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vdr/osd.c
Klaus Schmidinger 939081e274 Version 1.7.11 
- Fixed resetting the file size when regenerating the index file.
- The new function cDevice::PatPmtParser() can be used in derived devices to access
  the PAT/PMT of the currently replayed material.
- Updated the Italian OSD texts (thanks to Diego Pierotto).
- The PCR pid in generated PMTs is now set to 0x1FFF ("no PCR pid") in
  cPatPmtGenerator::GeneratePmt(), because VDR doesn't record the PCR pid.
- Updated the Estonian OSD texts (thanks to Arthur Konovalov).
- The 'sky' plugin is no longer part of the VDR source.
- Improved SPU handling on devices with limited OSD capabilities (thanks to
  Matthieu Castet).
- Several code modifications to avoid compiler warnings (thanks to Winfried Köhler).
- Added stream type 11172 AUDIO to cPatPmtParser::ParsePmt() (thanks to Johann
  Friedrichs).
- Removed debug output of '-' from cTransfer::Receive().
- Added defines for large files to the 'newplugin' script (reported by Udo Richter).
- Removed the workaround for short channel names of "Kabel Deutschland", because
  apparently they now have their data according to the DVB standard (thanks to
  Johann Friedrichs).
- Some fixes to dvbspu.[hc] (thanks to Johann Friedrichs).
- Fixed a busy loop when moving editing marks (thanks to Johann Friedrichs).
- Updated sources.conf (thanks to Derek Kelly).
- Modified cCharSetConv so that it can be used to convert from "whatever VDR uses"
  to a given code (thanks to Joachim Wilke).
- Channel names containing commas are now handled correctly in channels.conf.
  If a channel's short name contains a comma, it is replaced with a '.'.
- cDevice now logs the device number when a new device is created.
- Fixed handling STREAMTYPE_11172_AUDIO in cPatPmtParser::ParsePmt().
- cParsePatPmt now has functions to retrieve the audio, dolby and subtitle pids.
- cPatFilter::Process() now only stores CA descriptors for video and audio pids
  (thanks to Francesco Saverio Schiavarelli for reporting a problem with channels
  that have some encrypted components that VDR doesn't use).
- cDevice::AddPid() now stores the stream type of the given pid (thanks to Andreas
  Regel).
- Added cFont::FontName() and cFont::Size() (thanks to Andreas Regel).
- cPatPmtParser now also stores the audio stream types.
- The support for full featured DVB cards of the TT/FuSi design has been moved
  into the new plugin 'dvbsddevice'. On systems that use such a card as their
  primary device, this plugin now needs to be loaded when running VDR in order
  to view live or recorded video. If the plugin is not loaded, the card will
  be treated like a budget DVB card, and there will be no OSD or viewing
  capability.
- Fixed handling the "CA PMT" generation (revised a change not mentioned in version
  1.7.9's changes, which caused a malfunction with Conax and Viaccess CAMs).
- Fixed stopping subtitle display when switching the primary device (thanks to
  Anssi Hannula).
  IMPORTANT NOTE TO PLUGIN AUTHORS: a plugin that implements a derived cDevice
  class that can replay video must now call the MakePrimaryDevice() function of
  its base class.
- Fixed compiler warnings "format not a string literal and no format arguments"
  in some syslog calls (thanks to Rolf Ahrenberg).
- The new command line options --edit and --genindex can be used to edit a
  recording or generate its index without actually starting the entire VDR
  (based on a patch from Helmut Auer).
- Improved the description of the transponder parameters in vdr.5 (thanks to
  Winfried Köhler).
- Avoiding setting the video stream type to 2 if the vpid is 0 (problem reported
  by Arthur Konovalov).
- Implemented handling the "Content Descriptor" (based on a patch from Rolf
  Ahrenberg). The 'classic', 'sttng' and 'curses' skins display the textual
  representation of the content descriptors as "genre". The epg.data file stores
  the genre using the tag character 'G'.
- Implemented handling the "Parental Rating Descriptor" (based on a patch from Rolf
  Ahrenberg). The 'classic', 'sttng' and 'curses' skins display the parental
  rating (if given) in their event displays. The epg.data file stores
  the parental rating using the tag character 'R'.
  IMPORTANT NOTE: if VDR doesn't display a parental rating, this does not
  necessarily mean that the given programme is suitable for all audiences!
- Rearranged cEvent members to minimize memory waste.
- After a CLRE command, no further EPG processing is now done for 10 seconds,
  so that data sent with subsequent PUTE commands doesn't interfere with data
  from the broadcasters (suggested by Helmut Auer).
- Added support for DVB cards with multiple fontends. Note that this only
  works for DVB cards where each frontend can be used independently of all
  the others on the same adapter.
- Fixed plugin arguments corruption with glibc 2.11 on x86_64 (thanks to
  Anssi Hannula).
