Example #1
0
static bool
checker_ (ImageBuf &dst, Dim3 size,
          const float *color1, const float *color2,
          Dim3 offset,
          ROI roi, int nthreads=1)
{
    if (nthreads != 1 && roi.npixels() >= 1000) {
        // Lots of pixels and request for multi threads? Parallelize.
        ImageBufAlgo::parallel_image (
            OIIO::bind(checker_<T>, OIIO::ref(dst),
                        size, color1, color2, offset,
                        _1 /*roi*/, 1 /*nthreads*/),
            roi, nthreads);
        return true;
    }

    // Serial case
    for (ImageBuf::Iterator<T> p (dst, roi);  !p.done();  ++p) {
        int xtile = (p.x()-offset.x)/size.x;  xtile += (p.x()<offset.x);
        int ytile = (p.y()-offset.y)/size.y;  ytile += (p.y()<offset.y);
        int ztile = (p.z()-offset.z)/size.z;  ztile += (p.z()<offset.z);
        int v = xtile + ytile + ztile;
        if (v & 1)
            for (int c = roi.chbegin;  c < roi.chend;  ++c)
                p[c] = color2[c];
        else
            for (int c = roi.chbegin;  c < roi.chend;  ++c)
                p[c] = color1[c];
    }
    return true;
}
Example #2
0
bool
ImageBufAlgo::make_kernel (ImageBuf &dst, string_view name,
                           float width, float height, float depth,
                           bool normalize)
{
    int w = std::max (1, (int)ceilf(width));
    int h = std::max (1, (int)ceilf(height));
    int d = std::max (1, (int)ceilf(depth));
    // Round up size to odd
    w |= 1;
    h |= 1;
    d |= 1;
    ImageSpec spec (w, h, 1 /*channels*/, TypeDesc::FLOAT);
    spec.depth = d;
    spec.x = -w/2;
    spec.y = -h/2;
    spec.z = -d/2;
    spec.full_x = spec.x;
    spec.full_y = spec.y;
    spec.full_z = spec.z;
    spec.full_width = spec.width;
    spec.full_height = spec.height;
    spec.full_depth = spec.depth;
    dst.reset (spec);

    if (Filter2D *filter = Filter2D::create (name, width, height)) {
        // Named continuous filter from filter.h
        for (ImageBuf::Iterator<float> p (dst);  ! p.done();  ++p)
            p[0] = (*filter)((float)p.x(), (float)p.y());
        delete filter;
    } else if (name == "binomial") {
        // Binomial filter
        float *wfilter = ALLOCA (float, width);
        for (int i = 0;  i < width;  ++i)
            wfilter[i] = binomial (width-1, i);
        float *hfilter = (height == width) ? wfilter : ALLOCA (float, height);
        if (height != width)
            for (int i = 0;  i < height;  ++i)
                hfilter[i] = binomial (height-1, i);
        float *dfilter = ALLOCA (float, depth);
        if (depth == 1)
            dfilter[0] = 1;
        else
            for (int i = 0;  i < depth;  ++i)
                dfilter[i] = binomial (depth-1, i);
        for (ImageBuf::Iterator<float> p (dst);  ! p.done();  ++p)
            p[0] = wfilter[p.x()-spec.x] * hfilter[p.y()-spec.y] * dfilter[p.z()-spec.z];
    } else {
Example #3
0
static int
action_flip (int argc, const char *argv[])
{
    if (ot.postpone_callback (1, action_flip, argc, argv))
        return 0;

    ot.read ();
    ImageRecRef A = ot.pop();
    ot.push (new ImageRec (*A, ot.allsubimages ? -1 : 0,
                           ot.allsubimages ? -1 : 0, true, false));

    int subimages = ot.curimg->subimages();
    for (int s = 0;  s < subimages;  ++s) {
        int miplevels = ot.curimg->miplevels(s);
        for (int m = 0;  m < miplevels;  ++m) {
            const ImageBuf &Aib ((*A)(s,m));
            ImageBuf &Rib ((*ot.curimg)(s,m));
            ImageBuf::ConstIterator<float> a (Aib);
            ImageBuf::Iterator<float> r (Rib);
            int nchans = Rib.nchannels();
            int firstscanline = Rib.ymin();
            int lastscanline = Rib.ymax();
            for ( ; ! r.done(); ++r) {
                a.pos (r.x(), lastscanline - (r.y() - firstscanline));
                for (int c = 0;  c < nchans;  ++c)
                    r[c] = a[c];
            }
        }
    }
             
