrent))
{
PexDiffs diffs;
PexDiffs diffs6;
tr_pex* newPex = NULL;
tr_pex* newPex6 = NULL;
int const newCount = tr_peerMgrGetPeers(msgs->torrent, &newPex, TR_AF_INET, TR_PEERS_CONNECTED, MAX_PEX_PEER_COUNT);
int const newCount6 = tr_peerMgrGetPeers(msgs->torrent, &newPex6, TR_AF_INET6, TR_PEERS_CONNECTED, MAX_PEX_PEER_COUNT);
/* build the diffs */
diffs.added = tr_new(tr_pex, newCount);
diffs.addedCount = 0;
diffs.dropped = tr_new(tr_pex, msgs->pexCount);
diffs.droppedCount = 0;
diffs.elements = tr_new(tr_pex, newCount + msgs->pexCount);
diffs.elementCount = 0;
tr_set_compare(msgs->pex, msgs->pexCount, newPex, newCount, tr_pexCompare, sizeof(tr_pex), pexDroppedCb, pexAddedCb,
pexElementCb, &diffs);
diffs6.added = tr_new(tr_pex, newCount6);
diffs6.addedCount = 0;
diffs6.dropped = tr_new(tr_pex, msgs->pexCount6);
diffs6.droppedCount = 0;
diffs6.elements = tr_new(tr_pex, newCount6 + msgs->pexCount6);
diffs6.elementCount = 0;
tr_set_compare(msgs->pex6, msgs->pexCount6, newPex6, newCount6, tr_pexCompare, sizeof(tr_pex), pexDroppedCb, pexAddedCb,
pexElementCb, &diffs6);
dbgmsg(msgs, "pex: old peer count %d+%d, new peer count %d+%d, added %d+%d, removed %d+%d", msgs->pexCount,
msgs->pexCount6, newCount, newCount6, diffs.addedCount, diffs6.addedCount, diffs.droppedCount, diffs6.droppedCount);
if (diffs.addedCount == 0 && diffs.droppedCount == 0 && diffs6.addedCount == 0 && diffs6.droppedCount == 0)
{
tr_free(diffs.elements);
tr_free(diffs6.elements);
}
else
{
tr_variant val;
uint8_t* tmp;
uint8_t* walk;
struct evbuffer* payload;
struct evbuffer* out = msgs->outMessages;
/* update peer */
tr_free(msgs->pex);
msgs->pex = diffs.elements;
msgs->pexCount = diffs.elementCount;
tr_free(msgs->pex6);
msgs->pex6 = diffs6.elements;
msgs->pexCount6 = diffs6.elementCount;
/* build the pex payload */
tr_variantInitDict(&val, 3); /* ipv6 support: left as 3: speed vs. likelihood? */
if (diffs.addedCount > 0)
{
/* "added" */
tmp = walk = tr_new(uint8_t, diffs.addedCount * 6);
for (int i = 0; i < diffs.addedCount; ++i)
{
memcpy(walk, &diffs.added[i].addr.addr, 4);
walk += 4;
memcpy(walk, &diffs.added[i].port, 2);
walk += 2;
}
TR_ASSERT(walk - tmp == diffs.addedCount * 6);
tr_variantDictAddRaw(&val, TR_KEY_added, tmp, walk - tmp);
tr_free(tmp);
/* "added.f"
* unset each holepunch flag because we don't support it. */
tmp = walk = tr_new(uint8_t, diffs.addedCount);
for (int i = 0; i < diffs.addedCount; ++i)
{
*walk++ = diffs.added[i].flags & ~ADDED_F_HOLEPUNCH;
}
TR_ASSERT(walk - tmp == diffs.addedCount);
tr_variantDictAddRaw(&val, TR_KEY_added_f, tmp, walk - tmp);
tr_free(tmp);
}
if (diffs.droppedCount > 0)
{
/* "dropped" */
tmp = walk = tr_new(uint8_t, diffs.droppedCount * 6);
for (int i = 0; i < diffs.droppedCount; ++i)
{
memcpy(walk, &diffs.dropped[i].addr.addr, 4);
walk += 4;
memcpy(walk, &diffs.dropped[i].port, 2);
walk += 2;
}
TR_ASSERT(walk - tmp == diffs.droppedCount * 6);
tr_variantDictAddRaw(&val, TR_KEY_dropped, tmp, walk - tmp);
tr_free(tmp);
}
if (diffs6.addedCount > 0)
