netsurf/frontends/framebuffer/framebuffer.c
Michael Drake 8332bf6b2a Plotters: Remove width param from path plotter.
We now use the stroke_width in the plot_style.
2018-05-23 13:48:17 +01:00

656 lines
16 KiB
C

/*
* Copyright 2008 Vincent Sanders <vince@simtec.co.uk>
*
* Framebuffer interface
*
* This file is part of NetSurf, http://www.netsurf-browser.org/
*
* NetSurf 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; version 2 of the License.
*
* NetSurf 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 this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stdio.h>
#include <stdbool.h>
#include <stdlib.h>
#include <string.h>
#include <libnsfb.h>
#include <libnsfb_plot.h>
#include <libnsfb_event.h>
#include <libnsfb_cursor.h>
#include "utils/utils.h"
#include "utils/log.h"
#include "utils/utf8.h"
#include "netsurf/browser_window.h"
#include "netsurf/plotters.h"
#include "netsurf/bitmap.h"
#include "framebuffer/gui.h"
#include "framebuffer/fbtk.h"
#include "framebuffer/framebuffer.h"
#include "framebuffer/font.h"
#include "framebuffer/bitmap.h"
/* netsurf framebuffer library handle */
static nsfb_t *nsfb;
/**
* \brief Sets a clip rectangle for subsequent plot operations.
*
* \param ctx The current redraw context.
* \param clip The rectangle to limit all subsequent plot
* operations within.
* \return NSERROR_OK on success else error code.
*/
static nserror
framebuffer_plot_clip(const struct redraw_context *ctx, const struct rect *clip)
{
nsfb_bbox_t nsfb_clip;
nsfb_clip.x0 = clip->x0;
nsfb_clip.y0 = clip->y0;
nsfb_clip.x1 = clip->x1;
nsfb_clip.y1 = clip->y1;
if (!nsfb_plot_set_clip(nsfb, &nsfb_clip)) {
return NSERROR_INVALID;
}
return NSERROR_OK;
}
/**
* Plots an arc
*
* plot an arc segment around (x,y), anticlockwise from angle1
* to angle2. Angles are measured anticlockwise from
* horizontal, in degrees.
*
* \param ctx The current redraw context.
* \param style Style controlling the arc plot.
* \param x The x coordinate of the arc.
* \param y The y coordinate of the arc.
* \param radius The radius of the arc.
* \param angle1 The start angle of the arc.
* \param angle2 The finish angle of the arc.
* \return NSERROR_OK on success else error code.
*/
static nserror
framebuffer_plot_arc(const struct redraw_context *ctx,
const plot_style_t *style,
int x, int y, int radius, int angle1, int angle2)
{
if (!nsfb_plot_arc(nsfb, x, y, radius, angle1, angle2, style->fill_colour)) {
return NSERROR_INVALID;
}
return NSERROR_OK;
}
/**
* Plots a circle
*
* Plot a circle centered on (x,y), which is optionally filled.
*
* \param ctx The current redraw context.
* \param style Style controlling the circle plot.
* \param x x coordinate of circle centre.
* \param y y coordinate of circle centre.
* \param radius circle radius.
* \return NSERROR_OK on success else error code.
*/
static nserror
framebuffer_plot_disc(const struct redraw_context *ctx,
const plot_style_t *style,
int x, int y, int radius)
{
nsfb_bbox_t ellipse;
ellipse.x0 = x - radius;
ellipse.y0 = y - radius;
ellipse.x1 = x + radius;
ellipse.y1 = y + radius;
if (style->fill_type != PLOT_OP_TYPE_NONE) {
nsfb_plot_ellipse_fill(nsfb, &ellipse, style->fill_colour);
}
if (style->stroke_type != PLOT_OP_TYPE_NONE) {
nsfb_plot_ellipse(nsfb, &ellipse, style->stroke_colour);
}
return NSERROR_OK;
}
/**
* Plots a line
*
* plot a line from (x0,y0) to (x1,y1). Coordinates are at
* centre of line width/thickness.
*
* \param ctx The current redraw context.
* \param style Style controlling the line plot.
* \param line A rectangle defining the line to be drawn
* \return NSERROR_OK on success else error code.