    return 0;
}
Example #4
0
static bool
noise_salt_ (ImageBuf &dst, float saltval, float saltportion, bool mono,
             int seed, ROI roi, int nthreads)
{
    if (nthreads != 1 && roi.npixels() >= 1000) {
        // Lots of pixels and request for multi threads? Parallelize.
        ImageBufAlgo::parallel_image (
            OIIO::bind(noise_salt_<T>, OIIO::ref(dst),
                        saltval, saltportion, mono, seed,
                        _1 /*roi*/, 1 /*nthreads*/),
            roi, nthreads);
        return true;
    }

    // Serial case
    for (ImageBuf::Iterator<T> p (dst, roi);  !p.done();  ++p) {
        int x = p.x(), y = p.y(), z = p.z();
        float n = 0.0;
        for (int c = roi.chbegin;  c < roi.chend;  ++c) {
            if (c == roi.chbegin || !mono)
                n = hashrand (x, y, z, c, seed);
            if (n < saltportion)
                p[c] = saltval;
        }
    }
    return true;
}
Example #5
0
static bool
noise_gaussian_ (ImageBuf &dst, float mean, float stddev, bool mono,
                 int seed, ROI roi, int nthreads)
{
    if (nthreads != 1 && roi.npixels() >= 1000) {
        // Lots of pixels and request for multi threads? Parallelize.
        ImageBufAlgo::parallel_image (
            OIIO::bind(noise_gaussian_<T>, OIIO::ref(dst),
                        mean, stddev, mono, seed,
                        _1 /*roi*/, 1 /*nthreads*/),
            roi, nthreads);
        return true;
    }

    // Serial case
    for (ImageBuf::Iterator<T> p (dst, roi);  !p.done();  ++p) {
        int x = p.x(), y = p.y(), z = p.z();
        float n = 0.0;
        for (int c = roi.chbegin;  c < roi.chend;  ++c) {
            if (c == roi.chbegin || !mono)
                n = mean + stddev * hashnormal (x, y, z, c, seed);
            p[c] = p[c] + n;
        }
    }
    return true;
}
Example #6
0
static bool
fill_corners_ (ImageBuf &dst, const float *topleft, const float *topright,
       const float *bottomleft, const float *bottomright,
       ROI origroi, ROI roi=ROI(), int nthreads=1)
{
    if (nthreads != 1 && roi.npixels() >= 1000) {
        // Lots of pixels and request for multi threads? Parallelize.
        ImageBufAlgo::parallel_image (
            OIIO::bind(fill_corners_<T>, OIIO::ref(dst), topleft, topright,
                        bottomleft, bottomright,
                        origroi, _1 /*roi*/, 1 /*nthreads*/),
            roi, nthreads);
        return true;
    }

