OpenTTD-patches/src/viewport.cpp

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/*
* 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 <http://www.gnu.org/licenses/>.
*/
/**
* @file viewport.cpp Handling of all viewports.
*
* \verbatim
* The in-game coordinate system looks like this *
* *
* ^ Z *
* | *
* | *
* | *
* | *
* / \ *
* / \ *
* / \ *
* / \ *
* X < > Y *
* \endverbatim
*/
/**
* @defgroup vp_column_row Rows and columns in the viewport
*
* Columns are vertical sections of the viewport that are half a tile wide.
* The origin, i.e. column 0, is through the northern and southern most tile.
* This means that the column of e.g. Tile(0, 0) and Tile(100, 100) are in
* column number 0. The negative columns are towards the left of the screen,
* or towards the west, whereas the positive ones are towards respectively
* the right and east.
* With half a tile wide is meant that the next column of tiles directly west
* or east of the centre line are respectively column -1 and 1. Their tile
* centers are only half a tile from the center of their adjoining tile when
* looking only at the X-coordinate.
*
* \verbatim
* *
* ╲ *
* 0 *
* ╲ *
* -1 1 *
* ╲ *
* -2 0 2 *
* ╲ *
* -1 1 *
* ╲ *
* 0 *
* ╲ *
* *
* \endverbatim
*
*
* Rows are horizontal sections of the viewport, also half a tile wide.
* This time the northern most tile on the map defines 0 and
* everything south of that has a positive number.
*/
#include "stdafx.h"
#include "clear_map.h"
#include "tree_map.h"
#include "industry.h"
#include "smallmap_gui.h"
#include "smallmap_colours.h"
#include "table/tree_land.h"
#include "blitter/32bpp_base.hpp"
#include "core/math_func.hpp"
#include "core/smallvec_type.hpp"
#include "landscape.h"
#include "viewport_func.h"
#include "station_base.h"
#include "waypoint_base.h"
#include "town.h"
#include "signs_base.h"
#include "signs_func.h"
#include "plans_base.h"
#include "plans_func.h"
#include "vehicle_base.h"
#include "vehicle_gui.h"
#include "blitter/factory.hpp"
#include "strings_func.h"
#include "zoom_func.h"
#include "vehicle_func.h"
#include "company_func.h"
#include "waypoint_func.h"
#include "window_func.h"
#include "tilehighlight_func.h"
#include "zoning.h"
#include "window_gui.h"
#include "linkgraph/linkgraph_gui.h"
#include "viewport_kdtree.h"
#include "town_kdtree.h"
#include "viewport_sprite_sorter.h"
#include "bridge_map.h"
#include "company_base.h"
#include "command_func.h"
#include "network/network_func.h"
#include "framerate_type.h"
#include "depot_base.h"
#include "tunnelbridge_map.h"
#include "gui.h"
#include "core/container_func.hpp"
#include "tunnelbridge_map.h"
#include "video/video_driver.hpp"
#include "scope_info.h"
#include "scope.h"
#include "blitter/32bpp_base.hpp"
#include <map>
#include <vector>
#include <math.h>
#include <algorithm>
#include <tuple>
#include "table/strings.h"
#include "table/string_colours.h"
#include "safeguards.h"
Point _tile_fract_coords;
ViewportSignKdtree _viewport_sign_kdtree(&Kdtree_ViewportSignXYFunc);
bool _viewport_sign_kdtree_valid = false;
static int _viewport_sign_maxwidth = 0;
//static const int MAX_TILE_EXTENT_LEFT = ZOOM_LVL_BASE * TILE_PIXELS; ///< Maximum left extent of tile relative to north corner.
//static const int MAX_TILE_EXTENT_RIGHT = ZOOM_LVL_BASE * TILE_PIXELS; ///< Maximum right extent of tile relative to north corner.
static const int MAX_TILE_EXTENT_TOP = ZOOM_LVL_BASE * MAX_BUILDING_PIXELS; ///< Maximum top extent of tile relative to north corner (not considering bridges).
static const int MAX_TILE_EXTENT_BOTTOM = ZOOM_LVL_BASE * (TILE_PIXELS + 2 * TILE_HEIGHT); ///< Maximum bottom extent of tile relative to north corner (worst case: #SLOPE_STEEP_N).
struct StringSpriteToDraw {
StringID string;
Colours colour;
int32 x;
int32 y;
uint64 params[2];
uint16 width;
};
struct TileSpriteToDraw {
SpriteID image;
PaletteID pal;
const SubSprite *sub; ///< only draw a rectangular part of the sprite
int32 x; ///< screen X coordinate of sprite
int32 y; ///< screen Y coordinate of sprite
};
struct ChildScreenSpriteToDraw {
SpriteID image;
PaletteID pal;
const SubSprite *sub; ///< only draw a rectangular part of the sprite
int32 x;
int32 y;
int next; ///< next child to draw (-1 at the end)
bool relative;
};
/**
* Mode of "sprite combining"
* @see StartSpriteCombine
*/
enum SpriteCombineMode {
SPRITE_COMBINE_NONE, ///< Every #AddSortableSpriteToDraw start its own bounding box
SPRITE_COMBINE_PENDING, ///< %Sprite combining will start with the next unclipped sprite.
SPRITE_COMBINE_ACTIVE, ///< %Sprite combining is active. #AddSortableSpriteToDraw outputs child sprites.
};
typedef std::vector<TileSpriteToDraw> TileSpriteToDrawVector;
typedef std::vector<StringSpriteToDraw> StringSpriteToDrawVector;
typedef std::vector<ParentSpriteToDraw> ParentSpriteToDrawVector;
typedef std::vector<ChildScreenSpriteToDraw> ChildScreenSpriteToDrawVector;
typedef std::vector<std::pair<int, OrderType> > RankOrderTypeList;
typedef std::map<TileIndex, RankOrderTypeList> RouteStepsMap;
const uint max_rank_order_type_count = 10;
enum RailSnapMode {
RSM_NO_SNAP,
RSM_SNAP_TO_TILE,
RSM_SNAP_TO_RAIL,
};
/**
* Snapping point for a track.