*/
static nserror
framebuffer_plot_line(const struct redraw_context *ctx,
const plot_style_t *style,
const struct rect *line)
{
nsfb_bbox_t rect;
nsfb_plot_pen_t pen;
rect.x0 = line->x0;
rect.y0 = line->y0;
rect.x1 = line->x1;
rect.y1 = line->y1;
if (style->stroke_type != PLOT_OP_TYPE_NONE) {
if (style->stroke_type == PLOT_OP_TYPE_DOT) {
pen.stroke_type = NFSB_PLOT_OPTYPE_PATTERN;
pen.stroke_pattern = 0xAAAAAAAA;
} else if (style->stroke_type == PLOT_OP_TYPE_DASH) {
pen.stroke_type = NFSB_PLOT_OPTYPE_PATTERN;
pen.stroke_pattern = 0xF0F0F0F0;
} else {
pen.stroke_type = NFSB_PLOT_OPTYPE_SOLID;
}
pen.stroke_colour = style->stroke_colour;
pen.stroke_width = plot_style_fixed_to_int(style->stroke_width);
nsfb_plot_line(nsfb, &rect, &pen);
}
return NSERROR_OK;
}
/**
* Plots a rectangle.
*
* The rectangle can be filled an outline or both controlled
* by the plot style The line can be solid, dotted or
* dashed. Top left corner at (x0,y0) and rectangle has given
* width and height.
*
* \param ctx The current redraw context.
* \param style Style controlling the rectangle plot.
* \param nsrect A rectangle defining the line to be drawn
* \return NSERROR_OK on success else error code.
*/
static nserror
framebuffer_plot_rectangle(const struct redraw_context *ctx,
const plot_style_t *style,
const struct rect *nsrect)
{
nsfb_bbox_t rect;
bool dotted = false;
bool dashed = false;
rect.x0 = nsrect->x0;
rect.y0 = nsrect->y0;
rect.x1 = nsrect->x1;
rect.y1 = nsrect->y1;
if (style->fill_type != PLOT_OP_TYPE_NONE) {
nsfb_plot_rectangle_fill(nsfb, &rect, style->fill_colour);
}
if (style->stroke_type != PLOT_OP_TYPE_NONE) {
if (style->stroke_type == PLOT_OP_TYPE_DOT) {
dotted = true;
}
if (style->stroke_type == PLOT_OP_TYPE_DASH) {
dashed = true;
}
nsfb_plot_rectangle(nsfb, &rect,
plot_style_fixed_to_int(style->stroke_width),
style->stroke_colour, dotted, dashed);
}
return NSERROR_OK;
}
/**
* Plot a polygon
*
* Plots a filled polygon with straight lines between
* points. The lines around the edge of the ploygon are not
* plotted. The polygon is filled with the non-zero winding
* rule.
*
* \param ctx The current redraw context.
* \param style Style controlling the polygon plot.
* \param p verticies of polygon
* \param n number of verticies.
* \return NSERROR_OK on success else error code.
*/
static nserror
framebuffer_plot_polygon(const struct redraw_context *ctx,
const plot_style_t *style,
const int *p,
unsigned int n)
{
if (!nsfb_plot_polygon(nsfb, p, n, style->fill_colour)) {
return NSERROR_INVALID;
}
return NSERROR_OK;
}
/**
* Plots a path.
*
* Path plot consisting of cubic Bezier curves. Line and fill colour is
* controlled by the plot style.
*
* \param ctx The current redraw context.
* \param pstyle Style controlling the path plot.
* \param p elements of path
* \param n nunber of elements on path
* \param transform A transform to apply to the path.
* \return NSERROR_OK on success else error code.
*/
static nserror
framebuffer_plot_path(const struct redraw_context *ctx,
const plot_style_t *pstyle,
const float *p,
unsigned int n,
const float transform[6])
{
NSLOG(netsurf, INFO, "path unimplemented");
return NSERROR_OK;
}
/**
* Plot a bitmap
*
* Tiled plot of a bitmap image. (x,y) gives the top left
* coordinate of an explicitly placed tile. From this tile the
* image can repeat in all four directions -- up, down, left
* and right -- to the extents given by the current clip
* rectangle.
*
* The bitmap_flags say whether to tile in the x and y
* directions. If not tiling in x or y directions, the single
* image is plotted. The width and height give the dimensions
* the image is to be scaled to.
*
* \param ctx The current redraw context.
* \param bitmap The bitmap to plot
* \param x The x coordinate to plot the bitmap
* \param y The y coordiante to plot the bitmap
* \param width The width of area to plot the bitmap into
* \param height The height of area to plot the bitmap into
* \param bg the background colour to alpha blend into
* \param flags the flags controlling the type of plot operation
* \return NSERROR_OK on success else error code.
*/
static nserror
framebuffer_plot_bitmap(const struct redraw_context *ctx,
struct bitmap *bitmap,
int x, int y,
int width,
int height,
colour bg,
bitmap_flags_t flags)
{
nsfb_bbox_t loc;
nsfb_bbox_t clipbox;
bool repeat_x = (flags & BITMAPF_REPEAT_X);
bool repeat_y = (flags & BITMAPF_REPEAT_Y);
int bmwidth;
int bmheight;
int bmstride;
enum nsfb_format_e bmformat;
unsigned char *bmptr;
nsfb_t *bm = (nsfb_t *)bitmap;
/* x and y define coordinate of top left of of the initial explicitly
* placed tile. The width and height are the image scaling and the
* bounding box defines the extent of the repeat (which may go in all
* four directions from the initial tile).
