/*
* This file is part of OpenTTD.
* OpenTTD 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.
* OpenTTD 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 OpenTTD. If not, see .
*/
/** @file gfx.cpp Handling of drawing text and other gfx related stuff. */
#include "stdafx.h"
#include "gfx_layout.h"
#include "progress.h"
#include "zoom_func.h"
#include "blitter/factory.hpp"
#include "video/video_driver.hpp"
#include "strings_func.h"
#include "settings_type.h"
#include "network/network.h"
#include "network/network_func.h"
#include "window_func.h"
#include "newgrf_debug.h"
#include "thread.h"
#include "table/palettes.h"
#include "table/string_colours.h"
#include "table/sprites.h"
#include "table/control_codes.h"
#include "safeguards.h"
byte _dirkeys; ///< 1 = left, 2 = up, 4 = right, 8 = down
bool _fullscreen;
byte _support8bpp;
CursorVars _cursor;
bool _ctrl_pressed; ///< Is Ctrl pressed?
bool _shift_pressed; ///< Is Shift pressed?
byte _fast_forward;
bool _left_button_down; ///< Is left mouse button pressed?
bool _left_button_clicked; ///< Is left mouse button clicked?
bool _right_button_down; ///< Is right mouse button pressed?
bool _right_button_clicked; ///< Is right mouse button clicked?
DrawPixelInfo _screen;
bool _screen_disable_anim = false; ///< Disable palette animation (important for 32bpp-anim blitter during giant screenshot)
bool _exit_game;
GameMode _game_mode;
SwitchMode _switch_mode; ///< The next mainloop command.
PauseMode _pause_mode;
Palette _cur_palette;
static byte _stringwidth_table[FS_END][224]; ///< Cache containing width of often used characters. @see GetCharacterWidth()
DrawPixelInfo *_cur_dpi;
byte _colour_gradient[COLOUR_END][8];
static void GfxMainBlitterViewport(const Sprite *sprite, int x, int y, BlitterMode mode, const SubSprite *sub = nullptr, SpriteID sprite_id = SPR_CURSOR_MOUSE);
static void GfxMainBlitter(const Sprite *sprite, int x, int y, BlitterMode mode, const SubSprite *sub = nullptr, SpriteID sprite_id = SPR_CURSOR_MOUSE, ZoomLevel zoom = ZOOM_LVL_NORMAL);
static ReusableBuffer _cursor_backup;
ZoomLevel _gui_zoom; ///< GUI Zoom level
ZoomLevel _font_zoom; ///< Font Zoom level
/**
* The rect for repaint.
*
* This rectangle defines the area which should be repaint by the video driver.
*
* @ingroup dirty
*/
static Rect _invalid_rect;
static const byte *_colour_remap_ptr;
static byte _string_colourremap[3]; ///< Recoloursprite for stringdrawing. The grf loader ensures that #ST_FONT sprites only use colours 0 to 2.
static const uint DIRTY_BLOCK_HEIGHT = 8;
static const uint DIRTY_BLOCK_WIDTH = 64;
static uint _dirty_bytes_per_line = 0;
static byte *_dirty_blocks = nullptr;
extern uint _dirty_block_colour;
void GfxScroll(int left, int top, int width, int height, int xo, int yo)
{
Blitter *blitter = BlitterFactory::GetCurrentBlitter();
if (xo == 0 && yo == 0) return;
if (_cursor.visible) UndrawMouseCursor();
if (_networking) NetworkUndrawChatMessage();
blitter->ScrollBuffer(_screen.dst_ptr, left, top, width, height, xo, yo);
/* This part of the screen is now dirty. */
VideoDriver::GetInstance()->MakeDirty(left, top, width, height);
}
/**
* Applies a certain FillRectMode-operation to a rectangle [left, right] x [top, bottom] on the screen.
*
* @pre dpi->zoom == ZOOM_LVL_NORMAL, right >= left, bottom >= top
* @param left Minimum X (inclusive)
* @param top Minimum Y (inclusive)
* @param right Maximum X (inclusive)
* @param bottom Maximum Y (inclusive)
* @param colour A 8 bit palette index (FILLRECT_OPAQUE and FILLRECT_CHECKER) or a recolour spritenumber (FILLRECT_RECOLOUR)
* @param mode
* FILLRECT_OPAQUE: Fill the rectangle with the specified colour
* FILLRECT_CHECKER: Like FILLRECT_OPAQUE, but only draw every second pixel (used to grey out things)
* FILLRECT_RECOLOUR: Apply a recolour sprite to every pixel in the rectangle currently on screen
*/
void GfxFillRect(int left, int top, int right, int bottom, int colour, FillRectMode mode)
{
Blitter *blitter = BlitterFactory::GetCurrentBlitter();
const DrawPixelInfo *dpi = _cur_dpi;
void *dst;
const int otop = top;
const int oleft = left;
if (dpi->zoom != ZOOM_LVL_NORMAL) return;
if (left > right || top > bottom) return;
if (right < dpi->left || left >= dpi->left + dpi->width) return;
if (bottom < dpi->top || top >= dpi->top + dpi->height) return;
if ( (left -= dpi->left) < 0) left = 0;
right = right - dpi->left + 1;
if (right > dpi->width) right = dpi->width;
right -= left;
assert(right > 0);
if ( (top -= dpi->top) < 0) top = 0;
bottom = bottom - dpi->top + 1;
if (bottom > dpi->height) bottom = dpi->height;
bottom -= top;
assert(bottom > 0);
dst = blitter->MoveTo(dpi->dst_ptr, left, top);
switch (mode) {
default: // FILLRECT_OPAQUE
blitter->DrawRect(dst, right, bottom, (uint8)colour);
break;
case FILLRECT_RECOLOUR:
blitter->DrawColourMappingRect(dst, right, bottom, GB(colour, 0, PALETTE_WIDTH));
break;
case FILLRECT_CHECKER: {
byte bo = (oleft - left + dpi->left + otop - top + dpi->top) & 1;
do {
for (int i = (bo ^= 1); i < right; i += 2) blitter->SetPixel(dst, i, 0, (uint8)colour);
dst = blitter->MoveTo(dst, 0, 1);
} while (--bottom > 0);
break;
}
}
}
typedef std::pair LineSegment;
/**
* Make line segments from a polygon defined by points, translated by an offset.
* Entirely horizontal lines (start and end at same Y coordinate) are skipped, as they are irrelevant to scanline conversion algorithms.
* Generated line segments always have the lowest Y coordinate point first, i.e. original direction is lost.
* @param shape The polygon to convert.
* @param offset Offset vector subtracted from all coordinates in the shape.
* @return Vector of undirected line segments.
*/
static std::vector MakePolygonSegments(const std::vector &shape, Point offset)
{
std::vector segments;
if (shape.size() < 3) return segments; // fewer than 3 will always result in an empty polygon
segments.reserve(shape.size());
/* Connect first and last point by having initial previous point be the last */
Point prev = shape.back();
prev.x -= offset.x;
prev.y -= offset.y;
for (Point pt : shape) {
pt.x -= offset.x;
pt.y -= offset.y;
/* Create segments for all non-horizontal lines in the polygon.
* The segments always have lowest Y coordinate first. */
if (prev.y > pt.y) {
segments.emplace_back(pt, prev);
} else if (prev.y < pt.y) {
segments.emplace_back(prev, pt);
}
prev = pt;
}
return segments;
}
/**
* Fill a polygon with colour.
* The odd-even winding rule is used, i.e. self-intersecting polygons will have holes in them.
* Left and top edges are inclusive, right and bottom edges are exclusive.
* @note For rectangles the GfxFillRect function will be faster.
* @pre dpi->zoom == ZOOM_LVL_NORMAL
* @param shape List of points on the polygon.
* @param colour An 8 bit palette index (FILLRECT_OPAQUE and FILLRECT_CHECKER) or a recolour spritenumber (FILLRECT_RECOLOUR).
* @param mode
* FILLRECT_OPAQUE: Fill the polygon with the specified colour.
* FILLRECT_CHECKER: Fill every other pixel with the specified colour, in a checkerboard pattern.
* FILLRECT_RECOLOUR: Apply a recolour sprite to every pixel in the polygon.
*/
void GfxFillPolygon(const std::vector &shape, int colour, FillRectMode mode)
{
Blitter *blitter = BlitterFactory::GetCurrentBlitter();
const DrawPixelInfo *dpi = _cur_dpi;
if (dpi->zoom != ZOOM_LVL_NORMAL) return;
std::vector segments = MakePolygonSegments(shape, Point{ dpi->left, dpi->top });
/* Remove segments appearing entirely above or below the clipping area. */
segments.erase(std::remove_if(segments.begin(), segments.end(), [dpi](const LineSegment &s) { return s.second.y <= 0 || s.first.y >= dpi->height; }), segments.end());
/* Check that this wasn't an empty shape (all points on a horizontal line or outside clipping.) */
if (segments.empty()) return;
/* Sort the segments by first point Y coordinate. */
std::sort(segments.begin(), segments.end(), [](const LineSegment &a, const LineSegment &b) { return a.first.y < b.first.y; });
/* Segments intersecting current scanline. */
std::vector active;
/* Intersection points with a scanline.
