webrtc/modules/rtp_rtcp/source/tmmbr_help.cc

/*
 *  Copyright (c) 2011 The WebRTC project authors. All Rights Reserved.
 *
 *  Use of this source code is governed by a BSD-style license
 *  that can be found in the LICENSE file in the root of the source
 *  tree. An additional intellectual property rights grant can be found
 *  in the file PATENTS.  All contributing project authors may
 *  be found in the AUTHORS file in the root of the source tree.
 */

#include "tmmbr_help.h"

#include "rtp_rtcp_config.h"

namespace webrtc {
TMMBRSet::TMMBRSet() :
    ptrTmmbrSet(0),
    ptrPacketOHSet(0),
    ptrSsrcSet(0),
    sizeOfSet(0),
    lengthOfSet(0)
{
}

TMMBRSet::~TMMBRSet()
{
    delete [] ptrTmmbrSet;
    delete [] ptrPacketOHSet;
    delete [] ptrSsrcSet;
    ptrTmmbrSet = 0;
    ptrPacketOHSet = 0;
    ptrSsrcSet = 0;
    sizeOfSet = 0;
    lengthOfSet = 0;
}

void
TMMBRSet::VerifyAndAllocateSet(WebRtc_UWord32 minimumSize)
{
    if(minimumSize > sizeOfSet)
    {
        // make sure that our buffers are big enough
        if(ptrTmmbrSet)
        {
            delete [] ptrTmmbrSet;
            delete [] ptrPacketOHSet;
            delete [] ptrSsrcSet;
        }
        ptrTmmbrSet = new WebRtc_UWord32[minimumSize];
        ptrPacketOHSet = new WebRtc_UWord32[minimumSize];
        ptrSsrcSet = new WebRtc_UWord32[minimumSize];
        sizeOfSet = minimumSize;
    }
    // reset memory
    for(WebRtc_UWord32 i = 0; i < sizeOfSet; i++)
    {
        ptrTmmbrSet[i] = 0;
        ptrPacketOHSet[i] = 0;
        ptrSsrcSet[i] = 0;
    }
    lengthOfSet = 0;
}

TMMBRHelp::TMMBRHelp(const bool audio) :
    _criticalSection(*CriticalSectionWrapper::CreateCriticalSection()),
    _audio(audio),
    _candidateSet(),
    _boundingSet(),
    _boundingSetToSend(),
    _ptrIntersectionBoundingSet(NULL),
    _ptrMaxPRBoundingSet(NULL)
{
}

TMMBRHelp::~TMMBRHelp()
{
    delete [] _ptrIntersectionBoundingSet;
    delete [] _ptrMaxPRBoundingSet;
    _ptrIntersectionBoundingSet = 0;
    _ptrMaxPRBoundingSet = 0;
    delete &_criticalSection;
}

TMMBRSet*
TMMBRHelp::VerifyAndAllocateBoundingSet(WebRtc_UWord32 minimumSize)
{
    CriticalSectionScoped lock(_criticalSection);

    if(minimumSize > _boundingSet.sizeOfSet)
    {
        // make sure that our buffers are big enough
        if(_ptrIntersectionBoundingSet)
        {
            delete [] _ptrIntersectionBoundingSet;
            delete [] _ptrMaxPRBoundingSet;
        }
        _ptrIntersectionBoundingSet = new float[minimumSize];
        _ptrMaxPRBoundingSet = new float[minimumSize];
    }
    _boundingSet.VerifyAndAllocateSet(minimumSize);
    return &_boundingSet;
}

TMMBRSet*
TMMBRHelp::BoundingSet()
{
    return &_boundingSet;
}

WebRtc_Word32
TMMBRHelp::SetTMMBRBoundingSetToSend(const TMMBRSet* boundingSetToSend,
                                     const WebRtc_UWord32 maxBitrateKbit)
{
    CriticalSectionScoped lock(_criticalSection);

    if (boundingSetToSend == NULL)
    {
        _boundingSetToSend.lengthOfSet = 0;
        return 0;
    }