*/
if (!(repeat_x || repeat_y)) {
/* Not repeating at all, so just plot it */
loc.x0 = x;
loc.y0 = y;
loc.x1 = loc.x0 + width;
loc.y1 = loc.y0 + height;
if (!nsfb_plot_copy(bm, NULL, nsfb, &loc)) {
return NSERROR_INVALID;
}
return NSERROR_OK;
}
nsfb_plot_get_clip(nsfb, &clipbox);
nsfb_get_geometry(bm, &bmwidth, &bmheight, &bmformat);
nsfb_get_buffer(bm, &bmptr, &bmstride);
/* Optimise tiled plots of 1x1 bitmaps by replacing with a flat fill
* of the area. Can only be done when image is fully opaque. */
if ((bmwidth == 1) && (bmheight == 1)) {
if ((*(nsfb_colour_t *)bmptr & 0xff000000) != 0) {
if (!nsfb_plot_rectangle_fill(nsfb, &clipbox,
*(nsfb_colour_t *)bmptr)) {
return NSERROR_INVALID;
}
return NSERROR_OK;
}
}
/* Optimise tiled plots of bitmaps scaled to 1x1 by replacing with
* a flat fill of the area. Can only be done when image is fully
* opaque. */
if ((width == 1) && (height == 1)) {
if (framebuffer_bitmap_get_opaque(bm)) {
/** TODO: Currently using top left pixel. Maybe centre
* pixel or average value would be better. */
if (!nsfb_plot_rectangle_fill(nsfb, &clipbox,
*(nsfb_colour_t *)bmptr)) {
return NSERROR_INVALID;
}
return NSERROR_OK;
}
}
/* get left most tile position */
if (repeat_x) {
for (; x > clipbox.x0; x -= width);
}
/* get top most tile position */
if (repeat_y) {
for (; y > clipbox.y0; y -= height);
}
/* set up top left tile location */
loc.x0 = x;
loc.y0 = y;
loc.x1 = loc.x0 + width;
loc.y1 = loc.y0 + height;
/* plot tiling across and down to extents */
nsfb_plot_bitmap_tiles(nsfb, &loc,
repeat_x ? ((clipbox.x1 - x) + width - 1) / width : 1,
repeat_y ? ((clipbox.y1 - y) + height - 1) / height : 1,
(nsfb_colour_t *)bmptr, bmwidth, bmheight,
bmstride * 8 / 32, bmformat == NSFB_FMT_ABGR8888);
return NSERROR_OK;
}
#ifdef FB_USE_FREETYPE
/**
* Text plotting.
*
* \param ctx The current redraw context.
* \param fstyle plot style for this text
* \param x x coordinate
* \param y y coordinate
* \param text UTF-8 string to plot
* \param length length of string, in bytes
* \return NSERROR_OK on success else error code.
*/
static nserror
framebuffer_plot_text(const struct redraw_context *ctx,
const struct plot_font_style *fstyle,
int x,
int y,
const char *text,
size_t length)
{
uint32_t ucs4;
size_t nxtchr = 0;
FT_Glyph glyph;
FT_BitmapGlyph bglyph;
nsfb_bbox_t loc;
while (nxtchr < length) {
ucs4 = utf8_to_ucs4(text + nxtchr, length - nxtchr);
nxtchr = utf8_next(text, length, nxtchr);
glyph = fb_getglyph(fstyle, ucs4);
if (glyph == NULL)
continue;
if (glyph->format == FT_GLYPH_FORMAT_BITMAP) {
bglyph = (FT_BitmapGlyph)glyph;
loc.x0 = x + bglyph->left;
loc.y0 = y - bglyph->top;
loc.x1 = loc.x0 + bglyph->bitmap.width;
loc.y1 = loc.y0 + bglyph->bitmap.rows;
/* now, draw to our target surface */
if (bglyph->bitmap.pixel_mode == FT_PIXEL_MODE_MONO) {
nsfb_plot_glyph1(nsfb,
&loc,
bglyph->bitmap.buffer,
bglyph->bitmap.pitch,
fstyle->foreground);
} else {
nsfb_plot_glyph8(nsfb,
&loc,
bglyph->bitmap.buffer,
bglyph->bitmap.pitch,
fstyle->foreground);
}
}
x += glyph->advance.x >> 16;
}
return NSERROR_OK;
}
#else
/**
* Text plotting.
*
* \param ctx The current redraw context.
* \param fstyle plot style for this text
* \param x x coordinate
* \param y y coordinate
* \param text UTF-8 string to plot
* \param length length of string, in bytes
* \return NSERROR_OK on success else error code.