* Kept outside loop to avoid repeated re-allocations. */
std::vector intersections;
/* Normal, reasonable polygons don't have many intersections per scanline. */
active.reserve(4);
intersections.reserve(4);
/* Scan through the segments and paint each scanline. */
int y = segments.front().first.y;
std::vector::iterator nextseg = segments.begin();
while (!active.empty() || nextseg != segments.end()) {
/* Clean up segments that have ended. */
active.erase(std::remove_if(active.begin(), active.end(), [y](const LineSegment &s) { return s.second.y == y; }), active.end());
/* Activate all segments starting on this scanline. */
while (nextseg != segments.end() && nextseg->first.y == y) {
active.push_back(*nextseg);
++nextseg;
}
/* Check clipping. */
if (y < 0) {
++y;
continue;
}
if (y >= dpi->height) return;
/* Intersect scanline with all active segments. */
intersections.clear();
for (const LineSegment &s : active) {
const int sdx = s.second.x - s.first.x;
const int sdy = s.second.y - s.first.y;
const int ldy = y - s.first.y;
const int x = s.first.x + sdx * ldy / sdy;
intersections.push_back(x);
}
/* Fill between pairs of intersections. */
std::sort(intersections.begin(), intersections.end());
for (size_t i = 1; i < intersections.size(); i += 2) {
/* Check clipping. */
const int x1 = max(0, intersections[i - 1]);
const int x2 = min(intersections[i], dpi->width);
if (x2 < 0) continue;
if (x1 >= dpi->width) continue;
/* Fill line y from x1 to x2. */
void *dst = blitter->MoveTo(dpi->dst_ptr, x1, y);
switch (mode) {
default: // FILLRECT_OPAQUE
blitter->DrawRect(dst, x2 - x1, 1, (uint8)colour);
break;
case FILLRECT_RECOLOUR:
blitter->DrawColourMappingRect(dst, x2 - x1, 1, GB(colour, 0, PALETTE_WIDTH));
break;
case FILLRECT_CHECKER:
/* Fill every other pixel, offset such that the sum of filled pixels' X and Y coordinates is odd.
* This creates a checkerboard effect. */
for (int x = (x1 + y) & 1; x < x2 - x1; x += 2) {
blitter->SetPixel(dst, x, 0, (uint8)colour);
}
break;
}
}
/* Next line */
++y;
}
}
/**
* Check line clipping by using a linear equation and draw the visible part of
* the line given by x/y and x2/y2.
* @param video Destination pointer to draw into.
* @param x X coordinate of first point.
* @param y Y coordinate of first point.
* @param x2 X coordinate of second point.
* @param y2 Y coordinate of second point.
* @param screen_width With of the screen to check clipping against.
* @param screen_height Height of the screen to check clipping against.
* @param colour Colour of the line.
* @param width Width of the line.
* @param dash Length of dashes for dashed lines. 0 means solid line.
*/
static inline void GfxDoDrawLine(void *video, int x, int y, int x2, int y2, int screen_width, int screen_height, uint8 colour, int width, int dash = 0)
{
Blitter *blitter = BlitterFactory::GetCurrentBlitter();
assert(width > 0);
if (y2 == y || x2 == x) {
/* Special case: horizontal/vertical line. All checks already done in GfxPreprocessLine. */
blitter->DrawLine(video, x, y, x2, y2, screen_width, screen_height, colour, width, dash);
return;
}
int grade_y = y2 - y;
int grade_x = x2 - x;
/* Clipping rectangle. Slightly extended so we can ignore the width of the line. */
int extra = (int)CeilDiv(3 * width, 4); // not less then "width * sqrt(2) / 2"
Rect clip = { -extra, -extra, screen_width - 1 + extra, screen_height - 1 + extra };
/* prevent integer overflows. */
int margin = 1;
while (INT_MAX / abs(grade_y) < max(abs(clip.left - x), abs(clip.right - x))) {
grade_y /= 2;
grade_x /= 2;
margin *= 2; // account for rounding errors
}
/* Imagine that the line is infinitely long and it intersects with
* infinitely long left and right edges of the clipping rectangle.
* If both intersection points are outside the clipping rectangle
* and both on the same side of it, we don't need to draw anything. */
int left_isec_y = y + (clip.left - x) * grade_y / grade_x;
int right_isec_y = y + (clip.right - x) * grade_y / grade_x;
if ((left_isec_y > clip.bottom + margin && right_isec_y > clip.bottom + margin) ||
(left_isec_y < clip.top - margin && right_isec_y < clip.top - margin)) {
return;
}
/* It is possible to use the line equation to further reduce the amount of
* work the blitter has to do by shortening the effective line segment.
* However, in order to get that right and prevent the flickering effects
* of rounding errors so much additional code has to be run here that in
* the general case the effect is not noticeable. */
blitter->DrawLine(video, x, y, x2, y2, screen_width, screen_height, colour, width, dash);
}
/**
* Align parameters of a line to the given DPI and check simple clipping.
* @param dpi Screen parameters to align with.
* @param x X coordinate of first point.
* @param y Y coordinate of first point.
* @param x2 X coordinate of second point.
* @param y2 Y coordinate of second point.
* @param width Width of the line.
* @return True if the line is likely to be visible, false if it's certainly
* invisible.
*/
static inline bool GfxPreprocessLine(DrawPixelInfo *dpi, int &x, int &y, int &x2, int &y2, int width)
{
x -= dpi->left;
x2 -= dpi->left;
y -= dpi->top;
y2 -= dpi->top;
/* Check simple clipping */
if (x + width / 2 < 0 && x2 + width / 2 < 0 ) return false;
if (y + width / 2 < 0 && y2 + width / 2 < 0 ) return false;
if (x - width / 2 > dpi->width && x2 - width / 2 > dpi->width ) return false;
if (y - width / 2 > dpi->height && y2 - width / 2 > dpi->height) return false;
return true;
}
void GfxDrawLine(int x, int y, int x2, int y2, int colour, int width, int dash)
{
DrawPixelInfo *dpi = _cur_dpi;
if (GfxPreprocessLine(dpi, x, y, x2, y2, width)) {
GfxDoDrawLine(dpi->dst_ptr, x, y, x2, y2, dpi->width, dpi->height, colour, width, dash);
}
}
void GfxDrawLineUnscaled(int x, int y, int x2, int y2, int colour)
{
DrawPixelInfo *dpi = _cur_dpi;
if (GfxPreprocessLine(dpi, x, y, x2, y2, 1)) {
GfxDoDrawLine(dpi->dst_ptr,
UnScaleByZoom(x, dpi->zoom), UnScaleByZoom(y, dpi->zoom),
UnScaleByZoom(x2, dpi->zoom), UnScaleByZoom(y2, dpi->zoom),
UnScaleByZoom(dpi->width, dpi->zoom), UnScaleByZoom(dpi->height, dpi->zoom), colour, 1);
}
}
/**
* Draws the projection of a parallelepiped.
* This can be used to draw boxes in world coordinates.
*
* @param x Screen X-coordinate of top front corner.
* @param y Screen Y-coordinate of top front corner.
* @param dx1 Screen X-length of first edge.
* @param dy1 Screen Y-length of first edge.
* @param dx2 Screen X-length of second edge.
* @param dy2 Screen Y-length of second edge.
* @param dx3 Screen X-length of third edge.
* @param dy3 Screen Y-length of third edge.
*/
void DrawBox(int x, int y, int dx1, int dy1, int dx2, int dy2, int dx3, int dy3)
{
/* ....
* .. ....
* .. ....
* .. ^
* <--__(dx1,dy1) /(dx2,dy2)
* : --__ / :
* : --__ / :
* : *(x,y) :
* : | :
* : | ..
* .... |(dx3,dy3)
* .... | ..
* ....V.
*/
static const byte colour = PC_WHITE;
GfxDrawLineUnscaled(x, y, x + dx1, y + dy1, colour);
GfxDrawLineUnscaled(x, y, x + dx2, y + dy2, colour);
GfxDrawLineUnscaled(x, y, x + dx3, y + dy3, colour);
GfxDrawLineUnscaled(x + dx1, y + dy1, x + dx1 + dx2, y + dy1 + dy2, colour);
GfxDrawLineUnscaled(x + dx1, y + dy1, x + dx1 + dx3, y + dy1 + dy3, colour);
GfxDrawLineUnscaled(x + dx2, y + dy2, x + dx2 + dx1, y + dy2 + dy1, colour);
GfxDrawLineUnscaled(x + dx2, y + dy2, x + dx2 + dx3, y + dy2 + dy3, colour);
GfxDrawLineUnscaled(x + dx3, y + dy3, x + dx3 + dx1, y + dy3 + dy1, colour);
GfxDrawLineUnscaled(x + dx3, y + dy3, x + dx3 + dx2, y + dy3 + dy2, colour);
}
/**
* Set the colour remap to be for the given colour.