2010-01-06 13:34:00 +01:00

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/*
* osd.c: Abstract On Screen Display layer
*
* See the main source file 'vdr.c' for copyright information and
* how to reach the author.
*
* $Id: osd.c 2.6 2009/12/06 11:33:47 kls Exp $
*/
#include "osd.h"
#include <math.h>
#include <stdarg.h>
#include <stdlib.h>
#include <sys/ioctl.h>
#include <sys/stat.h>
#include <sys/unistd.h>
#include "device.h"
#include "tools.h"
// --- cPalette --------------------------------------------------------------
cPalette::cPalette(int Bpp)
{
SetBpp(Bpp);
SetAntiAliasGranularity(10, 10);
}
cPalette::~cPalette()
{
}
void cPalette::SetAntiAliasGranularity(uint FixedColors, uint BlendColors)
{
if (FixedColors >= MAXNUMCOLORS || BlendColors == 0)
antiAliasGranularity = MAXNUMCOLORS - 1;
else {
int ColorsForBlending = MAXNUMCOLORS - FixedColors;
int ColorsPerBlend = ColorsForBlending / BlendColors + 2; // +2 = the full foreground and background colors, which are amoung the fixed colors
antiAliasGranularity = double(MAXNUMCOLORS - 1) / (ColorsPerBlend - 1);
}
}
void cPalette::Reset(void)
{
numColors = 0;
modified = false;
}
int cPalette::Index(tColor Color)
{
// Check if color is already defined:
for (int i = 0; i < numColors; i++) {
if (color[i] == Color)
return i;
}
// No exact color, try a close one:
int i = ClosestColor(Color, 4);
if (i >= 0)
return i;
// No close one, try to define a new one:
if (numColors < maxColors) {
color[numColors++] = Color;
modified = true;
return numColors - 1;
}
// Out of colors, so any close color must do:
return ClosestColor(Color);
}
void cPalette::SetBpp(int Bpp)
{
bpp = Bpp;
maxColors = 1 << bpp;
Reset();
}
void cPalette::SetColor(int Index, tColor Color)
{
if (Index < maxColors) {
if (numColors <= Index) {
numColors = Index + 1;
modified = true;
}
else
modified |= color[Index] != Color;
color[Index] = Color;
}
}
const tColor *cPalette::Colors(int &NumColors) const
{
NumColors = numColors;
return numColors ? color : NULL;
}
void cPalette::Take(const cPalette &Palette, tIndexes *Indexes, tColor ColorFg, tColor ColorBg)
{
for (int i = 0; i < Palette.numColors; i++) {
tColor Color = Palette.color[i];
if (ColorFg || ColorBg) {
switch (i) {
case 0: Color = ColorBg; break;
case 1: Color = ColorFg; break;
default: ;
}
}
int n = Index(Color);
if (Indexes)
(*Indexes)[i] = n;
}
}
void cPalette::Replace(const cPalette &Palette)
{
for (int i = 0; i < Palette.numColors; i++)
SetColor(i, Palette.color[i]);
numColors = Palette.numColors;
antiAliasGranularity = Palette.antiAliasGranularity;
}
tColor cPalette::Blend(tColor ColorFg, tColor ColorBg, uint8_t Level) const
{
if (antiAliasGranularity > 0)
Level = uint8_t(int(Level / antiAliasGranularity + 0.5) * antiAliasGranularity);
int Af = (ColorFg & 0xFF000000) >> 24;
int Rf = (ColorFg & 0x00FF0000) >> 16;
int Gf = (ColorFg & 0x0000FF00) >> 8;
int Bf = (ColorFg & 0x000000FF);
int Ab = (ColorBg & 0xFF000000) >> 24;
int Rb = (ColorBg & 0x00FF0000) >> 16;
int Gb = (ColorBg & 0x0000FF00) >> 8;
int Bb = (ColorBg & 0x000000FF);
int A = (Ab + (Af - Ab) * Level / 0xFF) & 0xFF;
int R = (Rb + (Rf - Rb) * Level / 0xFF) & 0xFF;
int G = (Gb + (Gf - Gb) * Level / 0xFF) & 0xFF;
int B = (Bb + (Bf - Bb) * Level / 0xFF) & 0xFF;
return (A << 24) | (R << 16) | (G << 8) | B;
}
int cPalette::ClosestColor(tColor Color, int MaxDiff) const
{
int n = 0;
int d = INT_MAX;
int A1 = (Color & 0xFF000000) >> 24;
int R1 = (Color & 0x00FF0000) >> 16;
int G1 = (Color & 0x0000FF00) >> 8;
int B1 = (Color & 0x000000FF);
for (int i = 0; i < numColors; i++) {
int A2 = (color[i] & 0xFF000000) >> 24;
int R2 = (color[i] & 0x00FF0000) >> 16;