*/
static nserror
framebuffer_plot_text(const struct redraw_context *ctx,
const struct plot_font_style *fstyle,
int x,
int y,
const char *text,
size_t length)
{
enum fb_font_style style = fb_get_font_style(fstyle);
int size = fb_get_font_size(fstyle);
const uint8_t *chrp;
size_t nxtchr = 0;
nsfb_bbox_t loc;
uint32_t ucs4;
int p = FB_FONT_PITCH * size;
int w = FB_FONT_WIDTH * size;
int h = FB_FONT_HEIGHT * size;
y -= ((h * 3) / 4);
/* the coord is the bottom-left of the pixels offset by 1 to make
* it work since fb coords are the top-left of pixels */
y += 1;
while (nxtchr < length) {
ucs4 = utf8_to_ucs4(text + nxtchr, length - nxtchr);
nxtchr = utf8_next(text, length, nxtchr);
if (!codepoint_displayable(ucs4))
continue;
loc.x0 = x;
loc.y0 = y;
loc.x1 = loc.x0 + w;
loc.y1 = loc.y0 + h;
chrp = fb_get_glyph(ucs4, style, size);
nsfb_plot_glyph1(nsfb, &loc, chrp, p, fstyle->foreground);
x += w;
}
return NSERROR_OK;
}
#endif
/** framebuffer plot operation table */
const struct plotter_table fb_plotters = {
.clip = framebuffer_plot_clip,
.arc = framebuffer_plot_arc,
.disc = framebuffer_plot_disc,
.line = framebuffer_plot_line,
.rectangle = framebuffer_plot_rectangle,
.polygon = framebuffer_plot_polygon,
.path = framebuffer_plot_path,
.bitmap = framebuffer_plot_bitmap,
.text = framebuffer_plot_text,
.option_knockout = true,
};
static bool framebuffer_format_from_bpp(int bpp, enum nsfb_format_e *fmt)
{
switch (bpp) {
case 32:
*fmt = NSFB_FMT_XRGB8888;
break;
case 24:
*fmt = NSFB_FMT_RGB888;
break;
case 16:
*fmt = NSFB_FMT_RGB565;
break;
case 8:
*fmt = NSFB_FMT_I8;
break;
case 4:
*fmt = NSFB_FMT_I4;
break;
case 1:
*fmt = NSFB_FMT_I1;
break;
default:
NSLOG(netsurf, INFO, "Bad bits per pixel (%d)\n", bpp);
return false;
}
return true;
}
nsfb_t *
framebuffer_initialise(const char *fename, int width, int height, int bpp)
{
enum nsfb_type_e fbtype;
enum nsfb_format_e fbfmt;
/* bpp is a proxy for the framebuffer format */
if (framebuffer_format_from_bpp(bpp, &fbfmt) == false) {
return NULL;
}
fbtype = nsfb_type_from_name(fename);
if (fbtype == NSFB_SURFACE_NONE) {
NSLOG(netsurf, INFO,
"The %s surface is not available from libnsfb\n", fename);
return NULL;
}
nsfb = nsfb_new(fbtype);
if (nsfb == NULL) {
NSLOG(netsurf, INFO, "Unable to create %s fb surface\n", fename);
return NULL;
}
if (nsfb_set_geometry(nsfb, width, height, fbfmt) == -1) {
NSLOG(netsurf, INFO, "Unable to set surface geometry\n");
nsfb_free(nsfb);
return NULL;
}
nsfb_cursor_init(nsfb);
if (nsfb_init(nsfb) == -1) {
NSLOG(netsurf, INFO, "Unable to initialise nsfb surface\n");
nsfb_free(nsfb);
return NULL;
}
return nsfb;
}
bool
framebuffer_resize(nsfb_t *nsfb, int width, int height, int bpp)
{
enum nsfb_format_e fbfmt;
/* bpp is a proxy for the framebuffer format */
if (framebuffer_format_from_bpp(bpp, &fbfmt) == false) {
return false;
}
if (nsfb_set_geometry(nsfb, width, height, fbfmt) == -1) {
NSLOG(netsurf, INFO, "Unable to change surface geometry\n");
return false;
}
return true;
}
void
framebuffer_finalise(void)
{
nsfb_free(nsfb);
}
bool
framebuffer_set_cursor(struct fbtk_bitmap *bm)
{
return nsfb_cursor_set(nsfb, (nsfb_colour_t *)bm->pixdata, bm->width, bm->height, bm->width, bm->hot_x, bm->hot_y);
}
nsfb_t *framebuffer_set_surface(nsfb_t *new_nsfb)
{
nsfb_t *old_nsfb;
old_nsfb = nsfb;
nsfb = new_nsfb;
return old_nsfb;
}