* @param colour the new colour of the remap.
*/
static void SetColourRemap(TextColour colour)
{
if (colour == TC_INVALID) return;
/* Black strings have no shading ever; the shading is black, so it
* would be invisible at best, but it actually makes it illegible. */
bool no_shade = (colour & TC_NO_SHADE) != 0 || colour == TC_BLACK;
bool raw_colour = (colour & TC_IS_PALETTE_COLOUR) != 0;
colour &= ~(TC_NO_SHADE | TC_IS_PALETTE_COLOUR | TC_FORCED);
_string_colourremap[1] = raw_colour ? (byte)colour : _string_colourmap[colour];
_string_colourremap[2] = no_shade ? 0 : 1;
_colour_remap_ptr = _string_colourremap;
}
/**
* Drawing routine for drawing a laid out line of text.
* @param line String to draw.
* @param y The top most position to draw on.
* @param left The left most position to draw on.
* @param right The right most position to draw on.
* @param align The alignment of the string when drawing left-to-right. In the
* case a right-to-left language is chosen this is inverted so it
* will be drawn in the right direction.
* @param underline Whether to underline what has been drawn or not.
* @param truncation Whether to perform string truncation or not.
*
* @return In case of left or center alignment the right most pixel we have drawn to.
* In case of right alignment the left most pixel we have drawn to.
*/
static int DrawLayoutLine(const ParagraphLayouter::Line &line, int y, int left, int right, StringAlignment align, bool underline, bool truncation)
{
if (line.CountRuns() == 0) return 0;
int w = line.GetWidth();
int h = line.GetLeading();
/*
* The following is needed for truncation.
* Depending on the text direction, we either remove bits at the rear
* or the front. For this we shift the entire area to draw so it fits
* within the left/right bounds and the side we do not truncate it on.
* Then we determine the truncation location, i.e. glyphs that fall
* outside of the range min_x - max_x will not be drawn; they are thus
* the truncated glyphs.
*
* At a later step we insert the dots.
*/
int max_w = right - left + 1; // The maximum width.
int offset_x = 0; // The offset we need for positioning the glyphs
int min_x = left; // The minimum x position to draw normal glyphs on.
int max_x = right; // The maximum x position to draw normal glyphs on.
truncation &= max_w < w; // Whether we need to do truncation.
int dot_width = 0; // Cache for the width of the dot.
const Sprite *dot_sprite = nullptr; // Cache for the sprite of the dot.
if (truncation) {
/*
* Assumption may be made that all fonts of a run are of the same size.
* In any case, we'll use these dots for the abbreviation, so even if
* another size would be chosen it won't have truncated too little for
* the truncation dots.
*/
FontCache *fc = ((const Font*)line.GetVisualRun(0).GetFont())->fc;
GlyphID dot_glyph = fc->MapCharToGlyph('.');
dot_width = fc->GetGlyphWidth(dot_glyph);
dot_sprite = fc->GetGlyph(dot_glyph);
if (_current_text_dir == TD_RTL) {
min_x += 3 * dot_width;
offset_x = w - 3 * dot_width - max_w;
} else {
max_x -= 3 * dot_width;
}
w = max_w;
}
/* In case we have a RTL language we swap the alignment. */
if (!(align & SA_FORCE) && _current_text_dir == TD_RTL && (align & SA_HOR_MASK) != SA_HOR_CENTER) align ^= SA_RIGHT;
/* right is the right most position to draw on. In this case we want to do
* calculations with the width of the string. In comparison right can be
* seen as lastof(todraw) and width as lengthof(todraw). They differ by 1.
* So most +1/-1 additions are to move from lengthof to 'indices'.
*/
switch (align & SA_HOR_MASK) {
case SA_LEFT:
/* right + 1 = left + w */
right = left + w - 1;
break;
case SA_HOR_CENTER:
left = RoundDivSU(right + 1 + left - w, 2);
/* right + 1 = left + w */
right = left + w - 1;
break;
case SA_RIGHT:
left = right + 1 - w;
break;
default:
NOT_REACHED();
}
TextColour colour = TC_BLACK;
bool draw_shadow = false;
for (int run_index = 0; run_index < line.CountRuns(); run_index++) {
const ParagraphLayouter::VisualRun &run = line.GetVisualRun(run_index);
const Font *f = (const Font*)run.GetFont();
FontCache *fc = f->fc;
colour = f->colour;
SetColourRemap(colour);
DrawPixelInfo *dpi = _cur_dpi;
int dpi_left = dpi->left;
int dpi_right = dpi->left + dpi->width - 1;
draw_shadow = fc->GetDrawGlyphShadow() && (colour & TC_NO_SHADE) == 0 && colour != TC_BLACK;
for (int i = 0; i < run.GetGlyphCount(); i++) {
GlyphID glyph = run.GetGlyphs()[i];
/* Not a valid glyph (empty) */
if (glyph == 0xFFFF) continue;
int begin_x = (int)run.GetPositions()[i * 2] + left - offset_x;
int end_x = (int)run.GetPositions()[i * 2 + 2] + left - offset_x - 1;
int top = (int)run.GetPositions()[i * 2 + 1] + y;
/* Truncated away. */
if (truncation && (begin_x < min_x || end_x > max_x)) continue;
const Sprite *sprite = fc->GetGlyph(glyph);
/* Check clipping (the "+ 1" is for the shadow). */
if (begin_x + sprite->x_offs > dpi_right || begin_x + sprite->x_offs + sprite->width /* - 1 + 1 */ < dpi_left) continue;
if (draw_shadow && (glyph & SPRITE_GLYPH) == 0) {
SetColourRemap(TC_BLACK);
GfxMainBlitter(sprite, begin_x + 1, top + 1, BM_COLOUR_REMAP);
SetColourRemap(colour);
}
GfxMainBlitter(sprite, begin_x, top, BM_COLOUR_REMAP);
}
}
if (truncation) {
int x = (_current_text_dir == TD_RTL) ? left : (right - 3 * dot_width);
for (int i = 0; i < 3; i++, x += dot_width) {
if (draw_shadow) {
SetColourRemap(TC_BLACK);
GfxMainBlitter(dot_sprite, x + 1, y + 1, BM_COLOUR_REMAP);
SetColourRemap(colour);
}
GfxMainBlitter(dot_sprite, x, y, BM_COLOUR_REMAP);
}
}
if (underline) {
GfxFillRect(left, y + h, right, y + h, _string_colourremap[1]);
}
return (align & SA_HOR_MASK) == SA_RIGHT ? left : right;
}
/**
* Draw string, possibly truncated to make it fit in its allocated space
*
* @param left The left most position to draw on.
* @param right The right most position to draw on.
* @param top The top most position to draw on.
* @param str String to draw.
* @param colour Colour used for drawing the string, for details see _string_colourmap in
* table/palettes.h or docs/ottd-colourtext-palette.png or the enum TextColour in gfx_type.h
* @param align The alignment of the string when drawing left-to-right. In the
* case a right-to-left language is chosen this is inverted so it
* will be drawn in the right direction.
* @param underline Whether to underline what has been drawn or not.
* @param fontsize The size of the initial characters.
* @return In case of left or center alignment the right most pixel we have drawn to.
* In case of right alignment the left most pixel we have drawn to.
*/
int DrawString(int left, int right, int top, const char *str, TextColour colour, StringAlignment align, bool underline, FontSize fontsize)
{
/* The string may contain control chars to change the font, just use the biggest font for clipping. */
int max_height = max(max(FONT_HEIGHT_SMALL, FONT_HEIGHT_NORMAL), max(FONT_HEIGHT_LARGE, FONT_HEIGHT_MONO));
/* Funny glyphs may extent outside the usual bounds, so relax the clipping somewhat. */
int extra = max_height / 2;
if (_cur_dpi->top + _cur_dpi->height + extra < top || _cur_dpi->top > top + max_height + extra ||
_cur_dpi->left + _cur_dpi->width + extra < left || _cur_dpi->left > right + extra) {
return 0;
}
Layouter layout(str, INT32_MAX, colour, fontsize);
if (layout.size() == 0) return 0;
return DrawLayoutLine(*layout.front(), top, left, right, align, underline, true);
}
/**
* Draw string, possibly truncated to make it fit in its allocated space
*
* @param left The left most position to draw on.
* @param right The right most position to draw on.
* @param top The top most position to draw on.
* @param str String to draw.