    // Serial case
    float w = std::max (1, origroi.width() - 1);
    float h = std::max (1, origroi.height() - 1);
    for (ImageBuf::Iterator<T> p (dst, roi);  !p.done();  ++p) {
        float u = (p.x() - origroi.xbegin) / w;
        float v = (p.y() - origroi.ybegin) / h;
        for (int c = roi.chbegin;  c < roi.chend;  ++c)
            p[c] = bilerp (topleft[c], topright[c],
                           bottomleft[c], bottomright[c], u, v);
    }
    return true;
}
Example #7
0
static bool
flop_ (ImageBuf &dst, const ImageBuf &src, ROI roi, int nthreads)
{
    ImageBuf::ConstIterator<S, D> s (src, roi);
    ImageBuf::Iterator<D, D> d (dst, roi);
    for ( ; ! d.done(); ++d) {
        s.pos (roi.xend-1 - (d.x() - roi.xbegin), d.y(), d.z());
        for (int c = roi.chbegin; c < roi.chend; ++c)
            d[c] = s[c];
    }
    return true;
}
static bool
flip_ (ImageBuf &dst, const ImageBuf &src, ROI dst_roi, int nthreads)
{
    ROI src_roi_full = src.roi_full();
    ROI dst_roi_full = dst.roi_full();
    ImageBuf::ConstIterator<S, D> s (src);
    ImageBuf::Iterator<D, D> d (dst, dst_roi);
    for ( ; ! d.done(); ++d) {
        int yy = d.y() - dst_roi_full.ybegin;
        s.pos (d.x(), src_roi_full.yend-1 - yy, d.z());
        for (int c = dst_roi.chbegin; c < dst_roi.chend; ++c)
            d[c] = s[c];
    }
    return true;
}
static bool
rotate270_ (ImageBuf &dst, const ImageBuf &src, ROI dst_roi, int nthreads)
{
    ROI dst_roi_full = dst.roi_full();
    ImageBuf::ConstIterator<S, D> s (src);
    ImageBuf::Iterator<D, D> d (dst, dst_roi);
    for ( ; ! d.done(); ++d) {
        s.pos (dst_roi_full.yend - d.y() - 1,
               d.x(),
               d.z());
        for (int c = dst_roi.chbegin; c < dst_roi.chend; ++c)
            d[c] = s[c];
    }
    return true;
}
Example #10
0
static bool
convolve_ (ImageBuf &dst, const ImageBuf &src, const ImageBuf &kernel,
           bool normalize, ROI roi, int nthreads)
{
    if (nthreads != 1 && roi.npixels() >= 1000) {
        // Lots of pixels and request for multi threads? Parallelize.
        ImageBufAlgo::parallel_image (
            boost::bind(convolve_<DSTTYPE,SRCTYPE>, boost::ref(dst),
                        boost::cref(src), boost::cref(kernel), normalize,
                        _1 /*roi*/, 1 /*nthreads*/),
            roi, nthreads);
        return true;
    }

    // Serial case

    float scale = 1.0f;
    if (normalize) {
        scale = 0.0f;
        for (ImageBuf::ConstIterator<float> k (kernel); ! k.done(); ++k)
            scale += k[0];
        scale = 1.0f / scale;
    }

    float *sum = ALLOCA (float, roi.chend);
    ROI kroi = get_roi (kernel.spec());
    ImageBuf::Iterator<DSTTYPE> d (dst, roi);
    ImageBuf::ConstIterator<SRCTYPE> s (src, roi, ImageBuf::WrapClamp);
    for ( ; ! d.done();  ++d) {

        for (int c = roi.chbegin; c < roi.chend; ++c)
            sum[c] = 0.0f;

        for (ImageBuf::ConstIterator<float> k (kernel, kroi); !k.done(); ++k) {
            float kval = k[0];
            s.pos (d.x() + k.x(), d.y() + k.y(), d.z() + k.z());
            for (int c = roi.chbegin; c < roi.chend; ++c)
                sum[c] += kval * s[c];
        }
        
        for (int c = roi.chbegin; c < roi.chend; ++c)
            d[c] = scale * sum[c];
    }

    return true;
}
Example #11
0
static int
action_sub (int argc, const char *argv[])
{
    if (ot.postpone_callback (2, action_sub, argc, argv))
        return 0;

    ImageRecRef B (ot.pop());
    ImageRecRef A (ot.pop());
    ot.read (A);
    ot.read (B);
    ot.push (new ImageRec (*A, ot.allsubimages ? -1 : 0,
                           ot.allsubimages ? -1 : 0, true, false));

    int subimages = ot.curimg->subimages();
    for (int s = 0;  s < subimages;  ++s) {
        int miplevels = ot.curimg->miplevels(s);
        for (int m = 0;  m < miplevels;  ++m) {
            const ImageBuf &Aib ((*A)(s,m));
            const ImageBuf &Bib ((*B)(s,m));
            if (! same_size (Aib, Bib)) {
                // FIXME: some day, there should be options of combining
                // differing images somehow.
                std::cerr << "oiiotool: " << argv[0] << " could not combine images of differing sizes\n";
                continue;
            }
            ImageBuf &Rib ((*ot.curimg)(s,m));
            ImageBuf::ConstIterator<float> a (Aib);
            ImageBuf::ConstIterator<float> b (Bib);
            ImageBuf::Iterator<float> r (Rib);
            int nchans = Rib.nchannels();
            for ( ; ! r.done(); ++r) {
                a.pos (r.x(), r.y());
                b.pos (r.x(), r.y());
                for (int c = 0;  c < nchans;  ++c)
                    r[c] = a[c] - b[c];
            }
        }
    }
             
