OpenMW/components/terrain/buffercache.cpp

#include "buffercache.hpp"

#include <OgreHardwareBufferManager.h>

#include "defs.hpp"

namespace Terrain
{

    Ogre::HardwareVertexBufferSharedPtr BufferCache::getUVBuffer()
    {
        if (mUvBufferMap.find(mNumVerts) != mUvBufferMap.end())
        {
            return mUvBufferMap[mNumVerts];
        }

        int vertexCount = mNumVerts * mNumVerts;

        std::vector<float> uvs;
        uvs.reserve(vertexCount*2);

        for (unsigned int col = 0; col < mNumVerts; ++col)
        {
            for (unsigned int row = 0; row < mNumVerts; ++row)
            {
                uvs.push_back(col / static_cast<float>(mNumVerts-1)); // U
                uvs.push_back(row / static_cast<float>(mNumVerts-1)); // V
            }
        }

        Ogre::HardwareBufferManager* mgr = Ogre::HardwareBufferManager::getSingletonPtr();
        Ogre::HardwareVertexBufferSharedPtr buffer = mgr->createVertexBuffer(
                    Ogre::VertexElement::getTypeSize(Ogre::VET_FLOAT2),
                                                vertexCount, Ogre::HardwareBuffer::HBU_STATIC);

        buffer->writeData(0, buffer->getSizeInBytes(), &uvs[0], true);

        mUvBufferMap[mNumVerts] = buffer;
        return buffer;
    }

    Ogre::HardwareIndexBufferSharedPtr BufferCache::getIndexBuffer(int flags)
    {
        unsigned int verts = mNumVerts;

        if (mIndexBufferMap.find(flags) != mIndexBufferMap.end())
        {
            return mIndexBufferMap[flags];
        }

        // LOD level n means every 2^n-th vertex is kept
        size_t lodLevel = (flags >> (4*4));

        size_t lodDeltas[4];
        for (int i=0; i<4; ++i)
            lodDeltas[i] = (flags >> (4*i)) & (0xf);

        bool anyDeltas = (lodDeltas[North] || lodDeltas[South] || lodDeltas[West] || lodDeltas[East]);

        size_t increment = 1 << lodLevel;
        assert(increment < verts);
        std::vector<short> indices;
        indices.reserve((verts-1)*(verts-1)*2*3 / increment);

        size_t rowStart = 0, colStart = 0, rowEnd = verts-1, colEnd = verts-1;
        // If any edge needs stitching we'll skip all edges at this point,
        // mainly because stitching one edge would have an effect on corners and on the adjacent edges
        if (anyDeltas)
        {
            colStart += increment;
            colEnd -= increment;
            rowEnd -= increment;
            rowStart += increment;
        }
        for (size_t row = rowStart; row < rowEnd; row += increment)
        {
            for (size_t col = colStart; col < colEnd; col += increment)
            {
                indices.push_back(verts*col+row);
                indices.push_back(verts*(col+increment)+row+increment);
                indices.push_back(verts*col+row+increment);

                indices.push_back(verts*col+row);
                indices.push_back(verts*(col+increment)+row);
                indices.push_back(verts*(col+increment)+row+increment);
            }
        }

        size_t innerStep = increment;
        if (anyDeltas)
        {
            // Now configure LOD transitions at the edges - this is pretty tedious,
            // and some very long and boring code, but it works great

            // South
            size_t row = 0;
            size_t outerStep = 1 << (lodDeltas[South] + lodLevel);
            for (size_t col = 0; col < verts-1; col += outerStep)
            {
                indices.push_back(verts*col+row);
                indices.push_back(verts*(col+outerStep)+row);
                // Make sure not to touch the right edge
                if (col+outerStep == verts-1)
                    indices.push_back(verts*(col+outerStep-innerStep)+row+innerStep);
                else
                    indices.push_back(verts*(col+outerStep)+row+innerStep);

                for (size_t i = 0; i < outerStep; i += innerStep)
                {
                    // Make sure not to touch the left or right edges
                    if (col+i == 0 || col+i == verts-1-innerStep)
                        continue;
                    indices.push_back(verts*(col)+row);
                    indices.push_back(verts*(col+i+innerStep)+row+innerStep);
                    indices.push_back(verts*(col+i)+row+innerStep);
                }
            }

            // North
            row = verts-1;
            outerStep = 1 << (lodDeltas[North] + lodLevel);
            for (size_t col = 0; col < verts-1; col += outerStep)
            {
                indices.push_back(verts*(col+outerStep)+row);
                indices.push_back(verts*col+row);
                // Make sure not to touch the left edge
                if (col == 0)
                    indices.push_back(verts*(col+innerStep)+row-innerStep);
                else
                    indices.push_back(verts*col+row-innerStep);

                for (size_t i = 0; i < outerStep; i += innerStep)
                {
                    // Make sure not to touch the left or right edges
                    if (col+i == 0 || col+i == verts-1-innerStep)
                        continue;
                    indices.push_back(verts*(col+i)+row-innerStep);
                    indices.push_back(verts*(col+i+innerStep)+row-innerStep);
                    indices.push_back(verts*(col+outerStep)+row);
                }
            }

            // West
            size_t col = 0;
            outerStep = 1 << (lodDeltas[West] + lodLevel);
            for (size_t row = 0; row < verts-1; row += outerStep)
            {
                indices.push_back(verts*col+row+outerStep);
                indices.push_back(verts*col+row);
                // Make sure not to touch the top edge
                if (row+outerStep == verts-1)
                    indices.push_back(verts*(col+innerStep)+row+outerStep-innerStep);
                else
                    indices.push_back(verts*(col+innerStep)+row+outerStep);

                for (size_t i = 0; i < outerStep; i += innerStep)
                {
                    // Make sure not to touch the top or bottom edges
                    if (row+i == 0 || row+i == verts-1-innerStep)
                        continue;
                    indices.push_back(verts*col+row);
                    indices.push_back(verts*(col+innerStep)+row+i);
                    indices.push_back(verts*(col+innerStep)+row+i+innerStep);
                }
            }

            // East
            col = verts-1;
            outerStep = 1 << (lodDeltas[East] + lodLevel);
            for (size_t row = 0; row < verts-1; row += outerStep)
            {
                indices.push_back(verts*col+row);
                indices.push_back(verts*col+row+outerStep);
                // Make sure not to touch the bottom edge
                if (row == 0)
                    indices.push_back(verts*(col-innerStep)+row+innerStep);
                else
                    indices.push_back(verts*(col-innerStep)+row);

                for (size_t i = 0; i < outerStep; i += innerStep)
                {
                    // Make sure not to touch the top or bottom edges
                    if (row+i == 0 || row+i == verts-1-innerStep)
                        continue;
                    indices.push_back(verts*col+row+outerStep);
                    indices.push_back(verts*(col-innerStep)+row+i+innerStep);
                    indices.push_back(verts*(col-innerStep)+row+i);
                }
            }
        }

        Ogre::HardwareBufferManager* mgr = Ogre::HardwareBufferManager::getSingletonPtr();
        Ogre::HardwareIndexBufferSharedPtr buffer = mgr->createIndexBuffer(Ogre::HardwareIndexBuffer::IT_16BIT,
                                                                           indices.size(), Ogre::HardwareBuffer::HBU_STATIC);
        buffer->writeData(0, buffer->getSizeInBytes(), &indices[0], true);
        mIndexBufferMap[flags] = buffer;
        return buffer;
    }

}