* @param colour Colour used for drawing the string, for details see _string_colourmap in
* table/palettes.h or docs/ottd-colourtext-palette.png or the enum TextColour in gfx_type.h
* @param align The alignment of the string when drawing left-to-right. In the
* case a right-to-left language is chosen this is inverted so it
* will be drawn in the right direction.
* @param underline Whether to underline what has been drawn or not.
* @param fontsize The size of the initial characters.
* @return In case of left or center alignment the right most pixel we have drawn to.
* In case of right alignment the left most pixel we have drawn to.
*/
int DrawString(int left, int right, int top, StringID str, TextColour colour, StringAlignment align, bool underline, FontSize fontsize)
{
char buffer[DRAW_STRING_BUFFER];
GetString(buffer, str, lastof(buffer));
return DrawString(left, right, top, buffer, colour, align, underline, fontsize);
}
/**
* Calculates height of string (in pixels). The string is changed to a multiline string if needed.
* @param str string to check
* @param maxw maximum string width
* @return height of pixels of string when it is drawn
*/
int GetStringHeight(const char *str, int maxw, FontSize fontsize)
{
Layouter layout(str, maxw, TC_FROMSTRING, fontsize);
return layout.GetBounds().height;
}
/**
* Calculates height of string (in pixels). The string is changed to a multiline string if needed.
* @param str string to check
* @param maxw maximum string width
* @return height of pixels of string when it is drawn
*/
int GetStringHeight(StringID str, int maxw)
{
char buffer[DRAW_STRING_BUFFER];
GetString(buffer, str, lastof(buffer));
return GetStringHeight(buffer, maxw);
}
/**
* Calculates number of lines of string. The string is changed to a multiline string if needed.
* @param str string to check
* @param maxw maximum string width
* @return number of lines of string when it is drawn
*/
int GetStringLineCount(StringID str, int maxw)
{
char buffer[DRAW_STRING_BUFFER];
GetString(buffer, str, lastof(buffer));
Layouter layout(buffer, maxw);
return (uint)layout.size();
}
/**
* Calculate string bounding box for multi-line strings.
* @param str String to check.
* @param suggestion Suggested bounding box.
* @return Bounding box for the multi-line string, may be bigger than \a suggestion.
*/
Dimension GetStringMultiLineBoundingBox(StringID str, const Dimension &suggestion)
{
Dimension box = {suggestion.width, (uint)GetStringHeight(str, suggestion.width)};
return box;
}
/**
* Calculate string bounding box for multi-line strings.
* @param str String to check.
* @param suggestion Suggested bounding box.
* @return Bounding box for the multi-line string, may be bigger than \a suggestion.
*/
Dimension GetStringMultiLineBoundingBox(const char *str, const Dimension &suggestion)
{
Dimension box = {suggestion.width, (uint)GetStringHeight(str, suggestion.width)};
return box;
}
/**
* Draw string, possibly over multiple lines.
*
* @param left The left most position to draw on.
* @param right The right most position to draw on.
* @param top The top most position to draw on.
* @param bottom The bottom most position to draw on.
* @param str String to draw.
* @param colour Colour used for drawing the string, for details see _string_colourmap in
* table/palettes.h or docs/ottd-colourtext-palette.png or the enum TextColour in gfx_type.h
* @param align The horizontal and vertical alignment of the string.
* @param underline Whether to underline all strings
* @param fontsize The size of the initial characters.
*
* @return If \a align is #SA_BOTTOM, the top to where we have written, else the bottom to where we have written.
*/
int DrawStringMultiLine(int left, int right, int top, int bottom, const char *str, TextColour colour, StringAlignment align, bool underline, FontSize fontsize)
{
int maxw = right - left + 1;
int maxh = bottom - top + 1;
/* It makes no sense to even try if it can't be drawn anyway, or
* do we really want to support fonts of 0 or less pixels high? */
if (maxh <= 0) return top;
Layouter layout(str, maxw, colour, fontsize);
int total_height = layout.GetBounds().height;
int y;
switch (align & SA_VERT_MASK) {
case SA_TOP:
y = top;
break;
case SA_VERT_CENTER:
y = RoundDivSU(bottom + top - total_height, 2);
break;
case SA_BOTTOM:
y = bottom - total_height;
break;
default: NOT_REACHED();
}
int last_line = top;
int first_line = bottom;
for (const auto &line : layout) {
int line_height = line->GetLeading();
if (y >= top && y < bottom) {
last_line = y + line_height;
if (first_line > y) first_line = y;
DrawLayoutLine(*line, y, left, right, align, underline, false);
}
y += line_height;
}
return ((align & SA_VERT_MASK) == SA_BOTTOM) ? first_line : last_line;
}
/**
* Draw string, possibly over multiple lines.
*
* @param left The left most position to draw on.
* @param right The right most position to draw on.
* @param top The top most position to draw on.
* @param bottom The bottom most position to draw on.
* @param str String to draw.
* @param colour Colour used for drawing the string, for details see _string_colourmap in
* table/palettes.h or docs/ottd-colourtext-palette.png or the enum TextColour in gfx_type.h
* @param align The horizontal and vertical alignment of the string.
* @param underline Whether to underline all strings
* @param fontsize The size of the initial characters.
*
* @return If \a align is #SA_BOTTOM, the top to where we have written, else the bottom to where we have written.
*/
int DrawStringMultiLine(int left, int right, int top, int bottom, StringID str, TextColour colour, StringAlignment align, bool underline, FontSize fontsize)
{
char buffer[DRAW_STRING_BUFFER];
GetString(buffer, str, lastof(buffer));
return DrawStringMultiLine(left, right, top, bottom, buffer, colour, align, underline, fontsize);
}
/**
* Return the string dimension in pixels. The height and width are returned
* in a single Dimension value. TINYFONT, BIGFONT modifiers are only
* supported as the first character of the string. The returned dimensions
* are therefore a rough estimation correct for all the current strings
* but not every possible combination
* @param str string to calculate pixel-width
* @param start_fontsize Fontsize to start the text with
* @return string width and height in pixels
*/
Dimension GetStringBoundingBox(const char *str, FontSize start_fontsize)
{
Layouter layout(str, INT32_MAX, TC_FROMSTRING, start_fontsize);
return layout.GetBounds();
}
/**
* Get bounding box of a string. Uses parameters set by #SetDParam if needed.
* Has the same restrictions as #GetStringBoundingBox(const char *str, FontSize start_fontsize).
* @param strid String to examine.
* @return Width and height of the bounding box for the string in pixels.
*/
Dimension GetStringBoundingBox(StringID strid)
{
char buffer[DRAW_STRING_BUFFER];
GetString(buffer, strid, lastof(buffer));
return GetStringBoundingBox(buffer);
}
/**
* Get the leading corner of a character in a single-line string relative
* to the start of the string.
* @param str String containing the character.
* @param ch Pointer to the character in the string.
* @param start_fontsize Font size to start the text with.
* @return Upper left corner of the glyph associated with the character.
*/
Point GetCharPosInString(const char *str, const char *ch, FontSize start_fontsize)
{
Layouter layout(str, INT32_MAX, TC_FROMSTRING, start_fontsize);
return layout.GetCharPosition(ch);
}
/**
* Get the character from a string that is drawn at a specific position.
* @param str String to test.
* @param x Position relative to the start of the string.
* @param start_fontsize Font size to start the text with.
* @return Pointer to the character at the position or nullptr if there is no character at the position.
*/
const char *GetCharAtPosition(const char *str, int x, FontSize start_fontsize)
{
if (x < 0) return nullptr;
Layouter layout(str, INT32_MAX, TC_FROMSTRING, start_fontsize);
return layout.GetCharAtPosition(x);
}
/**
* Draw single character horizontally centered around (x,y)
* @param c Character (glyph) to draw
* @param x X position to draw character
* @param y Y position to draw character
* @param colour Colour to use, for details see _string_colourmap in
* table/palettes.h or docs/ottd-colourtext-palette.png or the enum TextColour in gfx_type.h
*/
void DrawCharCentered(WChar c, int x, int y, TextColour colour)
{
SetColourRemap(colour);
GfxMainBlitter(GetGlyph(FS_NORMAL, c), x - GetCharacterWidth(FS_NORMAL, c) / 2, y, BM_COLOUR_REMAP);
}
/**
* Get the size of a sprite.
* @param sprid Sprite to examine.
* @param[out] offset Optionally returns the sprite position offset.
* @param zoom The zoom level applicable to the sprite.
* @return Sprite size in pixels.
* @note The size assumes (0, 0) as top-left coordinate and ignores any part of the sprite drawn at the left or above that position.