*
* Point where a track (rail/road/other) can be snapped to while selecting tracks with polyline
* tool (HT_POLY). Besides of x/y coordinates expressed in tile "units" it contains a set of
* allowed line directions.
*/
struct LineSnapPoint : Point {
uint8 dirs; ///< Allowed line directions, set of #Direction bits.
};
typedef std::vector<LineSnapPoint> LineSnapPoints; ///< Set of snapping points
/** Coordinates of a polyline track made of 2 connected line segments. */
struct PolylineInfo {
Point start; ///< The point where the first segment starts (as given in LineSnapPoint).
Direction first_dir; ///< Direction of the first line segment.
uint first_len; ///< size of the first segment - number of track pieces.
Direction second_dir; ///< Direction of the second line segment.
uint second_len; ///< size of the second segment - number of track pieces.
};
struct TunnelToMap {
TunnelBridgeToMap tb;
int y_intercept;
uint8 tunnel_z;
};
struct TunnelToMapStorage {
std::vector<TunnelToMap> tunnels;
};
struct BridgeSetXComparator {
bool operator() (const TileIndex a, const TileIndex b) const
{
return std::make_tuple(TileX(a), TileY(a)) < std::make_tuple(TileX(b), TileY(b));
}
};
struct BridgeSetYComparator {
bool operator() (const TileIndex a, const TileIndex b) const
{
return a < b;
}
};
/** Data structure storing rendering information */
struct ViewportDrawer {
DrawPixelInfo dpi;
int offset_x;
int offset_y;
StringSpriteToDrawVector string_sprites_to_draw;
TileSpriteToDrawVector tile_sprites_to_draw;
ParentSpriteToDrawVector parent_sprites_to_draw;
ParentSpriteToSortVector parent_sprites_to_sort; ///< Parent sprite pointer array used for sorting
ChildScreenSpriteToDrawVector child_screen_sprites_to_draw;
TunnelToMapStorage tunnel_to_map_x;
TunnelToMapStorage tunnel_to_map_y;
btree::btree_map<TileIndex, TileIndex, BridgeSetXComparator> bridge_to_map_x;
btree::btree_map<TileIndex, TileIndex, BridgeSetYComparator> bridge_to_map_y;
int *last_child;
SpriteCombineMode combine_sprites; ///< Current mode of "sprite combining". @see StartSpriteCombine
uint combine_psd_index;
int combine_left;
int combine_right;
int combine_top;
int combine_bottom;
int foundation[FOUNDATION_PART_END]; ///< Foundation sprites (index into parent_sprites_to_draw).
FoundationPart foundation_part; ///< Currently active foundation for ground sprite drawing.
int *last_foundation_child[FOUNDATION_PART_END]; ///< Tail of ChildSprite list of the foundations. (index into child_screen_sprites_to_draw)
Point foundation_offset[FOUNDATION_PART_END]; ///< Pixel offset for ground sprites on the foundations.
};
static void MarkRouteStepDirty(RouteStepsMap::const_iterator cit);
static void MarkRouteStepDirty(const TileIndex tile, uint order_nr);
static void HideMeasurementTooltips();
static DrawPixelInfo _dpi_for_text;
static ViewportDrawer _vd;
static std::vector<Viewport *> _viewport_window_cache;
static std::vector<Rect> _viewport_coverage_rects;
std::vector<Rect> _viewport_vehicle_normal_redraw_rects;
std::vector<Rect> _viewport_vehicle_map_redraw_rects;
RouteStepsMap _vp_route_steps;
RouteStepsMap _vp_route_steps_last_mark_dirty;
uint _vp_route_step_width = 0;
uint _vp_route_step_height_top = 0;
uint _vp_route_step_height_middle = 0;
uint _vp_route_step_height_bottom = 0;
SubSprite _vp_route_step_subsprite;
struct DrawnPathRouteTileLine {
TileIndex from_tile;
TileIndex to_tile;
bool order_match;
bool operator==(const DrawnPathRouteTileLine &other) const
{
return std::tie(this->from_tile, this->to_tile, this->order_match) == std::tie(other.from_tile, other.to_tile, other.order_match);
}
bool operator!=(const DrawnPathRouteTileLine &other) const
{
return !(*this == other);
}
bool operator<(const DrawnPathRouteTileLine &other) const
{
return std::tie(this->from_tile, this->to_tile, this->order_match) < std::tie(other.from_tile, other.to_tile, other.order_match);
}
};
std::vector<DrawnPathRouteTileLine> _vp_route_paths;
std::vector<DrawnPathRouteTileLine> _vp_route_paths_last_mark_dirty;
static void MarkRoutePathsDirty(const std::vector<DrawnPathRouteTileLine> &lines);
TileHighlightData _thd;
static TileInfo *_cur_ti;
bool _draw_bounding_boxes = false;
bool _draw_dirty_blocks = false;
uint _dirty_block_colour = 0;
static VpSpriteSorter _vp_sprite_sorter = nullptr;
const byte *_pal2trsp_remap_ptr = nullptr;
static RailSnapMode _rail_snap_mode = RSM_NO_SNAP; ///< Type of rail track snapping (polyline tool).
static LineSnapPoints _tile_snap_points; ///< Tile to which a rail track will be snapped to (polyline tool).
static LineSnapPoints _rail_snap_points; ///< Set of points where a rail track will be snapped to (polyline tool).
static LineSnapPoint _current_snap_lock; ///< Start point and direction at which selected track is locked on currently (while dragging in polyline mode).
