Print the version string after the command line has been parsed.

[mplayer/glamo.git] / libass / ass_bitmap.c

// -*- c-basic-offset: 8; indent-tabs-mode: t -*-
// vim:ts=8:sw=8:noet:ai:
/*
 * Copyright (C) 2006 Evgeniy Stepanov <eugeni.stepanov@gmail.com>
 *
 * This file is part of libass.
 *
 * libass is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; either version 2 of the License, or
 * (at your option) any later version.
 *
 * libass is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License along
 * with libass; if not, write to the Free Software Foundation, Inc.,
 * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
 */

#include <stdlib.h>
#include <string.h>
#include <math.h>
#include <assert.h>
#include <ft2build.h>
#include FT_GLYPH_H

#include "mputils.h"
#include "ass_bitmap.h"

struct ass_synth_priv_s {
        int tmp_w, tmp_h;
        unsigned short* tmp;

        int g_r;
        int g_w;

        unsigned *g;
        unsigned *gt2;

        double radius;
};

static const unsigned int maxcolor = 255;
static const unsigned base = 256;

static int generate_tables(ass_synth_priv_t* priv, double radius)
{
        double A = log(1.0/base)/(radius*radius*2);
        int mx, i;
        double volume_diff, volume_factor = 0;
        unsigned volume;

        if (priv->radius == radius)
                return 0;
        else
                priv->radius = radius;

        priv->g_r = ceil(radius);
        priv->g_w = 2*priv->g_r+1;

        if (priv->g_r) {
                priv->g = malloc(priv->g_w * sizeof(unsigned));
                priv->gt2 = malloc(256 * priv->g_w * sizeof(unsigned));
                if (priv->g==NULL || priv->gt2==NULL) {
                        return -1;
                }
        }

        if (priv->g_r) {
                // gaussian curve with volume = 256
                for (volume_diff=10000000; volume_diff>0.0000001; volume_diff*=0.5){
                        volume_factor+= volume_diff;
                        volume=0;
                        for (i = 0; i<priv->g_w; ++i) {
                                priv->g[i] = (unsigned)(exp(A * (i-priv->g_r)*(i-priv->g_r)) * volume_factor + .5);
                                volume+= priv->g[i];
                        }
                        if(volume>256) volume_factor-= volume_diff;
                }
                volume=0;
                for (i = 0; i<priv->g_w; ++i) {
                        priv->g[i] = (unsigned)(exp(A * (i-priv->g_r)*(i-priv->g_r)) * volume_factor + .5);
                        volume+= priv->g[i];
                }

                // gauss table:
                for(mx=0;mx<priv->g_w;mx++){
                        for(i=0;i<256;i++){
                                priv->gt2[mx+i*priv->g_w] = i*priv->g[mx];
                        }
                }
        }

        return 0;
}

static void resize_tmp(ass_synth_priv_t* priv, int w, int h)
{
        if (priv->tmp_w >= w && priv->tmp_h >= h)
                return;
        if (priv->tmp_w == 0)
                priv->tmp_w = 64;
        if (priv->tmp_h == 0)
                priv->tmp_h = 64;
        while (priv->tmp_w < w) priv->tmp_w *= 2;
        while (priv->tmp_h < h) priv->tmp_h *= 2;
        if (priv->tmp)
                free(priv->tmp);
        priv->tmp = malloc((priv->tmp_w + 1) * priv->tmp_h * sizeof(short));
}

ass_synth_priv_t* ass_synth_init(double radius)
{
        ass_synth_priv_t* priv = calloc(1, sizeof(ass_synth_priv_t));
        generate_tables(priv, radius);
        return priv;
}

void ass_synth_done(ass_synth_priv_t* priv)
{
        if (priv->tmp)
                free(priv->tmp);
        if (priv->g)
                free(priv->g);
        if (priv->gt2)
                free(priv->gt2);
        free(priv);
}

static bitmap_t* alloc_bitmap(int w, int h)
{
        bitmap_t* bm;
        bm = calloc(1, sizeof(bitmap_t));
        bm->buffer = malloc(w*h);
        bm->w = w;
        bm->h = h;
        bm->left = bm->top = 0;
        return bm;
}

void ass_free_bitmap(bitmap_t* bm)
{
        if (bm) {
                if (bm->buffer) free(bm->buffer);
                free(bm);
        }
}

static bitmap_t* copy_bitmap(const bitmap_t* src)
{
        bitmap_t* dst = alloc_bitmap(src->w, src->h);
        dst->left = src->left;
        dst->top = src->top;
        memcpy(dst->buffer, src->buffer, src->w * src->h);
        return dst;
}

static int check_glyph_area(FT_Glyph glyph)
{
        FT_BBox bbox;
        long long dx, dy;
        FT_Glyph_Get_CBox(glyph, FT_GLYPH_BBOX_TRUNCATE, &bbox);
        dx = bbox.xMax - bbox.xMin;
        dy = bbox.yMax - bbox.yMin;
        if (dx * dy > 8000000) {
                mp_msg(MSGT_ASS, MSGL_WARN, MSGTR_LIBASS_GlyphBBoxTooLarge, (int)dx, (int)dy);
                return 1;
        } else
                return 0;
}

static bitmap_t* glyph_to_bitmap_internal(FT_Glyph glyph, int bord)
{
        FT_BitmapGlyph bg;
        FT_Bitmap* bit;
        bitmap_t* bm;
        int w, h;
        unsigned char* src;
        unsigned char* dst;
        int i;
        int error;