    return 0;
}
void test_paste ()
{
    std::cout << "test paste\n";
    // Create the source image, make it a gradient
    ImageSpec Aspec (4, 4, 3, TypeDesc::FLOAT);
    ImageBuf A (Aspec);
    for (ImageBuf::Iterator<float> it (A);  !it.done();  ++it) {
        it[0] = float(it.x()) / float(Aspec.width-1);
        it[1] = float(it.y()) / float(Aspec.height-1);
        it[2] = 0.1f;
    }

    // Create destination image -- black it out
    ImageSpec Bspec (8, 8, 3, TypeDesc::FLOAT);
    ImageBuf B (Bspec);
    float gray[3] = { .1, .1, .1 };
    ImageBufAlgo::fill (B, gray);

    // Paste a few pixels from A into B -- include offsets
    ImageBufAlgo::paste (B, 2, 2, 0, 1 /* chan offset */,
                         A, ROI(1, 4, 1, 4));

    // Spot check
    float a[3], b[3];
    B.getpixel (1, 1, 0, b);
    OIIO_CHECK_EQUAL (b[0], gray[0]);
    OIIO_CHECK_EQUAL (b[1], gray[1]);
    OIIO_CHECK_EQUAL (b[2], gray[2]);

    B.getpixel (2, 2, 0, b);
    A.getpixel (1, 1, 0, a);
    OIIO_CHECK_EQUAL (b[0], gray[0]);
    OIIO_CHECK_EQUAL (b[1], a[0]);
    OIIO_CHECK_EQUAL (b[2], a[1]);

    B.getpixel (3, 4, 0, b);
    A.getpixel (2, 3, 0, a);
    OIIO_CHECK_EQUAL (b[0], gray[0]);
    OIIO_CHECK_EQUAL (b[1], a[0]);
    OIIO_CHECK_EQUAL (b[2], a[1]);
}
Example #13
0
static bool
resize_ (ImageBuf &dst, const ImageBuf &src,
         Filter2D *filter, ROI roi, int nthreads)
{
    if (nthreads != 1 && roi.npixels() >= 1000) {
        // Lots of pixels and request for multi threads? Parallelize.
        ImageBufAlgo::parallel_image (
            boost::bind(resize_<DSTTYPE,SRCTYPE>, boost::ref(dst),
                        boost::cref(src), filter,
                        _1 /*roi*/, 1 /*nthreads*/),
            roi, nthreads);
        return true;
    }

    // Serial case

    const ImageSpec &srcspec (src.spec());
    const ImageSpec &dstspec (dst.spec());
    int nchannels = dstspec.nchannels;

    // Local copies of the source image window, converted to float
    float srcfx = srcspec.full_x;
    float srcfy = srcspec.full_y;
    float srcfw = srcspec.full_width;
    float srcfh = srcspec.full_height;

    // Ratios of dst/src size.  Values larger than 1 indicate that we
    // are maximizing (enlarging the image), and thus want to smoothly
    // interpolate.  Values less than 1 indicate that we are minimizing
    // (shrinking the image), and thus want to properly filter out the
    // high frequencies.
    float xratio = float(dstspec.full_width) / srcfw; // 2 upsize, 0.5 downsize
    float yratio = float(dstspec.full_height) / srcfh;

    float dstfx = dstspec.full_x;
    float dstfy = dstspec.full_y;
    float dstfw = dstspec.full_width;
    float dstfh = dstspec.full_height;
    float dstpixelwidth = 1.0f / dstfw;
    float dstpixelheight = 1.0f / dstfh;
    float *pel = ALLOCA (float, nchannels);
    float filterrad = filter->width() / 2.0f;