int G2 = (color[i] & 0x0000FF00) >> 8;
int B2 = (color[i] & 0x000000FF);
int diff = (abs(A1 - A2) << 1) + (abs(R1 - R2) << 1) + (abs(G1 - G2) << 1) + (abs(B1 - B2) << 1);
if (diff < d) {
d = diff;
n = i;
}
}
return d <= MaxDiff ? n : -1;
}
// --- cBitmap ---------------------------------------------------------------
cBitmap::cBitmap(int Width, int Height, int Bpp, int X0, int Y0)
:cPalette(Bpp)
{
bitmap = NULL;
x0 = X0;
y0 = Y0;
SetSize(Width, Height);
}
cBitmap::cBitmap(const char *FileName)
{
bitmap = NULL;
x0 = 0;
y0 = 0;
LoadXpm(FileName);
}
cBitmap::cBitmap(const char *const Xpm[])
{
bitmap = NULL;
x0 = 0;
y0 = 0;
SetXpm(Xpm);
}
cBitmap::~cBitmap()
{
free(bitmap);
}
void cBitmap::SetSize(int Width, int Height)
{
if (bitmap && Width == width && Height == height)
return;
width = Width;
height = Height;
free(bitmap);
bitmap = NULL;
dirtyX1 = 0;
dirtyY1 = 0;
dirtyX2 = width - 1;
dirtyY2 = height - 1;
if (width > 0 && height > 0) {
bitmap = MALLOC(tIndex, width * height);
if (bitmap)
memset(bitmap, 0x00, width * height);
else
esyslog("ERROR: can't allocate bitmap!");
}
else
esyslog("ERROR: invalid bitmap parameters (%d, %d)!", width, height);
}
bool cBitmap::Contains(int x, int y) const
{
x -= x0;
y -= y0;
return 0 <= x && x < width && 0 <= y && y < height;
}
bool cBitmap::Covers(int x1, int y1, int x2, int y2) const
{
x1 -= x0;
y1 -= y0;
x2 -= x0;
y2 -= y0;
return x1 <= 0 && y1 <= 0 && x2 >= width - 1 && y2 >= height - 1;
}
bool cBitmap::Intersects(int x1, int y1, int x2, int y2) const
{
x1 -= x0;
y1 -= y0;
x2 -= x0;
y2 -= y0;
return !(x2 < 0 || x1 >= width || y2 < 0 || y1 >= height);
}
bool cBitmap::Dirty(int &x1, int &y1, int &x2, int &y2)
{
if (dirtyX2 >= 0) {
x1 = dirtyX1;
y1 = dirtyY1;
x2 = dirtyX2;
y2 = dirtyY2;
return true;
}
return false;
}
void cBitmap::Clean(void)
{
dirtyX1 = width;
dirtyY1 = height;
dirtyX2 = -1;
dirtyY2 = -1;
}
bool cBitmap::LoadXpm(const char *FileName)
{
bool Result = false;
FILE *f = fopen(FileName, "r");
if (f) {
char **Xpm = NULL;
bool isXpm = false;
int lines = 0;
int index = 0;
char *s;
cReadLine ReadLine;
while ((s = ReadLine.Read(f)) != NULL) {
s = skipspace(s);
if (!isXpm) {
if (strcmp(s, "/* XPM */") != 0) {
esyslog("ERROR: invalid header in XPM file '%s'", FileName);
break;
}
isXpm = true;
}
else if (*s++ == '"') {
if (!lines) {
int w, h, n, c;
if (4 != sscanf(s, "%d %d %d %d", &w, &h, &n, &c)) {
esyslog("ERROR: faulty 'values' line in XPM file '%s'", FileName);
isXpm = false;
break;
}
lines = h + n + 1;
Xpm = MALLOC(char *, lines);
memset(Xpm, 0, lines * sizeof(char*));
}
char *q = strchr(s, '"');
if (!q) {
esyslog("ERROR: missing quotes in XPM file '%s'", FileName);
isXpm = false;
break;
}
*q = 0;
if (index < lines)
Xpm[index++] = strdup(s);
else {
esyslog("ERROR: too many lines in XPM file '%s'", FileName);
isXpm = false;
break;
}
}
}
if (isXpm) {
if (index == lines)
Result = SetXpm(Xpm);
else
esyslog("ERROR: too few lines in XPM file '%s'", FileName);
}
if (Xpm) {
for (int i = 0; i < index; i++)
free(Xpm[i]);
}
free(Xpm);
fclose(f);
}
else
esyslog("ERROR: can't open XPM file '%s'", FileName);
return Result;
}
bool cBitmap::SetXpm(const char *const Xpm[], bool IgnoreNone)
{
if (!Xpm)
return false;
const char *const *p = Xpm;
int w, h, n, c;
if (4 != sscanf(*p, "%d %d %d %d", &w, &h, &n, &c)) {
esyslog("ERROR: faulty 'values' line in XPM: '%s'", *p);
return false;
}
if (n > MAXNUMCOLORS) {
esyslog("ERROR: too many colors in XPM: %d", n);
return false;
}
int b = 0;
while (1 << (1 << b) < (IgnoreNone ? n - 1 : n))
b++;
SetBpp(1 << b);
SetSize(w, h);
int NoneColorIndex = MAXNUMCOLORS;
for (int i = 0; i < n; i++) {