static RailSnapMode GetRailSnapMode();
static void SetRailSnapMode(RailSnapMode mode);
static TileIndex GetRailSnapTile();
static void SetRailSnapTile(TileIndex tile);
enum ViewportDebugFlags {
VDF_DIRTY_BLOCK_PER_DRAW,
VDF_DIRTY_WHOLE_VIEWPORT,
VDF_DIRTY_BLOCK_PER_SPLIT,
VDF_DISABLE_DRAW_SPLIT,
VDF_SHOW_NO_LANDSCAPE_MAP_DRAW,
VDF_DISABLE_LANDSCAPE_CACHE,
};
uint32 _viewport_debug_flags;
static Point MapXYZToViewport(const Viewport *vp, int x, int y, int z)
{
Point p = RemapCoords(x, y, z);
p.x -= vp->virtual_width / 2;
p.y -= vp->virtual_height / 2;
return p;
}
static void FillViewportCoverageRect()
{
_viewport_coverage_rects.resize(_viewport_window_cache.size());
_viewport_vehicle_normal_redraw_rects.clear();
_viewport_vehicle_map_redraw_rects.clear();
for (uint i = 0; i < _viewport_window_cache.size(); i++) {
const Viewport *vp = _viewport_window_cache[i];
Rect &r = _viewport_coverage_rects[i];
r.left = vp->virtual_left;
r.top = vp->virtual_top;
r.right = vp->virtual_left + vp->virtual_width + (1 << vp->zoom) - 1;
r.bottom = vp->virtual_top + vp->virtual_height + (1 << vp->zoom) - 1;
if (vp->zoom >= ZOOM_LVL_DRAW_MAP) {
_viewport_vehicle_map_redraw_rects.push_back(r);
} else {
_viewport_vehicle_normal_redraw_rects.push_back({
r.left - (MAX_VEHICLE_PIXEL_X * ZOOM_LVL_BASE),
r.top - (MAX_VEHICLE_PIXEL_Y * ZOOM_LVL_BASE),
r.right + (MAX_VEHICLE_PIXEL_X * ZOOM_LVL_BASE),
r.bottom + (MAX_VEHICLE_PIXEL_Y * ZOOM_LVL_BASE),
});
}
}
}
void ClearViewportLandPixelCache(Viewport *vp)
{
vp->land_pixel_cache.assign(vp->land_pixel_cache.size(), 0xD7);
}
void ClearViewportCache(Viewport *vp)
{
if (vp->zoom >= ZOOM_LVL_DRAW_MAP) {
memset(vp->map_draw_vehicles_cache.done_hash_bits, 0, sizeof(vp->map_draw_vehicles_cache.done_hash_bits));
vp->map_draw_vehicles_cache.vehicle_pixels.assign(vp->map_draw_vehicles_cache.vehicle_pixels.size(), false);
}
}
void ClearViewportCaches()
{
for (Viewport *vp : _viewport_window_cache) {
ClearViewportCache(vp);
}
if (unlikely(HasBit(_viewport_debug_flags, VDF_DISABLE_LANDSCAPE_CACHE))) {
for (Viewport *vp : _viewport_window_cache) {
ClearViewportLandPixelCache(vp);
}
}
}
void DeleteWindowViewport(Window *w)
{
if (w->viewport == nullptr) return;
container_unordered_remove(_viewport_window_cache, w->viewport);
delete w->viewport->overlay;
delete w->viewport;
w->viewport = nullptr;
FillViewportCoverageRect();
}
/**
* Initialize viewport of the window for use.
* @param w Window to use/display the viewport in
* @param x Offset of left edge of viewport with respect to left edge window \a w
* @param y Offset of top edge of viewport with respect to top edge window \a w
* @param width Width of the viewport
* @param height Height of the viewport
* @param follow_flags Flags controlling the viewport.
* - If bit 31 is set, the lower 20 bits are the vehicle that the viewport should follow.
* - If bit 31 is clear, it is a #TileIndex.
* @param zoom Zoomlevel to display
*/
void InitializeWindowViewport(Window *w, int x, int y,
int width, int height, uint32 follow_flags, ZoomLevel zoom)
{
assert(w->viewport == nullptr);
ViewportData *vp = new ViewportData();
vp->overlay = nullptr;
vp->left = x + w->left;
vp->top = y + w->top;
vp->width = width;
vp->height = height;
vp->zoom = static_cast<ZoomLevel>(Clamp(zoom, _settings_client.gui.zoom_min, _settings_client.gui.zoom_max));
vp->virtual_left = 0;
vp->virtual_top = 0;
vp->virtual_width = ScaleByZoom(width, vp->zoom);
vp->virtual_height = ScaleByZoom(height, vp->zoom);
vp->map_type = VPMT_BEGIN;
UpdateViewportSizeZoom(vp);
Point pt;
if (follow_flags & 0x80000000) {
const Vehicle *veh;
vp->follow_vehicle = (VehicleID)(follow_flags & 0xFFFFF);
veh = Vehicle::Get(vp->follow_vehicle);
pt = MapXYZToViewport(vp, veh->x_pos, veh->y_pos, veh->z_pos);
MarkAllRoutePathsDirty(veh);
MarkAllRouteStepsDirty(veh);
} else {
uint x = TileX(follow_flags) * TILE_SIZE;
uint y = TileY(follow_flags) * TILE_SIZE;
vp->follow_vehicle = INVALID_VEHICLE;
pt = MapXYZToViewport(vp, x, y, GetSlopePixelZ(x, y));
}
vp->scrollpos_x = pt.x;
vp->scrollpos_y = pt.y;
vp->dest_scrollpos_x = pt.x;
vp->dest_scrollpos_y = pt.y;
w->viewport = vp;
_viewport_window_cache.push_back(vp);
FillViewportCoverageRect();
}
static Point _vp_move_offs;
struct ViewportRedrawRegion {
Rect coords;
};
static std::vector<ViewportRedrawRegion> _vp_redraw_regions;
static void DoViewportRedrawRegions(const Window *w, int left, int top, int width, int height)
{
if (width <= 0 || height <= 0) return;
for (const Window *w : Window::IterateFromBack<const Window>(w)) {
if (left + width > w->left &&
w->left + w->width > left &&
top + height > w->top &&
w->top + w->height > top) {
if (left < w->left) {
DoViewportRedrawRegions(w, left, top, w->left - left, height);
DoViewportRedrawRegions(w, left + (w->left - left), top, width - (w->left - left), height);
return;
}
if (left + width > w->left + w->width) {
DoViewportRedrawRegions(w, left, top, (w->left + w->width - left), height);
DoViewportRedrawRegions(w, left + (w->left + w->width - left), top, width - (w->left + w->width - left), height);
return;
}
if (top < w->top) {
DoViewportRedrawRegions(w, left, top, width, (w->top - top));
DoViewportRedrawRegions(w, left, top + (w->top - top), width, height - (w->top - top));