    // radi,radj is the filter radius, as an integer, in source pixels.  We
    // will filter the source over [x-radi, x+radi] X [y-radj,y+radj].
    int radi = (int) ceilf (filterrad/xratio);
    int radj = (int) ceilf (filterrad/yratio);
    int xtaps = 2*radi + 1;
    int ytaps = 2*radj + 1;
    bool separable = filter->separable();
    float *xfiltval = NULL, *yfiltval = NULL;
    if (separable) {
        // Allocate temp space to cache the filter weights
        xfiltval = ALLOCA (float, xtaps);
        yfiltval = ALLOCA (float, ytaps);
    }
#if 0
    std::cerr << "Resizing " << srcspec.full_width << "x" << srcspec.full_height
              << " to " << dstspec.full_width << "x" << dstspec.full_height << "\n";
    std::cerr << "ratios = " << xratio << ", " << yratio << "\n";
    std::cerr << "examining src filter support radius of " << radi << " x " << radj << " pixels\n";
    std::cerr << "dst range " << roi << "\n";
    std::cerr << "separable filter\n";
#endif


    // We're going to loop over all output pixels we're interested in.
    //
    // (s,t) = NDC space coordinates of the output sample we are computing.
    //     This is the "sample point".
    // (src_xf, src_xf) = source pixel space float coordinates of the
    //     sample we're computing. We want to compute the weighted sum
    //     of all the source image pixels that fall under the filter when
    //     centered at that location.
    // (src_x, src_y) = image space integer coordinates of the floor,
    //     i.e., the closest pixel in the source image.
    // src_xf_frac and src_yf_frac are the position within that pixel
    //     of our sample.
    ImageBuf::Iterator<DSTTYPE> out (dst, roi);
    for (int y = roi.ybegin;  y < roi.yend;  ++y) {
        float t = (y-dstfy+0.5f)*dstpixelheight;
        float src_yf = srcfy + t * srcfh;
        int src_y;
        float src_yf_frac = floorfrac (src_yf, &src_y);

        // If using separable filters, our vertical set of filter tap
        // weights will be the same for the whole scanline we're on.  Just
        // compute and normalize them once.
        float totalweight_y = 0.0f;
        if (separable) {
            for (int j = 0;  j < ytaps;  ++j) {
                float w = filter->yfilt (yratio * (j-radj-(src_yf_frac-0.5f)));
                yfiltval[j] = w;
                totalweight_y += w;
            }
            for (int i = 0;  i <= ytaps;  ++i)
                yfiltval[i] /= totalweight_y;
        }

        for (int x = roi.xbegin;  x < roi.xend;  ++x) {
            float s = (x-dstfx+0.5f)*dstpixelwidth;
            float src_xf = srcfx + s * srcfw;
            int src_x;
            float src_xf_frac = floorfrac (src_xf, &src_x);
            for (int c = 0;  c < nchannels;  ++c)
                pel[c] = 0.0f;
            if (separable) {
                // Cache and normalize the horizontal filter tap weights
                // just once for this (x,y) position, reuse for all vertical
                // taps.
                float totalweight_x = 0.0f;
                for (int i = 0;  i < xtaps;  ++i) {
                    float w = filter->xfilt (xratio * (i-radi-(src_xf_frac-0.5f)));
                    xfiltval[i] = w;
                    totalweight_x += w;
                }

                if (totalweight_x != 0.0f) {
                    for (int i = 0;  i < xtaps;  ++i)  // normalize x filter
                        xfiltval[i] /= totalweight_x;  // weights
                    ImageBuf::ConstIterator<SRCTYPE> srcpel (src, src_x-radi, src_x+radi+1,
                                                             src_y-radj, src_y+radj+1,
                                                             0, 1, ImageBuf::WrapClamp);
                    for (int j = -radj;  j <= radj;  ++j) {
                        float wy = yfiltval[j+radj];
                        if (wy == 0.0f) {
                            // 0 weight for this y tap -- move to next line
                            srcpel.pos (srcpel.x(), srcpel.y()+1, srcpel.z());
                            continue;
                        }
                        for (int i = 0;  i < xtaps; ++i, ++srcpel) {
                            float w = wy * xfiltval[i];
                            for (int c = 0;  c < nchannels;  ++c)
                                pel[c] += w * srcpel[c];
                        }
                    }
                }
                // Copy the pixel value (already normalized) to the output.
                DASSERT (out.x() == x && out.y() == y);
                if (totalweight_y == 0.0f) {
                    // zero it out
                    for (int c = 0;  c < nchannels;  ++c)
                        out[c] = 0.0f;
                } else {
                    for (int c = 0;  c < nchannels;  ++c)
                        out[c] = pel[c];
                }
            } else {
                // Non-separable
                float totalweight = 0.0f;
                ImageBuf::ConstIterator<SRCTYPE> srcpel (src, src_x-radi, src_x+radi+1,
                                                       src_y-radi, src_y+radi+1,
                                                       0, 1, ImageBuf::WrapClamp);
                for (int j = -radj;  j <= radj;  ++j) {
                    for (int i = -radi;  i <= radi;  ++i, ++srcpel) {
                        float w = (*filter)(xratio * (i-(src_xf_frac-0.5f)),
                                            yratio * (j-(src_yf_frac-0.5f)));
                        totalweight += w;
                        if (w == 0.0f)
                            continue;
                        DASSERT (! srcpel.done());
                        for (int c = 0;  c < nchannels;  ++c)
                            pel[c] += w * srcpel[c];
                    }
                }
                DASSERT (srcpel.done());
                // Rescale pel to normalize the filter and write it to the
                // output image.
                DASSERT (out.x() == x && out.y() == y);
                if (totalweight == 0.0f) {
                    // zero it out
                    for (int c = 0;  c < nchannels;  ++c)
                        out[c] = 0.0f;
                } else {
                    for (int c = 0;  c < nchannels;  ++c)
                        out[c] = pel[c] / totalweight;
                }
            }