const char *s = *++p;
if (int(strlen(s)) < c) {
esyslog("ERROR: faulty 'colors' line in XPM: '%s'", s);
return false;
}
s = skipspace(s + c);
if (*s != 'c') {
esyslog("ERROR: unknown color key in XPM: '%c'", *s);
return false;
}
s = skipspace(s + 1);
if (strcasecmp(s, "none") == 0) {
s = "#00000000";
NoneColorIndex = i;
if (IgnoreNone)
continue;
}
if (*s != '#') {
esyslog("ERROR: unknown color code in XPM: '%c'", *s);
return false;
}
tColor color = strtoul(++s, NULL, 16) | 0xFF000000;
SetColor((IgnoreNone && i > NoneColorIndex) ? i - 1 : i, color);
}
for (int y = 0; y < h; y++) {
const char *s = *++p;
if (int(strlen(s)) != w * c) {
esyslog("ERROR: faulty pixel line in XPM: %d '%s'", y, s);
return false;
}
for (int x = 0; x < w; x++) {
for (int i = 0; i <= n; i++) {
if (i == n) {
esyslog("ERROR: undefined pixel color in XPM: %d %d '%s'", x, y, s);
return false;
}
if (strncmp(Xpm[i + 1], s, c) == 0) {
if (i == NoneColorIndex)
NoneColorIndex = MAXNUMCOLORS;
SetIndex(x, y, (IgnoreNone && i > NoneColorIndex) ? i - 1 : i);
break;
}
}
s += c;
}
}
if (NoneColorIndex < MAXNUMCOLORS && !IgnoreNone)
return SetXpm(Xpm, true);
return true;
}
void cBitmap::SetIndex(int x, int y, tIndex Index)
{
if (bitmap) {
if (0 <= x && x < width && 0 <= y && y < height) {
if (bitmap[width * y + x] != Index) {
bitmap[width * y + x] = Index;
if (dirtyX1 > x) dirtyX1 = x;
if (dirtyY1 > y) dirtyY1 = y;
if (dirtyX2 < x) dirtyX2 = x;
if (dirtyY2 < y) dirtyY2 = y;
}
}
}
}
void cBitmap::DrawPixel(int x, int y, tColor Color)
{
x -= x0;
y -= y0;
if (0 <= x && x < width && 0 <= y && y < height)
SetIndex(x, y, Index(Color));
}
void cBitmap::DrawBitmap(int x, int y, const cBitmap &Bitmap, tColor ColorFg, tColor ColorBg, bool ReplacePalette, bool Overlay)
{
if (bitmap && Bitmap.bitmap && Intersects(x, y, x + Bitmap.Width() - 1, y + Bitmap.Height() - 1)) {
if (Covers(x, y, x + Bitmap.Width() - 1, y + Bitmap.Height() - 1))
Reset();
x -= x0;
y -= y0;
if (ReplacePalette && Covers(x + x0, y + y0, x + x0 + Bitmap.Width() - 1, y + y0 + Bitmap.Height() - 1)) {
Replace(Bitmap);
for (int ix = 0; ix < Bitmap.width; ix++) {
for (int iy = 0; iy < Bitmap.height; iy++) {
if (!Overlay || Bitmap.bitmap[Bitmap.width * iy + ix] != 0)
SetIndex(x + ix, y + iy, Bitmap.bitmap[Bitmap.width * iy + ix]);
}
}
}
else {
tIndexes Indexes;
Take(Bitmap, &Indexes, ColorFg, ColorBg);
for (int ix = 0; ix < Bitmap.width; ix++) {
for (int iy = 0; iy < Bitmap.height; iy++) {
if (!Overlay || Bitmap.bitmap[Bitmap.width * iy + ix] != 0)
SetIndex(x + ix, y + iy, Indexes[int(Bitmap.bitmap[Bitmap.width * iy + ix])]);
}
}
}
}
}
void cBitmap::DrawText(int x, int y, const char *s, tColor ColorFg, tColor ColorBg, const cFont *Font, int Width, int Height, int Alignment)
{
if (bitmap) {
int w = Font->Width(s);
int h = Font->Height();
int limit = 0;
int cw = Width ? Width : w;
int ch = Height ? Height : h;
if (!Intersects(x, y, x + cw - 1, y + ch - 1))
return;
if (ColorBg != clrTransparent)
DrawRectangle(x, y, x + cw - 1, y + ch - 1, ColorBg);
if (Width || Height) {
limit = x + cw - x0;
if (Width) {
if ((Alignment & taLeft) != 0)
;
else if ((Alignment & taRight) != 0) {
if (w < Width)
x += Width - w;
}
else { // taCentered
if (w < Width)
x += (Width - w) / 2;
}
}
if (Height) {
if ((Alignment & taTop) != 0)
;
else if ((Alignment & taBottom) != 0) {
if (h < Height)
y += Height - h;
}
else { // taCentered
if (h < Height)
y += (Height - h) / 2;
}
}
}
x -= x0;
y -= y0;
Font->DrawText(this, x, y, s, ColorFg, ColorBg, limit);
}
}
void cBitmap::DrawRectangle(int x1, int y1, int x2, int y2, tColor Color)
{
if (bitmap && Intersects(x1, y1, x2, y2)) {
if (Covers(x1, y1, x2, y2))