return;
}
if (top + height > w->top + w->height) {
DoViewportRedrawRegions(w, left, top, width, (w->top + w->height - top));
DoViewportRedrawRegions(w, left, top + (w->top + w->height - top), width, height - (w->top + w->height - top));
return;
}
return;
}
}
_vp_redraw_regions.push_back({ { left, top, left + width, top + height } });
}
static void DoSetViewportPositionFillRegion(int left, int top, int width, int height, int xo, int yo) {
int src_left = left - xo;
int src_top = top - yo;
int src_right = src_left + width;
int src_bottom = src_top + height;
for (const auto &region : _vp_redraw_regions) {
if (region.coords.left < src_right &&
region.coords.right > src_left &&
region.coords.top < src_bottom &&
region.coords.bottom > src_top) {
/* can use this region as a source */
if (src_left < region.coords.left) {
DoSetViewportPositionFillRegion(src_left + xo, src_top + yo, region.coords.left - src_left, height, xo, yo);
src_left = region.coords.left;
width = src_right - src_left;
}
if (src_top < region.coords.top) {
DoSetViewportPositionFillRegion(src_left + xo, src_top + yo, width, region.coords.top - src_top, xo, yo);
src_top = region.coords.top;
height = src_bottom - src_top;
}
if (src_right > region.coords.right) {
DoSetViewportPositionFillRegion(region.coords.right + xo, src_top + yo, src_right - region.coords.right, height, xo, yo);
src_right = region.coords.right;
width = src_right - src_left;
}
if (src_bottom > region.coords.bottom) {
DoSetViewportPositionFillRegion(src_left + xo, region.coords.bottom + yo, width, src_bottom - region.coords.bottom, xo, yo);
src_bottom = region.coords.bottom;
height = src_bottom - src_top;
}
if (xo >= 0) {
/* scrolling left, moving pixels right */
width += xo;
} else {
/* scrolling right, moving pixels left */
src_left += xo;
width -= xo;
}
if (yo >= 0) {
/* scrolling down, moving pixels up */
height += yo;
} else {
/* scrolling up, moving pixels down */
src_top += yo;
height -= yo;
}
BlitterFactory::GetCurrentBlitter()->ScrollBuffer(_screen.dst_ptr, src_left, src_top, width, height, xo, yo);
return;
}
}
DrawOverlappedWindowForAll(left, top, left + width, top + height);
};
static void DoSetViewportPosition(Window *w, const int left, const int top, const int width, const int height)
{
const int xo = _vp_move_offs.x;
const int yo = _vp_move_offs.y;
IncrementWindowUpdateNumber();
_vp_redraw_regions.clear();
DoViewportRedrawRegions(w, left, top, width, height);
if (abs(xo) >= width || abs(yo) >= height) {
/* fully outside */
for (ViewportRedrawRegion &vrr : _vp_redraw_regions) {
RedrawScreenRect(vrr.coords.left, vrr.coords.top, vrr.coords.right, vrr.coords.bottom);
}
return;
}
Blitter *blitter = BlitterFactory::GetCurrentBlitter();
if (_cursor.visible) UndrawMouseCursor();
if (_networking) NetworkUndrawChatMessage();
if (xo != 0) {
std::sort(_vp_redraw_regions.begin(), _vp_redraw_regions.end(), [&](const ViewportRedrawRegion &a, const ViewportRedrawRegion &b) {
if (a.coords.right <= b.coords.left && xo > 0) return true;
if (a.coords.left >= b.coords.right && xo < 0) return true;
return false;
});
if (yo != 0) {
std::stable_sort(_vp_redraw_regions.begin(), _vp_redraw_regions.end(), [&](const ViewportRedrawRegion &a, const ViewportRedrawRegion &b) {
if (a.coords.bottom <= b.coords.top && yo > 0) return true;
if (a.coords.top >= b.coords.bottom && yo < 0) return true;
return false;
});
}
} else {
std::sort(_vp_redraw_regions.begin(), _vp_redraw_regions.end(), [&](const ViewportRedrawRegion &a, const ViewportRedrawRegion &b) {
if (a.coords.bottom <= b.coords.top && yo > 0) return true;
if (a.coords.top >= b.coords.bottom && yo < 0) return true;
return false;
});
}
while (!_vp_redraw_regions.empty()) {
const Rect &rect = _vp_redraw_regions.back().coords;
int left = rect.left;
int top = rect.top;
int width = rect.right - rect.left;
int height = rect.bottom - rect.top;
_vp_redraw_regions.pop_back();
VideoDriver::GetInstance()->MakeDirty(left, top, width, height);
int fill_width = abs(xo);
int fill_height = abs(yo);
if (fill_width < width && fill_height < height) {
blitter->ScrollBuffer(_screen.dst_ptr, left, top, width, height, xo, yo);
} else {
if (width < fill_width) fill_width = width;
if (height < fill_height) fill_height = height;
}
if (xo < 0) {
/* scrolling right, moving pixels left, fill in on right */
width -= fill_width;
DoSetViewportPositionFillRegion(left + width, top, fill_width, height, xo, yo);
} else if (xo > 0) {
/* scrolling left, moving pixels right, fill in on left */
DoSetViewportPositionFillRegion(left, top, fill_width, height, xo, yo);
width -= fill_width;
left += fill_width;
}
if (yo < 0 && width > 0) {
/* scrolling down, moving pixels up, fill in at bottom */
height -= fill_height;
DoSetViewportPositionFillRegion(left, top + height, width, fill_height, xo, yo);
} else if (yo > 0 && width > 0) {
/* scrolling up, moving pixels down, fill in at top */
DoSetViewportPositionFillRegion(left, top, width, fill_height, xo, yo);
}
}
}
inline void UpdateViewportDirtyBlockLeftMargin(Viewport *vp)
{
if (vp->zoom >= ZOOM_LVL_DRAW_MAP) {
vp->dirty_block_left_margin = 0;
} else {
vp->dirty_block_left_margin = UnScaleByZoomLower((-vp->virtual_left) & 127, vp->zoom);