            ++out;
        }
    }

    return true;
}
Example #14
0
static bool
flatten_ (ImageBuf &dst, const ImageBuf &src, 
          ROI roi, int nthreads)
{
    if (nthreads != 1 && roi.npixels() >= 1000) {
        // Possible multiple thread case -- recurse via parallel_image
        ImageBufAlgo::parallel_image (
            boost::bind(flatten_<DSTTYPE>, boost::ref(dst), boost::cref(src),
                        _1 /*roi*/, 1 /*nthreads*/),
            roi, nthreads);
        return true;
    }

    const ImageSpec &srcspec (src.spec());
    int nc = srcspec.nchannels;

    int alpha_channel, RA_channel, GA_channel, BA_channel;
    int R_channel, G_channel, B_channel;
    int Z_channel, Zback_channel;
    if (! find_deep_channels (srcspec, alpha_channel,
                              RA_channel, GA_channel, BA_channel,
                              R_channel, G_channel, B_channel,
                              Z_channel, Zback_channel)) {
        dst.error ("No alpha channel could be identified");
        return false;
    }
    ASSERT (alpha_channel >= 0 ||
            (RA_channel >= 0 && GA_channel >= 0 && BA_channel >= 0));
    float *val = ALLOCA (float, nc);
    float &RAval (RA_channel >= 0 ? val[RA_channel] : val[alpha_channel]);
    float &GAval (GA_channel >= 0 ? val[GA_channel] : val[alpha_channel]);
    float &BAval (BA_channel >= 0 ? val[BA_channel] : val[alpha_channel]);

    for (ImageBuf::Iterator<DSTTYPE> r (dst, roi);  !r.done();  ++r) {
        int x = r.x(), y = r.y(), z = r.z();
        int samps = src.deep_samples (x, y, z);
        // Clear accumulated values for this pixel (0 for colors, big for Z)
        memset (val, 0, nc*sizeof(float));
        if (Z_channel >= 0 && samps == 0)
            val[Z_channel] = 1.0e30;
        if (Zback_channel >= 0 && samps == 0)
            val[Zback_channel] = 1.0e30;
        for (int s = 0;  s < samps;  ++s) {
            float RA = RAval, GA = GAval, BA = BAval;  // make copies
            float alpha = (RA + GA + BA) / 3.0f;
            if (alpha >= 1.0f)
                break;
            for (int c = 0;  c < nc;  ++c) {
                float v = src.deep_value (x, y, z, c, s);
                if (c == Z_channel || c == Zback_channel)
                    val[c] *= alpha;  // because Z are not premultiplied
                float a;
                if (c == R_channel)
                    a = RA;
                else if (c == G_channel)
                    a = GA;
                else if (c == B_channel)
                    a = BA;
                else
                    a = alpha;
                val[c] += (1.0f - a) * v;
            }
        }

        for (int c = roi.chbegin;  c < roi.chend;  ++c)
            r[c] = val[c];
    }

    return true;
}