Reset();
x1 -= x0;
y1 -= y0;
x2 -= x0;
y2 -= y0;
x1 = max(x1, 0);
y1 = max(y1, 0);
x2 = min(x2, width - 1);
y2 = min(y2, height - 1);
tIndex c = Index(Color);
for (int y = y1; y <= y2; y++)
for (int x = x1; x <= x2; x++)
SetIndex(x, y, c);
}
}
void cBitmap::DrawEllipse(int x1, int y1, int x2, int y2, tColor Color, int Quadrants)
{
if (!Intersects(x1, y1, x2, y2))
return;
// Algorithm based on http://homepage.smc.edu/kennedy_john/BELIPSE.PDF
int rx = x2 - x1;
int ry = y2 - y1;
int cx = (x1 + x2) / 2;
int cy = (y1 + y2) / 2;
switch (abs(Quadrants)) {
case 0: rx /= 2; ry /= 2; break;
case 1: cx = x1; cy = y2; break;
case 2: cx = x2; cy = y2; break;
case 3: cx = x2; cy = y1; break;
case 4: cx = x1; cy = y1; break;
case 5: cx = x1; ry /= 2; break;
case 6: cy = y2; rx /= 2; break;
case 7: cx = x2; ry /= 2; break;
case 8: cy = y1; rx /= 2; break;
default: ;
}
int TwoASquare = 2 * rx * rx;
int TwoBSquare = 2 * ry * ry;
int x = rx;
int y = 0;
int XChange = ry * ry * (1 - 2 * rx);
int YChange = rx * rx;
int EllipseError = 0;
int StoppingX = TwoBSquare * rx;
int StoppingY = 0;
while (StoppingX >= StoppingY) {
switch (Quadrants) {
case 5: DrawRectangle(cx, cy + y, cx + x, cy + y, Color); // no break
case 1: DrawRectangle(cx, cy - y, cx + x, cy - y, Color); break;
case 7: DrawRectangle(cx - x, cy + y, cx, cy + y, Color); // no break
case 2: DrawRectangle(cx - x, cy - y, cx, cy - y, Color); break;
case 3: DrawRectangle(cx - x, cy + y, cx, cy + y, Color); break;
case 4: DrawRectangle(cx, cy + y, cx + x, cy + y, Color); break;
case 0:
case 6: DrawRectangle(cx - x, cy - y, cx + x, cy - y, Color); if (Quadrants == 6) break;
case 8: DrawRectangle(cx - x, cy + y, cx + x, cy + y, Color); break;
case -1: DrawRectangle(cx + x, cy - y, x2, cy - y, Color); break;
case -2: DrawRectangle(x1, cy - y, cx - x, cy - y, Color); break;
case -3: DrawRectangle(x1, cy + y, cx - x, cy + y, Color); break;
case -4: DrawRectangle(cx + x, cy + y, x2, cy + y, Color); break;
default: ;
}
y++;
StoppingY += TwoASquare;
EllipseError += YChange;
YChange += TwoASquare;
if (2 * EllipseError + XChange > 0) {
x--;
StoppingX -= TwoBSquare;
EllipseError += XChange;
XChange += TwoBSquare;
}
}
x = 0;
y = ry;
XChange = ry * ry;
YChange = rx * rx * (1 - 2 * ry);
EllipseError = 0;
StoppingX = 0;
StoppingY = TwoASquare * ry;
while (StoppingX <= StoppingY) {
switch (Quadrants) {
case 5: DrawRectangle(cx, cy + y, cx + x, cy + y, Color); // no break
case 1: DrawRectangle(cx, cy - y, cx + x, cy - y, Color); break;
case 7: DrawRectangle(cx - x, cy + y, cx, cy + y, Color); // no break
case 2: DrawRectangle(cx - x, cy - y, cx, cy - y, Color); break;
case 3: DrawRectangle(cx - x, cy + y, cx, cy + y, Color); break;
case 4: DrawRectangle(cx, cy + y, cx + x, cy + y, Color); break;
case 0:
case 6: DrawRectangle(cx - x, cy - y, cx + x, cy - y, Color); if (Quadrants == 6) break;
case 8: DrawRectangle(cx - x, cy + y, cx + x, cy + y, Color); break;
case -1: DrawRectangle(cx + x, cy - y, x2, cy - y, Color); break;
case -2: DrawRectangle(x1, cy - y, cx - x, cy - y, Color); break;
case -3: DrawRectangle(x1, cy + y, cx - x, cy + y, Color); break;
case -4: DrawRectangle(cx + x, cy + y, x2, cy + y, Color); break;
default: ;
}
x++;
StoppingX += TwoBSquare;
EllipseError += XChange;
XChange += TwoBSquare;
if (2 * EllipseError + YChange > 0) {
y--;
StoppingY -= TwoASquare;
EllipseError += YChange;
YChange += TwoASquare;
}
}
}
void cBitmap::DrawSlope(int x1, int y1, int x2, int y2, tColor Color, int Type)
{
// TODO This is just a quick and dirty implementation of a slope drawing
// machanism. If somebody can come up with a better solution, let's have it!
