transmission/libtransmission/bandwidth.c

/*
 * This file Copyright (C) Mnemosyne LLC
 *
 * This file is licensed by the GPL version 2. Works owned by the
 * Transmission project are granted a special exemption to clause 2(b)
 * so that the bulk of its code can remain under the MIT license.
 * This exemption does not extend to derived works not owned by
 * the Transmission project.
 *
 * $Id$
 */

#include <assert.h>
#include <limits.h>
#include <string.h> /* memset() */

#include "transmission.h"
#include "bandwidth.h"
#include "crypto.h" /* tr_cryptoWeakRandInt() */
#include "peer-io.h"
#include "utils.h"

#define dbgmsg( ... ) \
    do { \
        if( tr_deepLoggingIsActive( ) ) \
            tr_deepLog( __FILE__, __LINE__, NULL, __VA_ARGS__ ); \
    } while( 0 )

/***
****
***/

static unsigned int
getSpeed_Bps( const struct bratecontrol * r, unsigned int interval_msec, uint64_t now )
{
    if( !now )
        now = tr_time_msec();

    if( now != r->cache_time )
    {
        int i = r->newest;
        uint64_t bytes = 0;
        const uint64_t cutoff = now - interval_msec;
        struct bratecontrol * rvolatile = (struct bratecontrol*) r;

        for( ;; )
        {
            if( r->transfers[i].date <= cutoff )
                break;

            bytes += r->transfers[i].size;

            if( --i == -1 ) i = HISTORY_SIZE - 1; /* circular history */
            if( i == r->newest ) break; /* we've come all the way around */
        }

        rvolatile->cache_val = (unsigned int)(( bytes * 1000u ) / interval_msec);
        rvolatile->cache_time = now;
    }

    return r->cache_val;
}

static void
bytesUsed( const uint64_t now, struct bratecontrol * r, size_t size )
{
    if( r->transfers[r->newest].date + GRANULARITY_MSEC >= now )
        r->transfers[r->newest].size += size;
    else
    {
        if( ++r->newest == HISTORY_SIZE ) r->newest = 0;
        r->transfers[r->newest].date = now;
        r->transfers[r->newest].size = size;
    }

    /* invalidate cache_val*/
    r->cache_time = 0;
}

/******
*******
*******
******/

static int
compareBandwidth( const void * va, const void * vb )
{
    const tr_bandwidth * a = va;
    const tr_bandwidth * b = vb;
    return a->uniqueKey - b->uniqueKey;
}

/***
****
***/

void
tr_bandwidthConstruct( tr_bandwidth * b, tr_session * session, tr_bandwidth * parent )
{
    static unsigned int uniqueKey = 0;

    b->session = session;
    b->children = TR_PTR_ARRAY_INIT;
    b->magicNumber = BANDWIDTH_MAGIC_NUMBER;
    b->uniqueKey = uniqueKey++;
    b->band[TR_UP].honorParentLimits = true;
    b->band[TR_DOWN].honorParentLimits = true;
    tr_bandwidthSetParent( b, parent );
}

void
tr_bandwidthDestruct( tr_bandwidth * b )
{
    assert( tr_isBandwidth( b ) );

    tr_bandwidthSetParent( b, NULL );
    tr_ptrArrayDestruct( &b->children, NULL );

    memset( b, ~0, sizeof( tr_bandwidth ) );
}

/***
****
***/

void
tr_bandwidthSetParent( tr_bandwidth  * b,
                       tr_bandwidth  * parent )
{
    assert( tr_isBandwidth( b ) );
    assert( b != parent );

    if( b->parent )
    {
        void * removed;

        assert( tr_isBandwidth( b->parent ) );

        removed = tr_ptrArrayRemoveSorted( &b->parent->children, b, compareBandwidth );
        assert( removed == b );
        assert( tr_ptrArrayFindSorted( &b->parent->children, b, compareBandwidth ) == NULL );

        b->parent = NULL;
    }

    if( parent )
    {
        assert( tr_isBandwidth( parent ) );
        assert( parent->parent != b );

        assert( tr_ptrArrayFindSorted( &parent->children, b, compareBandwidth ) == NULL );
        tr_ptrArrayInsertSorted( &parent->children, b, compareBandwidth );
        assert( tr_ptrArrayFindSorted( &parent->children, b, compareBandwidth ) == b );
        b->parent = parent;
    }
}