*/
Dimension GetSpriteSize(SpriteID sprid, Point *offset, ZoomLevel zoom)
{
const Sprite *sprite = GetSprite(sprid, ST_NORMAL);
if (offset != nullptr) {
offset->x = UnScaleByZoom(sprite->x_offs, zoom);
offset->y = UnScaleByZoom(sprite->y_offs, zoom);
}
Dimension d;
d.width = max(0, UnScaleByZoom(sprite->x_offs + sprite->width, zoom));
d.height = max(0, UnScaleByZoom(sprite->y_offs + sprite->height, zoom));
return d;
}
/**
* Helper function to get the blitter mode for different types of palettes.
* @param pal The palette to get the blitter mode for.
* @return The blitter mode associated with the palette.
*/
static BlitterMode GetBlitterMode(PaletteID pal)
{
switch (pal) {
case PAL_NONE: return BM_NORMAL;
case PALETTE_CRASH: return BM_CRASH_REMAP;
case PALETTE_ALL_BLACK: return BM_BLACK_REMAP;
default: return BM_COLOUR_REMAP;
}
}
/**
* Draw a sprite in a viewport.
* @param img Image number to draw
* @param pal Palette to use.
* @param x Left coordinate of image in viewport, scaled by zoom
* @param y Top coordinate of image in viewport, scaled by zoom
* @param sub If available, draw only specified part of the sprite
*/
void DrawSpriteViewport(SpriteID img, PaletteID pal, int x, int y, const SubSprite *sub)
{
SpriteID real_sprite = GB(img, 0, SPRITE_WIDTH);
if (HasBit(img, PALETTE_MODIFIER_TRANSPARENT)) {
_colour_remap_ptr = GetNonSprite(GB(pal, 0, PALETTE_WIDTH), ST_RECOLOUR) + 1;
GfxMainBlitterViewport(GetSprite(real_sprite, ST_NORMAL), x, y, BM_TRANSPARENT, sub, real_sprite);
} else if (pal != PAL_NONE) {
if (HasBit(pal, PALETTE_TEXT_RECOLOUR)) {
SetColourRemap((TextColour)GB(pal, 0, PALETTE_WIDTH));
} else {
_colour_remap_ptr = GetNonSprite(GB(pal, 0, PALETTE_WIDTH), ST_RECOLOUR) + 1;
}
GfxMainBlitterViewport(GetSprite(real_sprite, ST_NORMAL), x, y, GetBlitterMode(pal), sub, real_sprite);
} else {
GfxMainBlitterViewport(GetSprite(real_sprite, ST_NORMAL), x, y, BM_NORMAL, sub, real_sprite);
}
}
/**
* Draw a sprite, not in a viewport
* @param img Image number to draw
* @param pal Palette to use.
* @param x Left coordinate of image in pixels
* @param y Top coordinate of image in pixels
* @param sub If available, draw only specified part of the sprite
* @param zoom Zoom level of sprite
*/
void DrawSprite(SpriteID img, PaletteID pal, int x, int y, const SubSprite *sub, ZoomLevel zoom)
{
SpriteID real_sprite = GB(img, 0, SPRITE_WIDTH);
if (HasBit(img, PALETTE_MODIFIER_TRANSPARENT)) {
_colour_remap_ptr = GetNonSprite(GB(pal, 0, PALETTE_WIDTH), ST_RECOLOUR) + 1;
GfxMainBlitter(GetSprite(real_sprite, ST_NORMAL), x, y, BM_TRANSPARENT, sub, real_sprite, zoom);
} else if (pal != PAL_NONE) {
if (HasBit(pal, PALETTE_TEXT_RECOLOUR)) {
SetColourRemap((TextColour)GB(pal, 0, PALETTE_WIDTH));
} else {
_colour_remap_ptr = GetNonSprite(GB(pal, 0, PALETTE_WIDTH), ST_RECOLOUR) + 1;
}
GfxMainBlitter(GetSprite(real_sprite, ST_NORMAL), x, y, GetBlitterMode(pal), sub, real_sprite, zoom);
} else {
GfxMainBlitter(GetSprite(real_sprite, ST_NORMAL), x, y, BM_NORMAL, sub, real_sprite, zoom);
}
}
/**
* The code for setting up the blitter mode and sprite information before finally drawing the sprite.
* @param sprite The sprite to draw.
* @param x The X location to draw.
* @param y The Y location to draw.
* @param mode The settings for the blitter to pass.
* @param sub Whether to only draw a sub set of the sprite.
* @param zoom The zoom level at which to draw the sprites.
* @tparam ZOOM_BASE The factor required to get the sub sprite information into the right size.
* @tparam SCALED_XY Whether the X and Y are scaled or unscaled.
*/
template
static void GfxBlitter(const Sprite * const sprite, int x, int y, BlitterMode mode, const SubSprite * const sub, SpriteID sprite_id, ZoomLevel zoom)
{
const DrawPixelInfo *dpi = _cur_dpi;
Blitter::BlitterParams bp;
if (SCALED_XY) {
/* Scale it */
x = ScaleByZoom(x, zoom);
y = ScaleByZoom(y, zoom);
}
/* Move to the correct offset */
x += sprite->x_offs;
y += sprite->y_offs;
if (sub == nullptr) {
/* No clipping. */
bp.skip_left = 0;
bp.skip_top = 0;
bp.width = UnScaleByZoom(sprite->width, zoom);
bp.height = UnScaleByZoom(sprite->height, zoom);
} else {
/* Amount of pixels to clip from the source sprite */
int clip_left = max(0, -sprite->x_offs + sub->left * ZOOM_BASE );
int clip_top = max(0, -sprite->y_offs + sub->top * ZOOM_BASE );
int clip_right = max(0, sprite->width - (-sprite->x_offs + (sub->right + 1) * ZOOM_BASE));
int clip_bottom = max(0, sprite->height - (-sprite->y_offs + (sub->bottom + 1) * ZOOM_BASE));
if (clip_left + clip_right >= sprite->width) return;
if (clip_top + clip_bottom >= sprite->height) return;
bp.skip_left = UnScaleByZoomLower(clip_left, zoom);
bp.skip_top = UnScaleByZoomLower(clip_top, zoom);
bp.width = UnScaleByZoom(sprite->width - clip_left - clip_right, zoom);
bp.height = UnScaleByZoom(sprite->height - clip_top - clip_bottom, zoom);
x += ScaleByZoom(bp.skip_left, zoom);
y += ScaleByZoom(bp.skip_top, zoom);
}
/* Copy the main data directly from the sprite */
bp.sprite = sprite->data;
bp.sprite_width = sprite->width;
bp.sprite_height = sprite->height;
bp.top = 0;
bp.left = 0;
bp.dst = dpi->dst_ptr;
bp.pitch = dpi->pitch;
bp.remap = _colour_remap_ptr;
assert(sprite->width > 0);
assert(sprite->height > 0);
if (bp.width <= 0) return;
if (bp.height <= 0) return;
y -= SCALED_XY ? ScaleByZoom(dpi->top, zoom) : dpi->top;
int y_unscaled = UnScaleByZoom(y, zoom);
/* Check for top overflow */
if (y < 0) {
bp.height -= -y_unscaled;
if (bp.height <= 0) return;
bp.skip_top += -y_unscaled;
y = 0;
} else {
bp.top = y_unscaled;
}
/* Check for bottom overflow */
y += SCALED_XY ? ScaleByZoom(bp.height - dpi->height, zoom) : ScaleByZoom(bp.height, zoom) - dpi->height;
if (y > 0) {
bp.height -= UnScaleByZoom(y, zoom);
if (bp.height <= 0) return;
}
x -= SCALED_XY ? ScaleByZoom(dpi->left, zoom) : dpi->left;
int x_unscaled = UnScaleByZoom(x, zoom);
/* Check for left overflow */
if (x < 0) {
bp.width -= -x_unscaled;
if (bp.width <= 0) return;
bp.skip_left += -x_unscaled;
x = 0;
} else {
bp.left = x_unscaled;
}
/* Check for right overflow */
x += SCALED_XY ? ScaleByZoom(bp.width - dpi->width, zoom) : ScaleByZoom(bp.width, zoom) - dpi->width;
if (x > 0) {
bp.width -= UnScaleByZoom(x, zoom);
if (bp.width <= 0) return;
}
assert(bp.skip_left + bp.width <= UnScaleByZoom(sprite->width, zoom));
assert(bp.skip_top + bp.height <= UnScaleByZoom(sprite->height, zoom));
/* We do not want to catch the mouse. However we also use that spritenumber for unknown (text) sprites. */