if (!Intersects(x1, y1, x2, y2))
return;
bool upper = Type & 0x01;
bool falling = Type & 0x02;
bool vertical = Type & 0x04;
if (vertical) {
for (int y = y1; y <= y2; y++) {
double c = cos((y - y1) * M_PI / (y2 - y1 + 1));
if (falling)
c = -c;
int x = int((x2 - x1 + 1) * c / 2);
if (upper && !falling || !upper && falling)
DrawRectangle(x1, y, (x1 + x2) / 2 + x, y, Color);
else
DrawRectangle((x1 + x2) / 2 + x, y, x2, y, Color);
}
}
else {
for (int x = x1; x <= x2; x++) {
double c = cos((x - x1) * M_PI / (x2 - x1 + 1));
if (falling)
c = -c;
int y = int((y2 - y1 + 1) * c / 2);
if (upper)
DrawRectangle(x, y1, x, (y1 + y2) / 2 + y, Color);
else
DrawRectangle(x, (y1 + y2) / 2 + y, x, y2, Color);
}
}
}
const tIndex *cBitmap::Data(int x, int y) const
{
return &bitmap[y * width + x];
}
void cBitmap::ReduceBpp(const cPalette &Palette)
{
int NewBpp = Palette.Bpp();
if (Bpp() == 4 && NewBpp == 2) {
for (int i = width * height; i--; ) {
tIndex p = bitmap[i];
bitmap[i] = (p >> 2) | ((p & 0x03) != 0);
}
}
else if (Bpp() == 8) {
if (NewBpp == 2) {
for (int i = width * height; i--; ) {
tIndex p = bitmap[i];
bitmap[i] = (p >> 6) | ((p & 0x30) != 0);
}
}
else if (NewBpp == 4) {
for (int i = width * height; i--; ) {
tIndex p = bitmap[i];
bitmap[i] = p >> 4;
}
}
else
return;
}
else
return;
SetBpp(NewBpp);
Replace(Palette);
}
void cBitmap::ShrinkBpp(int NewBpp)
{
int NumOldColors;
const tColor *Colors = this->Colors(NumOldColors);
if (Colors) {
// Find the most frequently used colors and create a map table:
int Used[MAXNUMCOLORS] = { 0 };
int Map[MAXNUMCOLORS] = { 0 };
for (int i = width * height; i--; )
Used[bitmap[i]]++;
int MaxNewColors = (NewBpp == 4) ? 16 : 4;
cPalette NewPalette(NewBpp);
for (int i = 0; i < MaxNewColors; i++) {
int Max = 0;
int Index = -1;
for (int n = 0; n < NumOldColors; n++) {
if (Used[n] > Max) {
Max = Used[n];
Index = n;
}
}
if (Index >= 0) {
Used[Index] = 0;
Map[Index] = i;
NewPalette.SetColor(i, Colors[Index]);
}
else
break;
}
// Complete the map table for all other colors (will be set to closest match):
for (int n = 0; n < NumOldColors; n++) {
if (Used[n])
Map[n] = NewPalette.Index(Colors[n]);
}
// Do the actual index mapping:
for (int i = width * height; i--; )
bitmap[i] = Map[bitmap[i]];
SetBpp(NewBpp);
Replace(NewPalette);
}
}
// --- cOsd ------------------------------------------------------------------
int cOsd::osdLeft = 0;
int cOsd::osdTop = 0;
int cOsd::osdWidth = 0;
int cOsd::osdHeight = 0;
cVector<cOsd *> cOsd::Osds;
cOsd::cOsd(int Left, int Top, uint Level)
{
savedRegion = NULL;
numBitmaps = 0;
left = Left;
top = Top;
width = height = 0;
level = Level;
active = false;
for (int i = 0; i < Osds.Size(); i++) {
if (Osds[i]->level > level) {
Osds.Insert(this, i);
return;
}
}
Osds.Append(this);
}
cOsd::~cOsd()
{
for (int i = 0; i < numBitmaps; i++)
delete bitmaps[i];
delete savedRegion;
for (int i = 0; i < Osds.Size(); i++) {
if (Osds[i] == this) {
Osds.Remove(i);
if (Osds.Size())
Osds[0]->SetActive(true);
break;
}
}
}
void cOsd::SetOsdPosition(int Left, int Top, int Width, int Height)
{
osdLeft = Left;
osdTop = Top;
osdWidth = min(max(Width, MINOSDWIDTH), MAXOSDWIDTH);
osdHeight = min(max(Height, MINOSDHEIGHT), MAXOSDHEIGHT);
}
void cOsd::SetAntiAliasGranularity(uint FixedColors, uint BlendColors)