}
}
static void SetViewportPosition(Window *w, int x, int y, bool force_update_overlay)
{
if (unlikely(HasBit(_viewport_debug_flags, VDF_DIRTY_WHOLE_VIEWPORT))) {
w->flags |= WF_DIRTY;
}
Viewport *vp = w->viewport;
int old_left = vp->virtual_left;
int old_top = vp->virtual_top;
int i;
int left, top, width, height;
vp->virtual_left = x;
vp->virtual_top = y;
UpdateViewportDirtyBlockLeftMargin(vp);
if (force_update_overlay || IsViewportOverlayOutsideCachedRegion(w)) RebuildViewportOverlay(w, true);
/* Viewport is bound to its left top corner, so it must be rounded down (UnScaleByZoomLower)
* else glitch described in FS#1412 will happen (offset by 1 pixel with zoom level > NORMAL)
*/
old_left = UnScaleByZoomLower(old_left, vp->zoom);
old_top = UnScaleByZoomLower(old_top, vp->zoom);
x = UnScaleByZoomLower(x, vp->zoom);
y = UnScaleByZoomLower(y, vp->zoom);
old_left -= x;
old_top -= y;
if (old_top == 0 && old_left == 0) return;
_vp_move_offs.x = old_left;
_vp_move_offs.y = old_top;
left = vp->left;
top = vp->top;
width = vp->width;
height = vp->height;
if (left < 0) {
width += left;
left = 0;
}
i = left + width - _screen.width;
if (i >= 0) width -= i;
if (width > 0) {
if (top < 0) {
height += top;
top = 0;
}
i = top + height - _screen.height;
if (i >= 0) height -= i;
if (height > 0 && (_vp_move_offs.x != 0 || _vp_move_offs.y != 0)) {
ClearViewportLandPixelCache(vp);
SCOPE_INFO_FMT([&], "DoSetViewportPosition: %d, %d, %d, %d, %d, %d, %s", left, top, width, height, _vp_move_offs.x, _vp_move_offs.y, scope_dumper().WindowInfo(w));
w->viewport->update_vehicles = true;
DoSetViewportPosition((Window *) w->z_front, left, top, width, height);
ClearViewportCache(w->viewport);
FillViewportCoverageRect();
}
}
}
/**
* Is a xy position inside the viewport of the window?
* @param w Window to examine its viewport
* @param x X coordinate of the xy position
* @param y Y coordinate of the xy position
* @return Pointer to the viewport if the xy position is in the viewport of the window,
* otherwise \c nullptr is returned.
*/
Viewport *IsPtInWindowViewport(const Window *w, int x, int y)
{
Viewport *vp = w->viewport;
if (vp != nullptr &&
IsInsideMM(x, vp->left, vp->left + vp->width) &&
IsInsideMM(y, vp->top, vp->top + vp->height))
return vp;
return nullptr;
}
/**
* Translate screen coordinate in a viewport to underlying tile coordinate.
*
* Returns exact point of the map that is visible in the given place
* of the viewport (3D perspective), height of tiles and foundations matter.
*
* @param vp Viewport that contains the (\a x, \a y) screen coordinate
* @param x Screen x coordinate, distance in pixels from the left edge of viewport frame
* @param y Screen y coordinate, distance in pixels from the top edge of viewport frame
* @param clamp_to_map Clamp the coordinate outside of the map to the closest, non-void tile within the map
* @return Tile coordinate or (-1, -1) if given x or y is not within viewport frame
*/
Point TranslateXYToTileCoord(const Viewport *vp, int x, int y, bool clamp_to_map)
{
if (!IsInsideBS(x, vp->left, vp->width) || !IsInsideBS(y, vp->top, vp->height)) {
Point pt = { -1, -1 };
return pt;
}
return InverseRemapCoords2(
ScaleByZoom(x - vp->left, vp->zoom) + vp->virtual_left,
ScaleByZoom(y - vp->top, vp->zoom) + vp->virtual_top, clamp_to_map);
}
/* When used for zooming, check area below current coordinates (x,y)
* and return the tile of the zoomed out/in position (zoom_x, zoom_y)
* when you just want the tile, make x = zoom_x and y = zoom_y */
static Point GetTileFromScreenXY(int x, int y, int zoom_x, int zoom_y)
{
Window *w;
Viewport *vp;
Point pt;
if ( (w = FindWindowFromPt(x, y)) != nullptr &&
(vp = IsPtInWindowViewport(w, x, y)) != nullptr)
return TranslateXYToTileCoord(vp, zoom_x, zoom_y);
pt.y = pt.x = -1;
return pt;
}
Point GetTileBelowCursor()
{
return GetTileFromScreenXY(_cursor.pos.x, _cursor.pos.y, _cursor.pos.x, _cursor.pos.y);
}
Point GetTileZoomCenterWindow(bool in, Window * w)
{
int x, y;
Viewport *vp = w->viewport;
if (in) {
x = ((_cursor.pos.x - vp->left) >> 1) + (vp->width >> 2);
y = ((_cursor.pos.y - vp->top) >> 1) + (vp->height >> 2);
} else {
x = vp->width - (_cursor.pos.x - vp->left);
y = vp->height - (_cursor.pos.y - vp->top);
}
/* Get the tile below the cursor and center on the zoomed-out center */
return GetTileFromScreenXY(_cursor.pos.x, _cursor.pos.y, x + vp->left, y + vp->top);
}
/**
* Update the status of the zoom-buttons according to the zoom-level
* of the viewport. This will update their status and invalidate accordingly
* @param w Window pointer to the window that has the zoom buttons
* @param vp pointer to the viewport whose zoom-level the buttons represent
* @param widget_zoom_in widget index for window with zoom-in button
* @param widget_zoom_out widget index for window with zoom-out button
*/
void HandleZoomMessage(Window *w, const Viewport *vp, byte widget_zoom_in, byte widget_zoom_out)
{
w->SetWidgetDisabledState(widget_zoom_in, vp->zoom <= _settings_client.gui.zoom_min);
w->SetWidgetDirty(widget_zoom_in);
w->SetWidgetDisabledState(widget_zoom_out, vp->zoom >= _settings_client.gui.zoom_max);
w->SetWidgetDirty(widget_zoom_out);
}
/**
* Schedules a tile sprite for drawing.