{
/* "added6" */
tmp = walk = tr_new(uint8_t, diffs6.addedCount * 18);
for (int i = 0; i < diffs6.addedCount; ++i)
{
memcpy(walk, &diffs6.added[i].addr.addr.addr6.s6_addr, 16);
walk += 16;
memcpy(walk, &diffs6.added[i].port, 2);
walk += 2;
}
TR_ASSERT(walk - tmp == diffs6.addedCount * 18);
tr_variantDictAddRaw(&val, TR_KEY_added6, tmp, walk - tmp);
tr_free(tmp);
/* "added6.f"
* unset each holepunch flag because we don't support it. */
tmp = walk = tr_new(uint8_t, diffs6.addedCount);
for (int i = 0; i < diffs6.addedCount; ++i)
{
*walk++ = diffs6.added[i].flags & ~ADDED_F_HOLEPUNCH;
}
TR_ASSERT(walk - tmp == diffs6.addedCount);
tr_variantDictAddRaw(&val, TR_KEY_added6_f, tmp, walk - tmp);
tr_free(tmp);
}
if (diffs6.droppedCount > 0)
{
/* "dropped6" */
tmp = walk = tr_new(uint8_t, diffs6.droppedCount * 18);
for (int i = 0; i < diffs6.droppedCount; ++i)
{
memcpy(walk, &diffs6.dropped[i].addr.addr.addr6.s6_addr, 16);
walk += 16;
memcpy(walk, &diffs6.dropped[i].port, 2);
walk += 2;
}
TR_ASSERT(walk - tmp == diffs6.droppedCount * 18);
tr_variantDictAddRaw(&val, TR_KEY_dropped6, tmp, walk - tmp);
tr_free(tmp);
}
/* write the pex message */
payload = tr_variantToBuf(&val, TR_VARIANT_FMT_BENC);
evbuffer_add_uint32(out, 2 * sizeof(uint8_t) + evbuffer_get_length(payload));
evbuffer_add_uint8(out, BT_LTEP);
evbuffer_add_uint8(out, msgs->ut_pex_id);
evbuffer_add_buffer(out, payload);
pokeBatchPeriod(msgs, HIGH_PRIORITY_INTERVAL_SECS);
dbgmsg(msgs, "sending a pex message; outMessage size is now %zu", evbuffer_get_length(out));
dbgOutMessageLen(msgs);
evbuffer_free(payload);
tr_variantFree(&val);
}
/* cleanup */
tr_free(diffs.added);
tr_free(diffs.dropped);
tr_free(newPex);
tr_free(diffs6.added);
tr_free(diffs6.dropped);
tr_free(newPex6);
}
}
static void pexPulse(evutil_socket_t fd, short what, void* vmsgs)
{
TR_UNUSED(fd);
TR_UNUSED(what);
struct tr_peerMsgs* msgs = vmsgs;
sendPex(msgs);
TR_ASSERT(msgs->pexTimer != NULL);
tr_timerAdd(msgs->pexTimer, PEX_INTERVAL_SECS, 0);
}
/***
**** tr_peer virtual functions
***/
static bool peermsgs_is_transferring_pieces(struct tr_peer const* peer, uint64_t now, tr_direction direction,
unsigned int* setme_Bps)
{
unsigned int Bps = 0;
if (tr_isPeerMsgs(peer))
{
tr_peerMsgs const* msgs = (tr_peerMsgs const*)peer;
Bps = tr_peerIoGetPieceSpeed_Bps(msgs->io, now, direction);
}
if (setme_Bps != NULL)
{
*setme_Bps = Bps;
}
return Bps > 0;
}
static void peermsgs_destruct(tr_peer* peer)
{
tr_peerMsgs* const msgs = PEER_MSGS(peer);
TR_ASSERT(msgs != NULL);
if (msgs != NULL)
{
tr_peerMsgsSetActive(msgs, TR_UP, false);
tr_peerMsgsSetActive(msgs, TR_DOWN, false);
if (msgs->pexTimer != NULL)
{
event_free(msgs->pexTimer);
}
if (msgs->incoming.block != NULL)
{
evbuffer_free(msgs->incoming.block);
}
if (msgs->io != NULL)
{
tr_peerIoClear(msgs->io);
tr_peerIoUnref(msgs->io); /* balanced by the ref in handshakeDoneCB() */
}
evbuffer_free(msgs->outMessages);
tr_free(msgs->pex6);
tr_free(msgs->pex);
tr_peerDestruct(&msgs->peer);