{
for (int i = 0; i < numBitmaps; i++)
bitmaps[i]->SetAntiAliasGranularity(FixedColors, BlendColors);
}
cBitmap *cOsd::GetBitmap(int Area)
{
return Area < numBitmaps ? bitmaps[Area] : NULL;
}
eOsdError cOsd::CanHandleAreas(const tArea *Areas, int NumAreas)
{
if (NumAreas > MAXOSDAREAS)
return oeTooManyAreas;
eOsdError Result = oeOk;
for (int i = 0; i < NumAreas; i++) {
if (Areas[i].x1 > Areas[i].x2 || Areas[i].y1 > Areas[i].y2 || Areas[i].x1 < 0 || Areas[i].y1 < 0)
return oeWrongAlignment;
for (int j = i + 1; j < NumAreas; j++) {
if (Areas[i].Intersects(Areas[j])) {
Result = oeAreasOverlap;
break;
}
}
}
return Result;
}
eOsdError cOsd::SetAreas(const tArea *Areas, int NumAreas)
{
eOsdError Result = CanHandleAreas(Areas, NumAreas);
if (Result == oeOk) {
while (numBitmaps)
delete bitmaps[--numBitmaps];
width = height = 0;
for (int i = 0; i < NumAreas; i++) {
bitmaps[numBitmaps++] = new cBitmap(Areas[i].Width(), Areas[i].Height(), Areas[i].bpp, Areas[i].x1, Areas[i].y1);
width = max(width, Areas[i].x2 + 1);
height = max(height, Areas[i].y2 + 1);
}
}
else
esyslog("ERROR: cOsd::SetAreas returned %d", Result);
return Result;
}
void cOsd::SaveRegion(int x1, int y1, int x2, int y2)
{
delete savedRegion;
savedRegion = new cBitmap(x2 - x1 + 1, y2 - y1 + 1, 8, x1, y1);
for (int i = 0; i < numBitmaps; i++)
savedRegion->DrawBitmap(bitmaps[i]->X0(), bitmaps[i]->Y0(), *bitmaps[i]);
}
void cOsd::RestoreRegion(void)
{
if (savedRegion) {
DrawBitmap(savedRegion->X0(), savedRegion->Y0(), *savedRegion);
delete savedRegion;
savedRegion = NULL;
}
}
eOsdError cOsd::SetPalette(const cPalette &Palette, int Area)
{
if (Area < numBitmaps)
bitmaps[Area]->Take(Palette);
return oeUnknown;
}
void cOsd::DrawPixel(int x, int y, tColor Color)
{
for (int i = 0; i < numBitmaps; i++)
bitmaps[i]->DrawPixel(x, y, Color);
}
void cOsd::DrawBitmap(int x, int y, const cBitmap &Bitmap, tColor ColorFg, tColor ColorBg, bool ReplacePalette, bool Overlay)
{
for (int i = 0; i < numBitmaps; i++)
bitmaps[i]->DrawBitmap(x, y, Bitmap, ColorFg, ColorBg, ReplacePalette, Overlay);
}
void cOsd::DrawText(int x, int y, const char *s, tColor ColorFg, tColor ColorBg, const cFont *Font, int Width, int Height, int Alignment)
{
for (int i = 0; i < numBitmaps; i++)
bitmaps[i]->DrawText(x, y, s, ColorFg, ColorBg, Font, Width, Height, Alignment);
}
void cOsd::DrawRectangle(int x1, int y1, int x2, int y2, tColor Color)
{
for (int i = 0; i < numBitmaps; i++)
bitmaps[i]->DrawRectangle(x1, y1, x2, y2, Color);
}
void cOsd::DrawEllipse(int x1, int y1, int x2, int y2, tColor Color, int Quadrants)
{
for (int i = 0; i < numBitmaps; i++)
bitmaps[i]->DrawEllipse(x1, y1, x2, y2, Color, Quadrants);
}
void cOsd::DrawSlope(int x1, int y1, int x2, int y2, tColor Color, int Type)
{
for (int i = 0; i < numBitmaps; i++)
bitmaps[i]->DrawSlope(x1, y1, x2, y2, Color, Type);
}
void cOsd::Flush(void)
{
}
// --- cOsdProvider ----------------------------------------------------------
cOsdProvider *cOsdProvider::osdProvider = NULL;
int cOsdProvider::oldWidth = 0;
int cOsdProvider::oldHeight = 0;
double cOsdProvider::oldAspect = 1.0;
cOsdProvider::cOsdProvider(void)
{
delete osdProvider;
osdProvider = this;
}
cOsdProvider::~cOsdProvider()
{
osdProvider = NULL;
}