*
* @param image the image to draw.
* @param pal the provided palette.
* @param x position x (world coordinates) of the sprite.
* @param y position y (world coordinates) of the sprite.
* @param z position z (world coordinates) of the sprite.
* @param sub Only draw a part of the sprite.
* @param extra_offs_x Pixel X offset for the sprite position.
* @param extra_offs_y Pixel Y offset for the sprite position.
*/
static void AddTileSpriteToDraw(SpriteID image, PaletteID pal, int32 x, int32 y, int z, const SubSprite *sub = nullptr, int extra_offs_x = 0, int extra_offs_y = 0)
{
assert((image & SPRITE_MASK) < MAX_SPRITES);
TileSpriteToDraw &ts = _vd.tile_sprites_to_draw.emplace_back();
ts.image = image;
ts.pal = pal;
ts.sub = sub;
Point pt = RemapCoords(x, y, z);
ts.x = pt.x + extra_offs_x;
ts.y = pt.y + extra_offs_y;
}
/**
* Adds a child sprite to the active foundation.
*
* The pixel offset of the sprite relative to the ParentSprite is the sum of the offset passed to OffsetGroundSprite() and extra_offs_?.
*
* @param image the image to draw.
* @param pal the provided palette.
* @param sub Only draw a part of the sprite.
* @param foundation_part Foundation part.
* @param extra_offs_x Pixel X offset for the sprite position.
* @param extra_offs_y Pixel Y offset for the sprite position.
*/
static void AddChildSpriteToFoundation(SpriteID image, PaletteID pal, const SubSprite *sub, FoundationPart foundation_part, int extra_offs_x, int extra_offs_y)
{
assert(IsInsideMM(foundation_part, 0, FOUNDATION_PART_END));
assert(_vd.foundation[foundation_part] != -1);
Point offs = _vd.foundation_offset[foundation_part];
/* Change the active ChildSprite list to the one of the foundation */
int *old_child = _vd.last_child;
_vd.last_child = _vd.last_foundation_child[foundation_part];
AddChildSpriteScreen(image, pal, offs.x + extra_offs_x, offs.y + extra_offs_y, false, sub, false);
/* Switch back to last ChildSprite list */
_vd.last_child = old_child;
}
/**
* Draws a ground sprite at a specific world-coordinate relative to the current tile.
* If the current tile is drawn on top of a foundation the sprite is added as child sprite to the "foundation"-ParentSprite.
*
* @param image the image to draw.
* @param pal the provided palette.
* @param x position x (world coordinates) of the sprite relative to current tile.
* @param y position y (world coordinates) of the sprite relative to current tile.
* @param z position z (world coordinates) of the sprite relative to current tile.
* @param sub Only draw a part of the sprite.
* @param extra_offs_x Pixel X offset for the sprite position.
* @param extra_offs_y Pixel Y offset for the sprite position.
*/
void DrawGroundSpriteAt(SpriteID image, PaletteID pal, int32 x, int32 y, int z, const SubSprite *sub, int extra_offs_x, int extra_offs_y)
{
/* Switch to first foundation part, if no foundation was drawn */
if (_vd.foundation_part == FOUNDATION_PART_NONE) _vd.foundation_part = FOUNDATION_PART_NORMAL;
if (_vd.foundation[_vd.foundation_part] != -1) {
Point pt = RemapCoords(x, y, z);
AddChildSpriteToFoundation(image, pal, sub, _vd.foundation_part, pt.x + extra_offs_x * ZOOM_LVL_BASE, pt.y + extra_offs_y * ZOOM_LVL_BASE);
} else {
AddTileSpriteToDraw(image, pal, _cur_ti->x + x, _cur_ti->y + y, _cur_ti->z + z, sub, extra_offs_x * ZOOM_LVL_BASE, extra_offs_y * ZOOM_LVL_BASE);
}
}
/**
* Draws a ground sprite for the current tile.
* If the current tile is drawn on top of a foundation the sprite is added as child sprite to the "foundation"-ParentSprite.
*
* @param image the image to draw.
* @param pal the provided palette.
* @param sub Only draw a part of the sprite.
* @param extra_offs_x Pixel X offset for the sprite position.
* @param extra_offs_y Pixel Y offset for the sprite position.