    VerifyAndAllocateBoundingSetToSend(boundingSetToSend->lengthOfSet);

    for (WebRtc_UWord32 i = 0; i < boundingSetToSend->lengthOfSet; i++)
    {
        // cap at our configured max bitrate
        WebRtc_UWord32 bitrate = boundingSetToSend->ptrTmmbrSet[i];
        if(maxBitrateKbit)
        {
            // do we have a configured max bitrate?
            if(bitrate > maxBitrateKbit)
            {
                bitrate = maxBitrateKbit;
            }
        }

        _boundingSetToSend.ptrTmmbrSet[i]    = bitrate;
        _boundingSetToSend.ptrPacketOHSet[i] = boundingSetToSend->ptrPacketOHSet[i];
        _boundingSetToSend.ptrSsrcSet[i]     = boundingSetToSend->ptrSsrcSet[i];
    }
    _boundingSetToSend.lengthOfSet = boundingSetToSend->lengthOfSet;
    return 0;
}

WebRtc_Word32
TMMBRHelp::VerifyAndAllocateBoundingSetToSend(WebRtc_UWord32 minimumSize)
{
    CriticalSectionScoped lock(_criticalSection);

    _boundingSetToSend.VerifyAndAllocateSet(minimumSize);
    return 0;
}

TMMBRSet*
TMMBRHelp::VerifyAndAllocateCandidateSet(WebRtc_UWord32 minimumSize)
{
    CriticalSectionScoped lock(_criticalSection);

    _candidateSet.VerifyAndAllocateSet(minimumSize);
    return &_candidateSet;
}

TMMBRSet*
TMMBRHelp::CandidateSet()
{
    return &_candidateSet;
}

TMMBRSet*
TMMBRHelp::BoundingSetToSend()
{
    return &_boundingSetToSend;
}

WebRtc_Word32
TMMBRHelp::FindTMMBRBoundingSet(TMMBRSet*& boundingSet)
{
    CriticalSectionScoped lock(_criticalSection);

    // Work on local variable, will be modified
    TMMBRSet    candidateSet;
    candidateSet.VerifyAndAllocateSet(_candidateSet.sizeOfSet);

    // Number of set candidates
    WebRtc_Word32 numSetCandidates = 0;
    for (WebRtc_UWord32 i = 0; i < _candidateSet.sizeOfSet; i++)
    {
        if(_candidateSet.ptrTmmbrSet[i])
        {
            numSetCandidates++;
            candidateSet.ptrTmmbrSet[i]    = _candidateSet.ptrTmmbrSet[i];
            candidateSet.ptrPacketOHSet[i] = _candidateSet.ptrPacketOHSet[i];
            candidateSet.ptrSsrcSet[i]     = _candidateSet.ptrSsrcSet[i];
        }
        else
        {
            // make sure this is zero if tmmbr = 0
            _candidateSet.ptrPacketOHSet[i] = 0;
        }
    }
    candidateSet.lengthOfSet = numSetCandidates;

    // Find bounding set
    WebRtc_UWord32 numBoundingSet = 0;
    if (numSetCandidates > 0)
    {
        numBoundingSet =  FindTMMBRBoundingSet(numSetCandidates, candidateSet);
        if(numBoundingSet < 1 || (numBoundingSet > _candidateSet.sizeOfSet))
        {
            return -1;
        }
        boundingSet = &_boundingSet;
    }
    return numBoundingSet;
}


WebRtc_Word32
TMMBRHelp::FindTMMBRBoundingSet(WebRtc_Word32 numCandidates, TMMBRSet& candidateSet)
{
    CriticalSectionScoped lock(_criticalSection);