cOsd *cOsdProvider::NewOsd(int Left, int Top, uint Level)
{
if (Level == OSD_LEVEL_DEFAULT && cOsd::IsOpen())
esyslog("ERROR: attempt to open OSD while it is already open - using dummy OSD!");
else if (osdProvider) {
cOsd *ActiveOsd = cOsd::Osds.Size() ? cOsd::Osds[0] : NULL;
cOsd *Osd = osdProvider->CreateOsd(Left, Top, Level);
if (Osd == cOsd::Osds[0]) {
if (ActiveOsd)
ActiveOsd->SetActive(false);
Osd->SetActive(true);
}
return Osd;
}
else
esyslog("ERROR: no OSD provider available - using dummy OSD!");
return new cOsd(Left, Top, 999); // create a dummy cOsd, so that access won't result in a segfault
}
void cOsdProvider::UpdateOsdSize(bool Force)
{
int Width;
int Height;
double Aspect;
cDevice::PrimaryDevice()->GetOsdSize(Width, Height, Aspect);
if (Width != oldWidth || Height != oldHeight || !DoubleEqual(Aspect, oldAspect) || Force) {
Setup.OSDLeft = int(round(Width * Setup.OSDLeftP));
Setup.OSDTop = int(round(Height * Setup.OSDTopP));
Setup.OSDWidth = int(round(Width * Setup.OSDWidthP)) & ~0x07; // OSD width must be a multiple of 8
Setup.OSDHeight = int(round(Height * Setup.OSDHeightP));
Setup.OSDAspect = Aspect;
Setup.FontOsdSize = int(round(Height * Setup.FontOsdSizeP));
Setup.FontFixSize = int(round(Height * Setup.FontFixSizeP));
Setup.FontSmlSize = int(round(Height * Setup.FontSmlSizeP));
cFont::SetFont(fontOsd, Setup.FontOsd, Setup.FontOsdSize);
cFont::SetFont(fontFix, Setup.FontFix, Setup.FontFixSize);
cFont::SetFont(fontSml, Setup.FontSml, Setup.FontSmlSize);
oldWidth = Width;
oldHeight = Height;
oldAspect = Aspect;
dsyslog("OSD size changed to %dx%d @ %g", Width, Height, Aspect);
}
}
void cOsdProvider::Shutdown(void)
{
delete osdProvider;
osdProvider = NULL;
}
// --- cTextScroller ---------------------------------------------------------
cTextScroller::cTextScroller(void)
{
osd = NULL;
left = top = width = height = 0;
font = NULL;
colorFg = 0;
colorBg = 0;
offset = 0;
shown = 0;
}
cTextScroller::cTextScroller(cOsd *Osd, int Left, int Top, int Width, int Height, const char *Text, const cFont *Font, tColor ColorFg, tColor ColorBg)
{
Set(Osd, Left, Top, Width, Height, Text, Font, ColorFg, ColorBg);
}
void cTextScroller::Set(cOsd *Osd, int Left, int Top, int Width, int Height, const char *Text, const cFont *Font, tColor ColorFg, tColor ColorBg)
{
osd = Osd;
left = Left;
top = Top;
width = Width;
height = Height;
font = Font;
colorFg = ColorFg;
colorBg = ColorBg;
offset = 0;
textWrapper.Set(Text, Font, Width);
shown = min(Total(), height / font->Height());
height = shown * font->Height(); // sets height to the actually used height, which may be less than Height
DrawText();
}
void cTextScroller::Reset(void)
{
osd = NULL; // just makes sure it won't draw anything
}
void cTextScroller::DrawText(void)
{
if (osd) {
for (int i = 0; i < shown; i++)
osd->DrawText(left, top + i * font->Height(), textWrapper.GetLine(offset + i), colorFg, colorBg, font, width);
}
}
void cTextScroller::Scroll(bool Up, bool Page)
{
if (Up) {
if (CanScrollUp()) {
offset -= Page ? shown : 1;
if (offset < 0)
offset = 0;
DrawText();
}
}
else {
if (CanScrollDown()) {
offset += Page ? shown : 1;
if (offset + shown > Total())
offset = Total() - shown;
DrawText();
}
}
}
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