        if (check_glyph_area(glyph))
                return 0;
        error = FT_Glyph_To_Bitmap(&glyph, FT_RENDER_MODE_NORMAL, 0, 0);
        if (error) {
                mp_msg(MSGT_ASS, MSGL_WARN, MSGTR_LIBASS_FT_Glyph_To_BitmapError, error);
                return 0;
        }

        bg = (FT_BitmapGlyph)glyph;
        bit = &(bg->bitmap);
        if (bit->pixel_mode != FT_PIXEL_MODE_GRAY) {
                mp_msg(MSGT_ASS, MSGL_WARN, MSGTR_LIBASS_UnsupportedPixelMode, (int)(bit->pixel_mode));
                FT_Done_Glyph(glyph);
                return 0;
        }

        w = bit->width;
        h = bit->rows;
        bm = alloc_bitmap(w + 2*bord, h + 2*bord);
        memset(bm->buffer, 0, bm->w * bm->h);
        bm->left = bg->left - bord;
        bm->top = - bg->top - bord;

        src = bit->buffer;
        dst = bm->buffer + bord + bm->w * bord;
        for (i = 0; i < h; ++i) {
                memcpy(dst, src, w);
                src += bit->pitch;
                dst += bm->w;
        }

        return bm;
}

/**
 * \brief fix outline bitmap and generate shadow bitmap
 * Two things are done here:
 * 1. Glyph bitmap is subtracted from outline bitmap. This way looks much better in some cases.
 * 2. Shadow bitmap is created as a sum of glyph and outline bitmaps.
 */
static bitmap_t* fix_outline_and_shadow(bitmap_t* bm_g, bitmap_t* bm_o)
{
        int x, y;
        const int l = bm_o->left > bm_g->left ? bm_o->left : bm_g->left;
        const int t = bm_o->top > bm_g->top ? bm_o->top : bm_g->top;
        const int r = bm_o->left + bm_o->w < bm_g->left + bm_g->w ? bm_o->left + bm_o->w : bm_g->left + bm_g->w;
        const int b = bm_o->top + bm_o->h < bm_g->top + bm_g->h ? bm_o->top + bm_o->h : bm_g->top + bm_g->h;

        bitmap_t* bm_s = copy_bitmap(bm_o);

        unsigned char* g = bm_g->buffer + (t - bm_g->top) * bm_g->w + (l - bm_g->left);
        unsigned char* o = bm_o->buffer + (t - bm_o->top) * bm_o->w + (l - bm_o->left);
        unsigned char* s = bm_s->buffer + (t - bm_s->top) * bm_s->w + (l - bm_s->left);
        
        for (y = 0; y < b - t; ++y) {
                for (x = 0; x < r - l; ++x) {
                        unsigned char c_g, c_o;
                        c_g = g[x];
                        c_o = o[x];
                        o[x] = (c_o > c_g) ? c_o : 0;
                        s[x] = (c_o < 0xFF - c_g) ? c_o + c_g : 0xFF;
                }
                g += bm_g->w;
                o += bm_o->w;
                s += bm_s->w;
        }

        assert(bm_s);
        return bm_s;
}

int glyph_to_bitmap(ass_synth_priv_t* priv, ass_synth_priv_t* priv_blur,
                FT_Glyph glyph, FT_Glyph outline_glyph, bitmap_t** bm_g,
                bitmap_t** bm_o, bitmap_t** bm_s, int be, double blur_radius)
{
        int bord = be ? (be+1) : 0;
        bord = (blur_radius > 0.0) ? blur_radius : bord;

        assert(bm_g && bm_o && bm_s);

        *bm_g = *bm_o = *bm_s = 0;

        if (glyph)
                *bm_g = glyph_to_bitmap_internal(glyph, bord);
        if (!*bm_g)
                return 1;

        if (outline_glyph) {
                *bm_o = glyph_to_bitmap_internal(outline_glyph, bord);
                if (!*bm_o) {
                        ass_free_bitmap(*bm_g);
                        return 1;
                }
        }
        if (*bm_o) {
                resize_tmp(priv, (*bm_o)->w, (*bm_o)->h);
                resize_tmp(priv_blur, (*bm_o)->w, (*bm_o)->h);
        }
        resize_tmp(priv, (*bm_g)->w, (*bm_g)->h);
        resize_tmp(priv_blur, (*bm_g)->w, (*bm_g)->h);
        
        if (be) {
                while (be--) {
                        if (*bm_o)
                                blur((*bm_o)->buffer, priv->tmp, (*bm_o)->w, (*bm_o)->h, (*bm_o)->w, (int*)priv->gt2, priv->g_r, priv->g_w);
                        else
                                blur((*bm_g)->buffer, priv->tmp, (*bm_g)->w, (*bm_g)->h, (*bm_g)->w, (int*)priv->gt2, priv->g_r, priv->g_w);
                }
        } else {
                if (blur_radius > 0.0) {
                        generate_tables(priv_blur, blur_radius);
                        if (*bm_o)
                                blur((*bm_o)->buffer, priv_blur->tmp, (*bm_o)->w, (*bm_o)->h, (*bm_o)->w, (int*)priv_blur->gt2, priv_blur->g_r, priv_blur->g_w);
                        else
                                blur((*bm_g)->buffer, priv_blur->tmp, (*bm_g)->w, (*bm_g)->h, (*bm_g)->w, (int*)priv_blur->gt2, priv_blur->g_r, priv_blur->g_w);
                }
        }
        if (*bm_o)
                *bm_s = fix_outline_and_shadow(*bm_g, *bm_o);
        else
                *bm_s = copy_bitmap(*bm_g);

        assert(bm_s);
        return 0;
}