    WebRtc_UWord32 numBoundingSet = 0;
    VerifyAndAllocateBoundingSet(candidateSet.sizeOfSet);

    if (numCandidates == 1)
    {
        for (WebRtc_UWord32 i = 0; i < candidateSet.sizeOfSet; i++)
        {
            if(candidateSet.ptrTmmbrSet[i] > 0)
            {
                _boundingSet.ptrTmmbrSet[numBoundingSet]    = candidateSet.ptrTmmbrSet[i];
                _boundingSet.ptrPacketOHSet[numBoundingSet] = candidateSet.ptrPacketOHSet[i];
                _boundingSet.ptrSsrcSet[numBoundingSet]     = candidateSet.ptrSsrcSet[i];
                numBoundingSet++;
            }
        }
        if (numBoundingSet != 1)
        {
            numBoundingSet = -1;
        }
    } else
    {
        // 1. Sort by increasing packetOH
        WebRtc_UWord32 temp;
        for (int i = candidateSet.sizeOfSet - 1; i >= 0; i--)
        {
            for (int j = 1; j <= i; j++)
            {
                if (candidateSet.ptrPacketOHSet[j-1] > candidateSet.ptrPacketOHSet[j])
                {
                    temp = candidateSet.ptrPacketOHSet[j-1];
                    candidateSet.ptrPacketOHSet[j-1] = candidateSet.ptrPacketOHSet[j];
                    candidateSet.ptrPacketOHSet[j] = temp;
                    temp = candidateSet.ptrTmmbrSet[j-1];
                    candidateSet.ptrTmmbrSet[j-1] = candidateSet.ptrTmmbrSet[j];
                    candidateSet.ptrTmmbrSet[j] = temp;
                    temp = candidateSet.ptrSsrcSet[j-1];
                    candidateSet.ptrSsrcSet[j-1] = candidateSet.ptrSsrcSet[j];
                    candidateSet.ptrSsrcSet[j] = temp;
                }
            }
        }
        // 2. For tuples with same OH, keep the one w/ the lowest bitrate
        for (WebRtc_UWord32 i = 0; i < candidateSet.sizeOfSet; i++)
        {
            if (candidateSet.ptrTmmbrSet[i] > 0)
            {
                // get min bitrate for packets w/ same OH
                WebRtc_UWord32 currentPacketOH = candidateSet.ptrPacketOHSet[i];
                WebRtc_UWord32 currentMinTMMBR = candidateSet.ptrTmmbrSet[i];
                WebRtc_UWord32 currentMinIndexTMMBR = i;
                for (WebRtc_UWord32 j = i+1; j < candidateSet.sizeOfSet; j++)
                {
                    if(candidateSet.ptrPacketOHSet[j] == currentPacketOH)
                    {
                        if(candidateSet.ptrTmmbrSet[j] < currentMinTMMBR)
                        {
                            currentMinTMMBR = candidateSet.ptrTmmbrSet[j];
                            currentMinIndexTMMBR = j;
                        }
                    }
                }
                // keep lowest bitrate
                for (WebRtc_UWord32 j = 0; j < candidateSet.sizeOfSet; j++)
                {
                    if(candidateSet.ptrPacketOHSet[j] == currentPacketOH && j != currentMinIndexTMMBR)
                    {
                        candidateSet.ptrTmmbrSet[j]    = 0;
                        candidateSet.ptrPacketOHSet[j] = 0;
                        candidateSet.ptrSsrcSet[j]     = 0;
                        numCandidates--;
                    }
                }
            }
        }
        // 3. Select and remove tuple w/ lowest tmmbr. (If more than 1, choose the one w/ highest OH).
        WebRtc_UWord32 minTMMBR = 0;
        WebRtc_UWord32 minIndexTMMBR = 0;
        for (WebRtc_UWord32 i = 0; i < candidateSet.sizeOfSet; i++)
        {
            if (candidateSet.ptrTmmbrSet[i] > 0)
            {
                minTMMBR = candidateSet.ptrTmmbrSet[i];
                minIndexTMMBR = i;
                break;
            }
        }