if (_newgrf_debug_sprite_picker.mode == SPM_REDRAW && sprite_id != SPR_CURSOR_MOUSE) {
Blitter *blitter = BlitterFactory::GetCurrentBlitter();
void *topleft = blitter->MoveTo(bp.dst, bp.left, bp.top);
void *bottomright = blitter->MoveTo(topleft, bp.width - 1, bp.height - 1);
void *clicked = _newgrf_debug_sprite_picker.clicked_pixel;
if (topleft <= clicked && clicked <= bottomright) {
uint offset = (((size_t)clicked - (size_t)topleft) / (blitter->GetScreenDepth() / 8)) % bp.pitch;
if (offset < (uint)bp.width) {
include(_newgrf_debug_sprite_picker.sprites, sprite_id);
}
}
}
BlitterFactory::GetCurrentBlitter()->Draw(&bp, mode, zoom);
}
static void GfxMainBlitterViewport(const Sprite *sprite, int x, int y, BlitterMode mode, const SubSprite *sub, SpriteID sprite_id)
{
GfxBlitter(sprite, x, y, mode, sub, sprite_id, _cur_dpi->zoom);
}
static void GfxMainBlitter(const Sprite *sprite, int x, int y, BlitterMode mode, const SubSprite *sub, SpriteID sprite_id, ZoomLevel zoom)
{
GfxBlitter<1, true>(sprite, x, y, mode, sub, sprite_id, zoom);
}
void DoPaletteAnimations();
void GfxInitPalettes()
{
memcpy(&_cur_palette, &_palette, sizeof(_cur_palette));
DoPaletteAnimations();
}
#define EXTR(p, q) (((uint16)(palette_animation_counter * (p)) * (q)) >> 16)
#define EXTR2(p, q) (((uint16)(~palette_animation_counter * (p)) * (q)) >> 16)
void DoPaletteAnimations()
{
/* Animation counter for the palette animation. */
static int palette_animation_counter = 0;
palette_animation_counter += 8;
Blitter *blitter = BlitterFactory::GetCurrentBlitter();
const Colour *s;
const ExtraPaletteValues *ev = &_extra_palette_values;
Colour old_val[PALETTE_ANIM_SIZE];
const uint old_tc = palette_animation_counter;
uint i;
uint j;
if (blitter != nullptr && blitter->UsePaletteAnimation() == Blitter::PALETTE_ANIMATION_NONE) {
palette_animation_counter = 0;
}
Colour *palette_pos = &_cur_palette.palette[PALETTE_ANIM_START]; // Points to where animations are taking place on the palette
/* Makes a copy of the current animation palette in old_val,
* so the work on the current palette could be compared, see if there has been any changes */
memcpy(old_val, palette_pos, sizeof(old_val));
/* Fizzy Drink bubbles animation */
s = ev->fizzy_drink;
j = EXTR2(512, EPV_CYCLES_FIZZY_DRINK);
for (i = 0; i != EPV_CYCLES_FIZZY_DRINK; i++) {
*palette_pos++ = s[j];
j++;
if (j == EPV_CYCLES_FIZZY_DRINK) j = 0;
}
/* Oil refinery fire animation */
s = ev->oil_refinery;
j = EXTR2(512, EPV_CYCLES_OIL_REFINERY);
for (i = 0; i != EPV_CYCLES_OIL_REFINERY; i++) {
*palette_pos++ = s[j];
j++;
if (j == EPV_CYCLES_OIL_REFINERY) j = 0;
}
/* Radio tower blinking */
{
byte i = (palette_animation_counter >> 1) & 0x7F;
byte v;
if (i < 0x3f) {
v = 255;
} else if (i < 0x4A || i >= 0x75) {
v = 128;
} else {
v = 20;
}
palette_pos->r = v;
palette_pos->g = 0;
palette_pos->b = 0;
palette_pos++;
i ^= 0x40;
if (i < 0x3f) {
v = 255;
} else if (i < 0x4A || i >= 0x75) {
v = 128;
} else {
v = 20;
}
palette_pos->r = v;
palette_pos->g = 0;
palette_pos->b = 0;
palette_pos++;
}
/* Handle lighthouse and stadium animation */
s = ev->lighthouse;
j = EXTR(256, EPV_CYCLES_LIGHTHOUSE);
for (i = 0; i != EPV_CYCLES_LIGHTHOUSE; i++) {
*palette_pos++ = s[j];
j++;
if (j == EPV_CYCLES_LIGHTHOUSE) j = 0;
}
/* Dark blue water */
s = (_settings_game.game_creation.landscape == LT_TOYLAND) ? ev->dark_water_toyland : ev->dark_water;
j = EXTR(320, EPV_CYCLES_DARK_WATER);
for (i = 0; i != EPV_CYCLES_DARK_WATER; i++) {
*palette_pos++ = s[j];
j++;
if (j == EPV_CYCLES_DARK_WATER) j = 0;
}
/* Glittery water */
s = (_settings_game.game_creation.landscape == LT_TOYLAND) ? ev->glitter_water_toyland : ev->glitter_water;
j = EXTR(128, EPV_CYCLES_GLITTER_WATER);
for (i = 0; i != EPV_CYCLES_GLITTER_WATER / 3; i++) {
*palette_pos++ = s[j];
j += 3;
if (j >= EPV_CYCLES_GLITTER_WATER) j -= EPV_CYCLES_GLITTER_WATER;
}
if (blitter != nullptr && blitter->UsePaletteAnimation() == Blitter::PALETTE_ANIMATION_NONE) {
palette_animation_counter = old_tc;
} else {
if (memcmp(old_val, &_cur_palette.palette[PALETTE_ANIM_START], sizeof(old_val)) != 0 && _cur_palette.count_dirty == 0) {
/* Did we changed anything on the palette? Seems so. Mark it as dirty */
_cur_palette.first_dirty = PALETTE_ANIM_START;
_cur_palette.count_dirty = PALETTE_ANIM_SIZE;
}
}
}
/**
* Determine a contrasty text colour for a coloured background.
* @param background Background colour.
* @param threshold Background colour brightness threshold below which the background is considered dark and TC_WHITE is returned, range: 0 - 255, default 128.
* @return TC_BLACK or TC_WHITE depending on what gives a better contrast.
*/
TextColour GetContrastColour(uint8 background, uint8 threshold)
{
Colour c = _cur_palette.palette[background];
/* Compute brightness according to http://www.w3.org/TR/AERT#color-contrast.
* The following formula computes 1000 * brightness^2, with brightness being in range 0 to 255. */
uint sq1000_brightness = c.r * c.r * 299 + c.g * c.g * 587 + c.b * c.b * 114;
/* Compare with threshold brightness which defaults to 128 (50%) */
return sq1000_brightness < ((uint) threshold) * ((uint) threshold) * 1000 ? TC_WHITE : TC_BLACK;
}
/**
* Initialize _stringwidth_table cache
* @param monospace Whether to load the monospace cache or the normal fonts.
*/
void LoadStringWidthTable(bool monospace)
{
ClearFontCache();
for (FontSize fs = monospace ? FS_MONO : FS_BEGIN; fs < (monospace ? FS_END : FS_MONO); fs++) {
for (uint i = 0; i != 224; i++) {
_stringwidth_table[fs][i] = GetGlyphWidth(fs, i + 32);
}
}
ReInitAllWindows();
}
/**
* Return width of character glyph.
* @param size Font of the character
* @param key Character code glyph
* @return Width of the character glyph
*/
byte GetCharacterWidth(FontSize size, WChar key)
{
/* Use _stringwidth_table cache if possible */
if (key >= 32 && key < 256) return _stringwidth_table[size][key - 32];
return GetGlyphWidth(size, key);
}
/**
* Return the maximum width of single digit.
* @param size Font of the digit
* @return Width of the digit.
*/
byte GetDigitWidth(FontSize size)
{
byte width = 0;
for (char c = '0'; c <= '9'; c++) {
width = max(GetCharacterWidth(size, c), width);
}
return width;
}
/**
* Determine the broadest digits for guessing the maximum width of a n-digit number.
* @param[out] front Broadest digit, which is not 0. (Use this digit as first digit for numbers with more than one digit.)
* @param[out] next Broadest digit, including 0. (Use this digit for all digits, except the first one; or for numbers with only one digit.)