/***
****
***/

static void
allocateBandwidth( tr_bandwidth  * b,
                   tr_priority_t   parent_priority,
                   tr_direction    dir,
                   unsigned int    period_msec,
                   tr_ptrArray   * peer_pool )
{
    const tr_priority_t priority = MAX( parent_priority, b->priority );

    assert( tr_isBandwidth( b ) );
    assert( tr_isDirection( dir ) );

    /* set the available bandwidth */
    if( b->band[dir].isLimited )
    {
        const unsigned int nextPulseSpeed = b->band[dir].desiredSpeed_Bps;
        b->band[dir].bytesLeft = ( nextPulseSpeed * period_msec ) / 1000u;
    }

    /* add this bandwidth's peer, if any, to the peer pool */
    if( b->peer != NULL ) {
        b->peer->priority = priority;
        tr_ptrArrayAppend( peer_pool, b->peer );
    }

    /* traverse & repeat for the subtree */
    if( 1 ) {
        int i;
        struct tr_bandwidth ** children = (struct tr_bandwidth**) tr_ptrArrayBase( &b->children );
        const int n = tr_ptrArraySize( &b->children );
        for( i=0; i<n; ++i )
            allocateBandwidth( children[i], priority, dir, period_msec, peer_pool );
    }
}

static void
phaseOne( tr_ptrArray * peerArray, tr_direction dir )
{
    int i, n;
    int peerCount = tr_ptrArraySize( peerArray );
    struct tr_peerIo ** peers = (struct tr_peerIo**) tr_ptrArrayBase( peerArray );

    /* First phase of IO. Tries to distribute bandwidth fairly to keep faster
     * peers from starving the others. Loop through the peers, giving each a
     * small chunk of bandwidth. Keep looping until we run out of bandwidth
     * and/or peers that can use it */
    n = peerCount;
    dbgmsg( "%d peers to go round-robin for %s", n, (dir==TR_UP?"upload":"download") );
    i = n ? tr_cryptoWeakRandInt( n ) : 0; /* pick a random starting point */
    while( n > 0 )
    {
        /* value of 3000 bytes chosen so that when using uTP we'll send a full-size
         * frame right away and leave enough buffered data for the next frame to go
         * out in a timely manner. */
        const size_t increment = 3000;

        const int bytesUsed = tr_peerIoFlush( peers[i], dir, increment );

        dbgmsg( "peer #%d of %d used %d bytes in this pass", i, n, bytesUsed );

        if( bytesUsed == (int)increment )
            ++i;
        else {
            /* peer is done writing for now; move it to the end of the list */
            tr_peerIo * pio = peers[i];
            peers[i] = peers[n-1];
            peers[n-1] = pio;
            --n;
        }

        if( i >= n )
            i = 0;
    }
}

void
tr_bandwidthAllocate( tr_bandwidth  * b,
                      tr_direction    dir,
                      unsigned int    period_msec )
{
    int i, peerCount;
    tr_ptrArray tmp = TR_PTR_ARRAY_INIT;
    tr_ptrArray low = TR_PTR_ARRAY_INIT;
    tr_ptrArray high = TR_PTR_ARRAY_INIT;
    tr_ptrArray normal = TR_PTR_ARRAY_INIT;
    struct tr_peerIo ** peers;

    /* allocateBandwidth() is a helper function with two purposes:
     * 1. allocate bandwidth to b and its subtree
     * 2. accumulate an array of all the peerIos from b and its subtree. */
    allocateBandwidth( b, TR_PRI_LOW, dir, period_msec, &tmp );
    peers = (struct tr_peerIo**) tr_ptrArrayBase( &tmp );
    peerCount = tr_ptrArraySize( &tmp );

    for( i=0; i<peerCount; ++i )
    {
        tr_peerIo * io = peers[i];
        tr_peerIoRef( io );

        tr_peerIoFlushOutgoingProtocolMsgs( io );

        switch( io->priority ) {
            case TR_PRI_HIGH:   tr_ptrArrayAppend( &high,   io ); /* fall through */
            case TR_PRI_NORMAL: tr_ptrArrayAppend( &normal, io ); /* fall through */
            default:            tr_ptrArrayAppend( &low,    io );
        }
    }

    /* First phase of IO. Tries to distribute bandwidth fairly to keep faster
     * peers from starving the others. Loop through the peers, giving each a
     * small chunk of bandwidth. Keep looping until we run out of bandwidth
     * and/or peers that can use it */
    phaseOne( &high, dir );
    phaseOne( &normal, dir );
    phaseOne( &low, dir );