        for (WebRtc_UWord32 i = 0; i < candidateSet.sizeOfSet; i++)
        {
            if (candidateSet.ptrTmmbrSet[i] > 0 && candidateSet.ptrTmmbrSet[i] <= minTMMBR)
            {
                // get min bitrate
                minTMMBR = candidateSet.ptrTmmbrSet[i];
                minIndexTMMBR = i;
            }
        }
        // first member of selected list
        _boundingSet.ptrTmmbrSet[numBoundingSet]    = candidateSet.ptrTmmbrSet[minIndexTMMBR];
        _boundingSet.ptrPacketOHSet[numBoundingSet] = candidateSet.ptrPacketOHSet[minIndexTMMBR];
        _boundingSet.ptrSsrcSet[numBoundingSet]     = candidateSet.ptrSsrcSet[minIndexTMMBR];
        // set intersection value
        _ptrIntersectionBoundingSet[numBoundingSet] = 0;
        // calculate its maximum packet rate (where its line crosses x-axis)
        _ptrMaxPRBoundingSet[numBoundingSet] = _boundingSet.ptrTmmbrSet[numBoundingSet]*1000 / float(8*_boundingSet.ptrPacketOHSet[numBoundingSet]);
        numBoundingSet++;
        // remove from candidate list
        candidateSet.ptrTmmbrSet[minIndexTMMBR]    = 0;
        candidateSet.ptrPacketOHSet[minIndexTMMBR] = 0;
        candidateSet.ptrSsrcSet[minIndexTMMBR]     = 0;
        numCandidates--;

        // 4. Discard from candidate list all tuple w/ lower OH (next tuple must be steeper)
        for (WebRtc_UWord32 i = 0; i < candidateSet.sizeOfSet; i++)
        {
            if(candidateSet.ptrTmmbrSet[i] > 0 && candidateSet.ptrPacketOHSet[i] < _boundingSet.ptrPacketOHSet[0])
            {
                candidateSet.ptrTmmbrSet[i]    = 0;
                candidateSet.ptrPacketOHSet[i] = 0;
                candidateSet.ptrSsrcSet[i]     = 0;
                numCandidates--;
            }
        }

        if (numCandidates == 0)
        {
            _boundingSet.lengthOfSet = numBoundingSet;
            return numBoundingSet;
        }

        bool getNewCandidate = true;
        int curCandidateTMMBR = 0;
        int curCandidateIndex = 0;
        int curCandidatePacketOH = 0;
        int curCandidateSSRC = 0;
        do
        {
            if (getNewCandidate)
            {
                // 5. Remove first remaining tuple from candidate list
                for (WebRtc_UWord32 i = 0; i < candidateSet.sizeOfSet; i++)
                {
                    if (candidateSet.ptrTmmbrSet[i] > 0)
                    {
                        curCandidateTMMBR    = candidateSet.ptrTmmbrSet[i];
                        curCandidatePacketOH = candidateSet.ptrPacketOHSet[i];
                        curCandidateSSRC     = candidateSet.ptrSsrcSet[i];
                        curCandidateIndex    = i;
                        candidateSet.ptrTmmbrSet[curCandidateIndex]    = 0;
                        candidateSet.ptrPacketOHSet[curCandidateIndex] = 0;
                        candidateSet.ptrSsrcSet[curCandidateIndex]     = 0;
                        break;
                    }
                }
            }

            // 6. Calculate packet rate and intersection of the current line with line of last tuple in selected list
            float packetRate = float(curCandidateTMMBR - _boundingSet.ptrTmmbrSet[numBoundingSet-1])*1000 / (8*(curCandidatePacketOH - _boundingSet.ptrPacketOHSet[numBoundingSet-1]));

            // 7. If the packet rate is equal or lower than intersection of last tuple in selected list,
            //    remove last tuple in selected list & go back to step 6
            if(packetRate <= _ptrIntersectionBoundingSet[numBoundingSet-1])
            {
                // remove last tuple and goto step 6
                numBoundingSet--;
                _boundingSet.ptrTmmbrSet[numBoundingSet]    = 0;
                _boundingSet.ptrPacketOHSet[numBoundingSet] = 0;
                _boundingSet.ptrSsrcSet[numBoundingSet]     = 0;
                _ptrIntersectionBoundingSet[numBoundingSet] = 0;
                _ptrMaxPRBoundingSet[numBoundingSet]        = 0;
                getNewCandidate = false;
            } else
            {
                // 8. If packet rate is lower than maximum packet rate of last tuple in selected list, add current tuple to selected list
                if (packetRate < _ptrMaxPRBoundingSet[numBoundingSet-1])
                {
                    _boundingSet.ptrTmmbrSet[numBoundingSet]    = curCandidateTMMBR;
                    _boundingSet.ptrPacketOHSet[numBoundingSet] = curCandidatePacketOH;
                    _boundingSet.ptrSsrcSet[numBoundingSet]     = curCandidateSSRC;
                    _ptrIntersectionBoundingSet[numBoundingSet] = packetRate;
                    _ptrMaxPRBoundingSet[numBoundingSet] = _boundingSet.ptrTmmbrSet[numBoundingSet]*1000 / float(8*_boundingSet.ptrPacketOHSet[numBoundingSet]);
                    numBoundingSet++;
                }
                numCandidates--;
                getNewCandidate = true;
            }