*/
void DrawGroundSprite(SpriteID image, PaletteID pal, const SubSprite *sub, int extra_offs_x, int extra_offs_y)
{
DrawGroundSpriteAt(image, pal, 0, 0, 0, sub, extra_offs_x, extra_offs_y);
}
/**
* Called when a foundation has been drawn for the current tile.
* Successive ground sprites for the current tile will be drawn as child sprites of the "foundation"-ParentSprite, not as TileSprites.
*
* @param x sprite x-offset (screen coordinates) of ground sprites relative to the "foundation"-ParentSprite.
* @param y sprite y-offset (screen coordinates) of ground sprites relative to the "foundation"-ParentSprite.
*/
void OffsetGroundSprite(int x, int y)
{
/* Switch to next foundation part */
switch (_vd.foundation_part) {
case FOUNDATION_PART_NONE:
_vd.foundation_part = FOUNDATION_PART_NORMAL;
break;
case FOUNDATION_PART_NORMAL:
_vd.foundation_part = FOUNDATION_PART_HALFTILE;
break;
default: NOT_REACHED();
}
/* _vd.last_child == nullptr if foundation sprite was clipped by the viewport bounds */
if (_vd.last_child != nullptr) _vd.foundation[_vd.foundation_part] = (uint)_vd.parent_sprites_to_draw.size() - 1;
_vd.foundation_offset[_vd.foundation_part].x = x * ZOOM_LVL_BASE;
_vd.foundation_offset[_vd.foundation_part].y = y * ZOOM_LVL_BASE;
_vd.last_foundation_child[_vd.foundation_part] = _vd.last_child;
}
/**
* Adds a child sprite to a parent sprite.
* In contrast to "AddChildSpriteScreen()" the sprite position is in world coordinates
*
* @param image the image to draw.
* @param pal the provided palette.
* @param x position x of the sprite.
* @param y position y of the sprite.
* @param z position z of the sprite.
* @param sub Only draw a part of the sprite.
*/
static void AddCombinedSprite(SpriteID image, PaletteID pal, int x, int y, int z, const SubSprite *sub)
{
Point pt = RemapCoords(x, y, z);
const Sprite *spr = GetSprite(image & SPRITE_MASK, ST_NORMAL);
int left = pt.x + spr->x_offs;
int right = pt.x + spr->x_offs + spr->width;
int top = pt.y + spr->y_offs;
int bottom = pt.y + spr->y_offs + spr->height;
if (left >= _vd.dpi.left + _vd.dpi.width ||
right <= _vd.dpi.left ||
top >= _vd.dpi.top + _vd.dpi.height ||
bottom <= _vd.dpi.top)
return;
AddChildSpriteScreen(image, pal, pt.x, pt.y, false, sub, false, false);
if (left < _vd.combine_left) _vd.combine_left = left;
if (right > _vd.combine_right) _vd.combine_right = right;
if (top < _vd.combine_top) _vd.combine_top = top;
if (bottom > _vd.combine_bottom) _vd.combine_bottom = bottom;
}
/**
* Draw a (transparent) sprite at given coordinates with a given bounding box.
* The bounding box extends from (x + bb_offset_x, y + bb_offset_y, z + bb_offset_z) to (x + w - 1, y + h - 1, z + dz - 1), both corners included.
* Bounding boxes with bb_offset_x == w or bb_offset_y == h or bb_offset_z == dz are allowed and produce thin slices.
*
* @note Bounding boxes are normally specified with bb_offset_x = bb_offset_y = bb_offset_z = 0. The extent of the bounding box in negative direction is
* defined by the sprite offset in the grf file.
* However if modifying the sprite offsets is not suitable (e.g. when using existing graphics), the bounding box can be tuned by bb_offset.
*
* @pre w >= bb_offset_x, h >= bb_offset_y, dz >= bb_offset_z. Else w, h or dz are ignored.
*
* @param image the image to combine and draw,
* @param pal the provided palette,
* @param x position X (world) of the sprite,
* @param y position Y (world) of the sprite,
* @param w bounding box extent towards positive X (world),
* @param h bounding box extent towards positive Y (world),
* @param dz bounding box extent towards positive Z (world),
* @param z position Z (world) of the sprite,
* @param transparent if true, switch the palette between the provided palette and the transparent palette,
* @param bb_offset_x bounding box extent towards negative X (world),
* @param bb_offset_y bounding box extent towards negative Y (world),
* @param bb_offset_z bounding box extent towards negative Z (world)
* @param sub Only draw a part of the sprite.