memset(msgs, ~0, sizeof(tr_peerMsgs));
}
}
static struct tr_peer_virtual_funcs const my_funcs =
{
.destruct = peermsgs_destruct,
.is_transferring_pieces = peermsgs_is_transferring_pieces
};
/***
****
***/
time_t tr_peerMsgsGetConnectionAge(tr_peerMsgs const* msgs)
{
TR_ASSERT(tr_isPeerMsgs(msgs));
return tr_peerIoGetAge(msgs->io);
}
bool tr_peerMsgsIsPeerChoked(tr_peerMsgs const* msgs)
{
TR_ASSERT(tr_isPeerMsgs(msgs));
return msgs->peer_is_choked;
}
bool tr_peerMsgsIsPeerInterested(tr_peerMsgs const* msgs)
{
TR_ASSERT(tr_isPeerMsgs(msgs));
return msgs->peer_is_interested;
}
bool tr_peerMsgsIsClientChoked(tr_peerMsgs const* msgs)
{
TR_ASSERT(tr_isPeerMsgs(msgs));
return msgs->client_is_choked;
}
bool tr_peerMsgsIsClientInterested(tr_peerMsgs const* msgs)
{
TR_ASSERT(tr_isPeerMsgs(msgs));
return msgs->client_is_interested;
}
bool tr_peerMsgsIsUtpConnection(tr_peerMsgs const* msgs)
{
TR_ASSERT(tr_isPeerMsgs(msgs));
return msgs->io->socket.type == TR_PEER_SOCKET_TYPE_UTP;
}
bool tr_peerMsgsIsEncrypted(tr_peerMsgs const* msgs)
{
TR_ASSERT(tr_isPeerMsgs(msgs));
return tr_peerIoIsEncrypted(msgs->io);
}
bool tr_peerMsgsIsIncomingConnection(tr_peerMsgs const* msgs)
{
TR_ASSERT(tr_isPeerMsgs(msgs));
return tr_peerIoIsIncoming(msgs->io);
}
/***
****
***/
bool tr_isPeerMsgs(void const* msgs)
{
return msgs != NULL && ((struct tr_peerMsgs const*)msgs)->magic_number == MAGIC_NUMBER;
}
tr_peerMsgs* tr_peerMsgsCast(void* vm)
{
return tr_isPeerMsgs(vm) ? vm : NULL;
}
tr_peerMsgs* tr_peerMsgsNew(struct tr_torrent* torrent, struct tr_peerIo* io, tr_peer_callback callback, void* callbackData)
{
TR_ASSERT(io != NULL);
tr_peerMsgs* m = tr_new0(tr_peerMsgs, 1);
tr_peerConstruct(&m->peer, torrent);
m->peer.funcs = &my_funcs;
m->magic_number = MAGIC_NUMBER;
m->client_is_choked = true;
m->peer_is_choked = true;
m->client_is_interested = false;
m->peer_is_interested = false;
m->is_active[TR_UP] = false;
m->is_active[TR_DOWN] = false;
m->callback = callback;
m->callbackData = callbackData;
m->io = io;
m->torrent = torrent;
m->state = AWAITING_BT_LENGTH;
m->outMessages = evbuffer_new();
m->outMessagesBatchedAt = 0;
m->outMessagesBatchPeriod = LOW_PRIORITY_INTERVAL_SECS;
if (tr_torrentAllowsPex(torrent))
{
m->pexTimer = evtimer_new(torrent->session->event_base, pexPulse, m);
tr_timerAdd(m->pexTimer, PEX_INTERVAL_SECS, 0);
}
if (tr_peerIoSupportsUTP(m->io))
{
tr_address const* addr = tr_peerIoGetAddress(m->io, NULL);
tr_peerMgrSetUtpSupported(torrent, addr);
tr_peerMgrSetUtpFailed(torrent, addr, false);
}
if (tr_peerIoSupportsLTEP(m->io))
{
sendLtepHandshake(m);
}
tellPeerWhatWeHave(m);
if (tr_dhtEnabled(torrent->session) && tr_peerIoSupportsDHT(m->io))
{
/* Only send PORT over IPv6 when the IPv6 DHT is running (BEP-32). */
struct tr_address const* addr = tr_peerIoGetAddress(m->io, NULL);
if (addr->type == TR_AF_INET || tr_globalIPv6() != NULL)
{
protocolSendPort(m, tr_dhtPort(torrent->session));
}
}
tr_peerIoSetIOFuncs(m->io, canRead, didWrite, gotError, m);
updateDesiredRequestCount(m);
return m;
}