    /* Second phase of IO. To help us scale in high bandwidth situations,
     * enable on-demand IO for peers with bandwidth left to burn.
     * This on-demand IO is enabled until (1) the peer runs out of bandwidth,
     * or (2) the next tr_bandwidthAllocate() call, when we start over again. */
    for( i=0; i<peerCount; ++i )
        tr_peerIoSetEnabled( peers[i], dir, tr_peerIoHasBandwidthLeft( peers[i], dir ) );

    for( i=0; i<peerCount; ++i )
        tr_peerIoUnref( peers[i] );

    /* cleanup */
    tr_ptrArrayDestruct( &normal, NULL );
    tr_ptrArrayDestruct( &high, NULL );
    tr_ptrArrayDestruct( &low, NULL );
    tr_ptrArrayDestruct( &tmp, NULL );
}

void
tr_bandwidthSetPeer( tr_bandwidth * b, tr_peerIo * peer )
{
    assert( tr_isBandwidth( b ) );
    assert( ( peer == NULL ) || tr_isPeerIo( peer ) );

    b->peer = peer;
}

/***
****
***/

static unsigned int
bandwidthClamp( const tr_bandwidth  * b,
                uint64_t              now,
                tr_direction          dir,
                unsigned int          byteCount )
{
    assert( tr_isBandwidth( b ) );
    assert( tr_isDirection( dir ) );

    if( b )
    {
        if( b->band[dir].isLimited )
        {
            byteCount = MIN( byteCount, b->band[dir].bytesLeft );

            /* if we're getting close to exceeding the speed limit,
             * clamp down harder on the bytes available */
            if( byteCount > 0 )
            {
                double current;
                double desired;
                double r;

                if( now == 0 )
                    now = tr_time_msec( );

                current = tr_bandwidthGetRawSpeed_Bps( b, now, TR_DOWN );
                desired = tr_bandwidthGetDesiredSpeed_Bps( b, TR_DOWN );
                r = desired >= 1 ? current / desired : 0;

                     if( r > 1.0 ) byteCount = 0;
                else if( r > 0.9 ) byteCount *= 0.8;
                else if( r > 0.8 ) byteCount *= 0.9;
            }
        }

        if( b->parent && b->band[dir].honorParentLimits && ( byteCount > 0 ) )
            byteCount = bandwidthClamp( b->parent, now, dir, byteCount );
    }

    return byteCount;
}
unsigned int
tr_bandwidthClamp( const tr_bandwidth  * b,
                   tr_direction          dir,
                   unsigned int          byteCount )
{
    return bandwidthClamp( b, 0, dir, byteCount );
}


unsigned int
tr_bandwidthGetRawSpeed_Bps( const tr_bandwidth * b, const uint64_t now, const tr_direction dir )
{
    assert( tr_isBandwidth( b ) );
    assert( tr_isDirection( dir ) );

    return getSpeed_Bps( &b->band[dir].raw, HISTORY_MSEC, now );
}

unsigned int
tr_bandwidthGetPieceSpeed_Bps( const tr_bandwidth * b, const uint64_t now, const tr_direction dir )
{
    assert( tr_isBandwidth( b ) );
    assert( tr_isDirection( dir ) );

    return getSpeed_Bps( &b->band[dir].piece, HISTORY_MSEC, now );
}

void
tr_bandwidthUsed( tr_bandwidth  * b,
                  tr_direction    dir,
                  size_t          byteCount,
                  bool         isPieceData,
                  uint64_t        now )
{
    struct tr_band * band;

    assert( tr_isBandwidth( b ) );
    assert( tr_isDirection( dir ) );

    band = &b->band[dir];

    if( band->isLimited && isPieceData )
        band->bytesLeft -= MIN( band->bytesLeft, byteCount );

#ifdef DEBUG_DIRECTION
if( ( dir == DEBUG_DIRECTION ) && ( band->isLimited ) )
fprintf( stderr, "%p consumed %5zu bytes of %5s data... was %6zu, now %6zu left\n",
         b, byteCount, (isPieceData?"piece":"raw"), oldBytesLeft, band->bytesLeft );
#endif

    bytesUsed( now, &band->raw, byteCount );

    if( isPieceData )
        bytesUsed( now, &band->piece, byteCount );

    if( b->parent != NULL )
        tr_bandwidthUsed( b->parent, dir, byteCount, isPieceData, now );
}