* @param size Font of the digit
*/
void GetBroadestDigit(uint *front, uint *next, FontSize size)
{
int width = -1;
for (char c = '9'; c >= '0'; c--) {
int w = GetCharacterWidth(size, c);
if (w > width) {
width = w;
*next = c - '0';
if (c != '0') *front = c - '0';
}
}
}
void ScreenSizeChanged()
{
_dirty_bytes_per_line = CeilDiv(_screen.width, DIRTY_BLOCK_WIDTH);
_dirty_blocks = ReallocT(_dirty_blocks, _dirty_bytes_per_line * CeilDiv(_screen.height, DIRTY_BLOCK_HEIGHT));
/* check the dirty rect */
if (_invalid_rect.right >= _screen.width) _invalid_rect.right = _screen.width;
if (_invalid_rect.bottom >= _screen.height) _invalid_rect.bottom = _screen.height;
/* screen size changed and the old bitmap is invalid now, so we don't want to undraw it */
_cursor.visible = false;
}
void UndrawMouseCursor()
{
/* Don't undraw the mouse cursor if the screen is not ready */
if (_screen.dst_ptr == nullptr) return;
if (_cursor.visible) {
Blitter *blitter = BlitterFactory::GetCurrentBlitter();
_cursor.visible = false;
blitter->CopyFromBuffer(blitter->MoveTo(_screen.dst_ptr, _cursor.draw_pos.x, _cursor.draw_pos.y), _cursor_backup.GetBuffer(), _cursor.draw_size.x, _cursor.draw_size.y);
VideoDriver::GetInstance()->MakeDirty(_cursor.draw_pos.x, _cursor.draw_pos.y, _cursor.draw_size.x, _cursor.draw_size.y);
}
}
void DrawMouseCursor()
{
/* Don't draw the mouse cursor if the screen is not ready */
if (_screen.dst_ptr == nullptr) return;
Blitter *blitter = BlitterFactory::GetCurrentBlitter();
/* Redraw mouse cursor but only when it's inside the window */
if (!_cursor.in_window) return;
/* Don't draw the mouse cursor if it's already drawn */
if (_cursor.visible) {
if (!_cursor.dirty) return;
UndrawMouseCursor();
}
/* Determine visible area */
int left = _cursor.pos.x + _cursor.total_offs.x;
int width = _cursor.total_size.x;
if (left < 0) {
width += left;
left = 0;
}
if (left + width > _screen.width) {
width = _screen.width - left;
}
if (width <= 0) return;
int top = _cursor.pos.y + _cursor.total_offs.y;
int height = _cursor.total_size.y;
if (top < 0) {
height += top;
top = 0;
}
if (top + height > _screen.height) {
height = _screen.height - top;
}
if (height <= 0) return;
_cursor.draw_pos.x = left;
_cursor.draw_pos.y = top;
_cursor.draw_size.x = width;
_cursor.draw_size.y = height;
uint8 *buffer = _cursor_backup.Allocate(blitter->BufferSize(_cursor.draw_size.x, _cursor.draw_size.y));
/* Make backup of stuff below cursor */
blitter->CopyToBuffer(blitter->MoveTo(_screen.dst_ptr, _cursor.draw_pos.x, _cursor.draw_pos.y), buffer, _cursor.draw_size.x, _cursor.draw_size.y);
/* Draw cursor on screen */
_cur_dpi = &_screen;
for (uint i = 0; i < _cursor.sprite_count; ++i) {
DrawSprite(_cursor.sprite_seq[i].sprite, _cursor.sprite_seq[i].pal, _cursor.pos.x + _cursor.sprite_pos[i].x, _cursor.pos.y + _cursor.sprite_pos[i].y);
}
VideoDriver::GetInstance()->MakeDirty(_cursor.draw_pos.x, _cursor.draw_pos.y, _cursor.draw_size.x, _cursor.draw_size.y);
_cursor.visible = true;
_cursor.dirty = false;
}
/**
* Repaints a specific rectangle of the screen.
*
* @param left,top,right,bottom The area of the screen that needs repainting
* @pre The rectangle should have been previously marked dirty with \c AddDirtyBlock.
* @see AddDirtyBlock
* @see DrawDirtyBlocks
* @ingroup dirty
*
*/
void RedrawScreenRect(int left, int top, int right, int bottom)
{
assert(right <= _screen.width && bottom <= _screen.height);
if (_cursor.visible) {
if (right > _cursor.draw_pos.x &&
left < _cursor.draw_pos.x + _cursor.draw_size.x &&
bottom > _cursor.draw_pos.y &&
top < _cursor.draw_pos.y + _cursor.draw_size.y) {
UndrawMouseCursor();
}
}
if (_networking) NetworkUndrawChatMessage();
DrawOverlappedWindowForAll(left, top, right, bottom);
VideoDriver::GetInstance()->MakeDirty(left, top, right - left, bottom - top);
}
/**
* Repaints the rectangle blocks which are marked as 'dirty'.
*
* @see AddDirtyBlock
*
* @ingroup dirty
*/
void DrawDirtyBlocks()
{
byte *b = _dirty_blocks;
const int w = Align(_screen.width, DIRTY_BLOCK_WIDTH);
const int h = Align(_screen.height, DIRTY_BLOCK_HEIGHT);
int x;
int y;
if (HasModalProgress()) {
/* We are generating the world, so release our rights to the map and
* painting while we are waiting a bit. */
_modal_progress_paint_mutex.unlock();
_modal_progress_work_mutex.unlock();
/* Wait a while and update _realtime_tick so we are given the rights */
if (!IsFirstModalProgressLoop()) CSleep(MODAL_PROGRESS_REDRAW_TIMEOUT);
_realtime_tick += MODAL_PROGRESS_REDRAW_TIMEOUT;
/* Modal progress thread may need blitter access while we are waiting for it. */
VideoDriver::GetInstance()->ReleaseBlitterLock();
_modal_progress_paint_mutex.lock();
VideoDriver::GetInstance()->AcquireBlitterLock();
_modal_progress_work_mutex.lock();
/* When we ended with the modal progress, do not draw the blocks.
* Simply let the next run do so, otherwise we would be loading
* the new state (and possibly change the blitter) when we hold
* the drawing lock, which we must not do. */
if (_switch_mode != SM_NONE && !HasModalProgress()) return;
}
y = 0;
do {
x = 0;
do {
if (*b != 0) {
int left;
int top;
int right = x + DIRTY_BLOCK_WIDTH;
int bottom = y;
byte *p = b;
int h2;
/* First try coalescing downwards */
do {
*p = 0;
p += _dirty_bytes_per_line;
bottom += DIRTY_BLOCK_HEIGHT;
} while (bottom != h && *p != 0);
/* Try coalescing to the right too. */
h2 = (bottom - y) / DIRTY_BLOCK_HEIGHT;
assert(h2 > 0);
p = b;
while (right != w) {
byte *p2 = ++p;
int h = h2;
/* Check if a full line of dirty flags is set. */
do {
if (!*p2) goto no_more_coalesc;
p2 += _dirty_bytes_per_line;
} while (--h != 0);
/* Wohoo, can combine it one step to the right!
* Do that, and clear the bits. */
right += DIRTY_BLOCK_WIDTH;
h = h2;
p2 = p;
do {
*p2 = 0;
p2 += _dirty_bytes_per_line;
} while (--h != 0);
}
no_more_coalesc:
left = x;
top = y;
if (left < _invalid_rect.left ) left = _invalid_rect.left;
if (top < _invalid_rect.top ) top = _invalid_rect.top;
if (right > _invalid_rect.right ) right = _invalid_rect.right;
if (bottom > _invalid_rect.bottom) bottom = _invalid_rect.bottom;
if (left < right && top < bottom) {
RedrawScreenRect(left, top, right, bottom);
}
}
} while (b++, (x += DIRTY_BLOCK_WIDTH) != w);
} while (b += -(int)(w / DIRTY_BLOCK_WIDTH) + _dirty_bytes_per_line, (y += DIRTY_BLOCK_HEIGHT) != h);
++_dirty_block_colour;
_invalid_rect.left = w;
_invalid_rect.top = h;
_invalid_rect.right = 0;
_invalid_rect.bottom = 0;
}
/**
* Extend the internal _invalid_rect rectangle to contain the rectangle
* defined by the given parameters. Note the point (0,0) is top left.
*
* @param left The left edge of the rectangle
* @param top The top edge of the rectangle
* @param right The right edge of the rectangle
* @param bottom The bottom edge of the rectangle
* @see DrawDirtyBlocks
* @ingroup dirty
*
*/
void AddDirtyBlock(int left, int top, int right, int bottom)
{
byte *b;
int width;
int height;
if (left < 0) left = 0;
if (top < 0) top = 0;
if (right > _screen.width) right = _screen.width;
if (bottom > _screen.height) bottom = _screen.height;
if (left >= right || top >= bottom) return;
if (left < _invalid_rect.left ) _invalid_rect.left = left;
if (top < _invalid_rect.top ) _invalid_rect.top = top;
if (right > _invalid_rect.right ) _invalid_rect.right = right;
if (bottom > _invalid_rect.bottom) _invalid_rect.bottom = bottom;
left /= DIRTY_BLOCK_WIDTH;
top /= DIRTY_BLOCK_HEIGHT;
b = _dirty_blocks + top * _dirty_bytes_per_line + left;
width = ((right - 1) / DIRTY_BLOCK_WIDTH) - left + 1;
height = ((bottom - 1) / DIRTY_BLOCK_HEIGHT) - top + 1;
assert(width > 0 && height > 0);
do {
int i = width;
do b[--i] = 0xFF; while (i != 0);
b += _dirty_bytes_per_line;
} while (--height != 0);
}
/**
* This function mark the whole screen as dirty. This results in repainting
* the whole screen. Use this with care as this function will break the
* idea about marking only parts of the screen as 'dirty'.