            // 9. Go back to step 5 if any tuple remains in candidate list
        } while (numCandidates > 0);
    }
    _boundingSet.lengthOfSet = numBoundingSet;
    return numBoundingSet;
}

bool
TMMBRHelp::IsOwner(const WebRtc_UWord32 ssrc,
                   const WebRtc_UWord32 length) const
{
    CriticalSectionScoped lock(_criticalSection);

    if (length == 0)
    {
        // empty bounding set
        return false;
    }

    for(WebRtc_UWord32 i = 0; (i < length) && (i < _boundingSet.sizeOfSet); ++i)
    {
        if(_boundingSet.ptrSsrcSet[i] == ssrc)
        {
            return true;
        }
    }
    return false;
}

WebRtc_Word32
TMMBRHelp::CalcMinMaxBitRate(const WebRtc_UWord32 totalPacketRate,
                             const WebRtc_UWord32 lengthOfBoundingSet,
                             WebRtc_UWord32& minBitrateKbit,
                             WebRtc_UWord32& maxBitrateKbit) const
{
    CriticalSectionScoped lock(_criticalSection);

    if (lengthOfBoundingSet <= 0 || _candidateSet.sizeOfSet == 0)
    {
        // empty bounding set
        return -1;
    }

    minBitrateKbit = 0xFFFFFFFF;
    maxBitrateKbit = 0;

    for (WebRtc_UWord32 i = 0; i < _candidateSet.sizeOfSet; ++i)
    {
        if (_candidateSet.ptrTmmbrSet[i])
        {
            WebRtc_Word32 curNetBitRate = static_cast<WebRtc_Word32>((_candidateSet.ptrTmmbrSet[i]*1000.0
                            - (totalPacketRate * (_candidateSet.ptrPacketOHSet[i] << 3)))/1000 + 0.5);

        if (curNetBitRate < 0)
        {
            // could be negative for a large packet rate
            if(_audio)
            {
                curNetBitRate = MIN_AUDIO_BW_MANAGEMENT_BITRATE;
            }else
            {
                curNetBitRate = MIN_VIDEO_BW_MANAGEMENT_BITRATE;
            }
        }
            minBitrateKbit = (WebRtc_UWord32(curNetBitRate) < minBitrateKbit) ? curNetBitRate : minBitrateKbit;
        }
    }
    maxBitrateKbit = minBitrateKbit;

    if (maxBitrateKbit == 0 || maxBitrateKbit < minBitrateKbit)
    {
        return -1;
    }

    if(_audio)
    {
        if (minBitrateKbit < MIN_AUDIO_BW_MANAGEMENT_BITRATE)
        {
            minBitrateKbit = MIN_AUDIO_BW_MANAGEMENT_BITRATE;
        }
        if (maxBitrateKbit < MIN_AUDIO_BW_MANAGEMENT_BITRATE)
        {
            maxBitrateKbit = MIN_AUDIO_BW_MANAGEMENT_BITRATE;
        }
    }else
    {
        if (minBitrateKbit < MIN_VIDEO_BW_MANAGEMENT_BITRATE)
        {
            minBitrateKbit = MIN_VIDEO_BW_MANAGEMENT_BITRATE;
        }
        if (maxBitrateKbit < MIN_VIDEO_BW_MANAGEMENT_BITRATE)
        {
            maxBitrateKbit = MIN_VIDEO_BW_MANAGEMENT_BITRATE;
        }
    }

    return 0;
}
} // namespace webrtc