* @ingroup dirty
*/
void MarkWholeScreenDirty()
{
AddDirtyBlock(0, 0, _screen.width, _screen.height);
}
/**
* Set up a clipping area for only drawing into a certain area. To do this,
* Fill a DrawPixelInfo object with the supplied relative rectangle, backup
* the original (calling) _cur_dpi and assign the just returned DrawPixelInfo
* _cur_dpi. When you are done, give restore _cur_dpi's original value
* @param *n the DrawPixelInfo that will be the clipping rectangle box allowed
* for drawing
* @param left,top,width,height the relative coordinates of the clipping
* rectangle relative to the current _cur_dpi. This will most likely be the
* offset from the calling window coordinates
* @return return false if the requested rectangle is not possible with the
* current dpi pointer. Only continue of the return value is true, or you'll
* get some nasty results
*/
bool FillDrawPixelInfo(DrawPixelInfo *n, int left, int top, int width, int height)
{
Blitter *blitter = BlitterFactory::GetCurrentBlitter();
const DrawPixelInfo *o = _cur_dpi;
n->zoom = ZOOM_LVL_NORMAL;
assert(width > 0);
assert(height > 0);
if ((left -= o->left) < 0) {
width += left;
if (width <= 0) return false;
n->left = -left;
left = 0;
} else {
n->left = 0;
}
if (width > o->width - left) {
width = o->width - left;
if (width <= 0) return false;
}
n->width = width;
if ((top -= o->top) < 0) {
height += top;
if (height <= 0) return false;
n->top = -top;
top = 0;
} else {
n->top = 0;
}
n->dst_ptr = blitter->MoveTo(o->dst_ptr, left, top);
n->pitch = o->pitch;
if (height > o->height - top) {
height = o->height - top;
if (height <= 0) return false;
}
n->height = height;
return true;
}
/**
* Update cursor dimension.
* Called when changing cursor sprite resp. reloading grfs.
*/
void UpdateCursorSize()
{
/* Ignore setting any cursor before the sprites are loaded. */
if (GetMaxSpriteID() == 0) return;
static_assert(lengthof(_cursor.sprite_seq) == lengthof(_cursor.sprite_pos));
assert(_cursor.sprite_count <= lengthof(_cursor.sprite_seq));
for (uint i = 0; i < _cursor.sprite_count; ++i) {
const Sprite *p = GetSprite(GB(_cursor.sprite_seq[i].sprite, 0, SPRITE_WIDTH), ST_NORMAL);
Point offs, size;
offs.x = UnScaleGUI(p->x_offs) + _cursor.sprite_pos[i].x;
offs.y = UnScaleGUI(p->y_offs) + _cursor.sprite_pos[i].y;
size.x = UnScaleGUI(p->width);
size.y = UnScaleGUI(p->height);
if (i == 0) {
_cursor.total_offs = offs;
_cursor.total_size = size;
} else {
int right = max(_cursor.total_offs.x + _cursor.total_size.x, offs.x + size.x);
int bottom = max(_cursor.total_offs.y + _cursor.total_size.y, offs.y + size.y);
if (offs.x < _cursor.total_offs.x) _cursor.total_offs.x = offs.x;
if (offs.y < _cursor.total_offs.y) _cursor.total_offs.y = offs.y;
_cursor.total_size.x = right - _cursor.total_offs.x;
_cursor.total_size.y = bottom - _cursor.total_offs.y;
}
}
_cursor.dirty = true;
}
/**
* Switch cursor to different sprite.
* @param cursor Sprite to draw for the cursor.
* @param pal Palette to use for recolouring.
*/
static void SetCursorSprite(CursorID cursor, PaletteID pal)
{
if (_cursor.sprite_count == 1 && _cursor.sprite_seq[0].sprite == cursor && _cursor.sprite_seq[0].pal == pal) return;
_cursor.sprite_count = 1;
_cursor.sprite_seq[0].sprite = cursor;
_cursor.sprite_seq[0].pal = pal;
_cursor.sprite_pos[0].x = 0;
_cursor.sprite_pos[0].y = 0;
UpdateCursorSize();
}
static void SwitchAnimatedCursor()
{
const AnimCursor *cur = _cursor.animate_cur;
if (cur == nullptr || cur->sprite == AnimCursor::LAST) cur = _cursor.animate_list;
SetCursorSprite(cur->sprite, _cursor.sprite_seq[0].pal);
_cursor.animate_timeout = cur->display_time;
_cursor.animate_cur = cur + 1;
}
void CursorTick()
{
if (_cursor.animate_timeout != 0 && --_cursor.animate_timeout == 0) {
SwitchAnimatedCursor();
}
}
/**
* Set or unset the ZZZ cursor.
* @param busy Whether to show the ZZZ cursor.
*/
void SetMouseCursorBusy(bool busy)
{
if (busy) {
if (_cursor.sprite_seq[0].sprite == SPR_CURSOR_MOUSE) SetMouseCursor(SPR_CURSOR_ZZZ, PAL_NONE);
} else {
if (_cursor.sprite_seq[0].sprite == SPR_CURSOR_ZZZ) SetMouseCursor(SPR_CURSOR_MOUSE, PAL_NONE);
}
}
/**
* Assign a single non-animated sprite to the cursor.
* @param sprite Sprite to draw for the cursor.
* @param pal Palette to use for recolouring.
* @see SetAnimatedMouseCursor
*/
void SetMouseCursor(CursorID sprite, PaletteID pal)
{
/* Turn off animation */
_cursor.animate_timeout = 0;
/* Set cursor */
SetCursorSprite(sprite, pal);
}
/**
* Assign an animation to the cursor.
* @param table Array of animation states.
* @see SetMouseCursor
*/
void SetAnimatedMouseCursor(const AnimCursor *table)
{
_cursor.animate_list = table;
_cursor.animate_cur = nullptr;
_cursor.sprite_seq[0].pal = PAL_NONE;
SwitchAnimatedCursor();
}
/**
* Update cursor position on mouse movement for relative modes.
* @param delta_x How much change in the X position.
* @param delta_y How much change in the Y position.
*/
void CursorVars::UpdateCursorPositionRelative(int delta_x, int delta_y)
{
if (this->fix_at) {
this->delta.x = delta_x;
this->delta.y = delta_y;
} else {
int last_position_x = this->pos.x;
int last_position_y = this->pos.y;
this->pos.x = Clamp(this->pos.x + delta_x, 0, _cur_resolution.width - 1);
this->pos.y = Clamp(this->pos.y + delta_y, 0, _cur_resolution.height - 1);
this->delta.x = last_position_x - this->pos.x;
this->delta.y = last_position_y - this->pos.y;
this->dirty = true;
}
}
/**
* Update cursor position on mouse movement.
* @param x New X position.
* @param y New Y position.
* @param queued_warp True, if the OS queues mouse warps after pending mouse movement events.
* False, if the warp applies instantaneous.
* @return true, if the OS cursor position should be warped back to this->pos.
*/
bool CursorVars::UpdateCursorPosition(int x, int y, bool queued_warp)
{
/* Detecting relative mouse movement is somewhat tricky.
* - There may be multiple mouse move events in the video driver queue (esp. when OpenTTD lags a bit).
* - When we request warping the mouse position (return true), a mouse move event is appended at the end of the queue.
*
* So, when this->fix_at is active, we use the following strategy:
* - The first movement triggers the warp to reset the mouse position.
* - Subsequent events have to compute movement relative to the previous event.
* - The relative movement is finished, when we receive the event matching the warp.
*/
if (x == this->pos.x && y == this->pos.y) {
/* Warp finished. */
this->queued_warp = false;
}
this->delta.x = x - (this->queued_warp ? this->last_position.x : this->pos.x);
this->delta.y = y - (this->queued_warp ? this->last_position.y : this->pos.y);
this->last_position.x = x;
this->last_position.y = y;
bool need_warp = false;
if (this->fix_at) {
if (this->delta.x != 0 || this->delta.y != 0) {
/* Trigger warp.
* Note: We also trigger warping again, if there is already a pending warp.
* This makes it more tolerant about the OS or other software in between
* botchering the warp. */
this->queued_warp = queued_warp;
need_warp = true;
}
} else if (this->pos.x != x || this->pos.y != y) {
this->queued_warp = false; // Cancel warping, we are no longer confining the position.
this->dirty = true;
this->pos.x = x;
this->pos.y = y;
}
return need_warp;
}
bool ChangeResInGame(int width, int height)
{
return (_screen.width == width && _screen.height == height) || VideoDriver::GetInstance()->ChangeResolution(width, height);
}
bool ToggleFullScreen(bool fs)
{
bool result = VideoDriver::GetInstance()->ToggleFullscreen(fs);
if (_fullscreen != fs && _resolutions.empty()) {
DEBUG(driver, 0, "Could not find a suitable fullscreen resolution");
}
return result;
}
void SortResolutions()
{
std::sort(_resolutions.begin(), _resolutions.end());
}