*/
void AddSortableSpriteToDraw(SpriteID image, PaletteID pal, int x, int y, int w, int h, int dz, int z, bool transparent, int bb_offset_x, int bb_offset_y, int bb_offset_z, const SubSprite *sub)
{
int32 left, right, top, bottom;
assert((image & SPRITE_MASK) < MAX_SPRITES);
/* make the sprites transparent with the right palette */
if (transparent) {
SetBit(image, PALETTE_MODIFIER_TRANSPARENT);
pal = PALETTE_TO_TRANSPARENT;
}
if (_vd.combine_sprites == SPRITE_COMBINE_ACTIVE) {
AddCombinedSprite(image, pal, x, y, z, sub);
return;
}
_vd.last_child = nullptr;
Point pt = RemapCoords(x, y, z);
int tmp_left, tmp_top, tmp_x = pt.x, tmp_y = pt.y;
uint16 tmp_width, tmp_height;
/* Compute screen extents of sprite */
if (unlikely(image == SPR_EMPTY_BOUNDING_BOX)) {
left = tmp_left = RemapCoords(x + w , y + bb_offset_y, z + bb_offset_z).x;
right = RemapCoords(x + bb_offset_x, y + h , z + bb_offset_z).x + 1;
top = tmp_top = RemapCoords(x + bb_offset_x, y + bb_offset_y, z + dz ).y;
bottom = RemapCoords(x + w , y + h , z + bb_offset_z).y + 1;
tmp_width = right - left;
tmp_height = bottom - top;
} else {
const Sprite *spr = GetSprite(image & SPRITE_MASK, ST_NORMAL);
left = tmp_left = (pt.x += spr->x_offs);
right = (pt.x + spr->width );
top = tmp_top = (pt.y += spr->y_offs);
bottom = (pt.y + spr->height);
tmp_width = spr->width;
tmp_height = spr->height;
}
if (unlikely(_draw_bounding_boxes && (image != SPR_EMPTY_BOUNDING_BOX))) {
/* Compute maximal extents of sprite and its bounding box */
left = std::min(left , RemapCoords(x + w , y + bb_offset_y, z + bb_offset_z).x);
right = std::max(right , RemapCoords(x + bb_offset_x, y + h , z + bb_offset_z).x + 1);
top = std::min(top , RemapCoords(x + bb_offset_x, y + bb_offset_y, z + dz ).y);
bottom = std::max(bottom, RemapCoords(x + w , y + h , z + bb_offset_z).y + 1);
}
/* Do not add the sprite to the viewport, if it is outside */
if (left >= _vd.dpi.left + _vd.dpi.width ||
right <= _vd.dpi.left ||
top >= _vd.dpi.top + _vd.dpi.height ||
bottom <= _vd.dpi.top) {
return;
}
ParentSpriteToDraw &ps = _vd.parent_sprites_to_draw.emplace_back();
ps.x = tmp_x;
ps.y = tmp_y;
ps.left = tmp_left;
ps.top = tmp_top;
ps.image = image;
ps.pal = pal;
ps.sub = sub;
ps.xmin = x + bb_offset_x;
ps.xmax = x + std::max(bb_offset_x, w) - 1;
ps.ymin = y + bb_offset_y;
ps.ymax = y + std::max(bb_offset_y, h) - 1;
ps.zmin = z + bb_offset_z;
ps.zmax = z + std::max(bb_offset_z, dz) - 1;
ps.first_child = -1;
ps.width = tmp_width;
ps.height = tmp_height;
/* bit 15 of ps.height */
// ps.comparison_done = false;
_vd.last_child = &ps.first_child;
if (_vd.combine_sprites == SPRITE_COMBINE_PENDING) {
_vd.combine_sprites = SPRITE_COMBINE_ACTIVE;
_vd.combine_psd_index = (uint)_vd.parent_sprites_to_draw.size() - 1;
_vd.combine_left = tmp_left;
_vd.combine_right = right;
_vd.combine_top = tmp_top;
_vd.combine_bottom = bottom;
}
}
/**
* Starts a block of sprites, which are "combined" into a single bounding box.
*
* Subsequent calls to #AddSortableSpriteToDraw will be drawn into the same bounding box.
* That is: The first sprite that is not clipped by the viewport defines the bounding box, and
* the following sprites will be child sprites to that one.
*
* That implies:
* - The drawing order is definite. No other sprites will be sorted between those of the block.
* - You have to provide a valid bounding box for all sprites,
* as you won't know which one is the first non-clipped one.
* Preferable you use the same bounding box for all.
* - You cannot use #AddChildSpriteScreen inside the block, as its result will be indefinite.
*
* The block is terminated by #EndSpriteCombine.
*
* You cannot nest "combined" blocks.
*/
void StartSpriteCombine()
{
assert(_vd.combine_sprites == SPRITE_COMBINE_NONE);
_vd.combine_sprites = SPRITE_COMBINE_PENDING;
}
/**
* Terminates a block of sprites started by #StartSpriteCombine.
* Take a look there for details.
*/
void EndSpriteCombine()
{
assert(_vd.combine_sprites != SPRITE_COMBINE_NONE);
if (_vd.combine_sprites == SPRITE_COMBINE_ACTIVE) {
ParentSpriteToDraw &ps = _vd.parent_sprites_to_draw[_vd.combine_psd_index];
ps.left = _vd.combine_left;
ps.top = _vd.combine_top;
ps.width = _vd.combine_right - _vd.combine_left;
ps.height = _vd.combine_bottom - _vd.combine_top;
}
_vd.combine_sprites = SPRITE_COMBINE_NONE;
}
/**
* Check if the parameter "check" is inside the interval between
* begin and end, including both begin and end.
* @note Whether \c begin or \c end is the biggest does not matter.
* This method will account for that.
* @param begin The begin of the interval.
* @param end The end of the interval.
* @param check The value to check.
*/
static bool IsInRangeInclusive(int begin, int end, int check)
{
if (begin > end) Swap(begin, end);
return begin <= check && check <= end;
}
/**
* Checks whether a point is inside the selected rectangle given by _thd.size, _thd.pos and _thd.diagonal
* @param x The x coordinate of the point to be checked.
* @param y The y coordinate of the point to be checked.
* @return True if the point is inside the rectangle, else false.
*/
static bool IsInsideSelectedRectangle(int x, int y)
{
if (!_thd.diagonal) {
return IsInsideBS(x, _thd.pos.x, _thd.size.x) && IsInsideBS(y, _thd.pos.y, _thd.size.y);
}
int dist_a = (_thd.size.x + _thd.size.y); // Rotated coordinate system for selected rectangle.
int dist_b = (_thd.size.x - _thd.size.y); // We don't have to divide by 2. It's all relative!
int a = ((x - _thd.pos.x) + (y - _thd.pos.y)); // Rotated coordinate system for the point under scrutiny.
int b = ((x - _thd.pos.x) - (y - _thd.pos.y));
/* Check if a and b are between 0 and dist_a or dist_b respectively. */
return IsInRangeInclusive(dist_a, 0, a) && IsInRangeInclusive(dist_b, 0, b);
}
/**
* Add a child sprite to a parent sprite.
*
* @param image the image to draw.
* @param pal the provided palette.
* @param x sprite x-offset (screen coordinates), optionally relative to parent sprite.
* @param y sprite y-offset (screen coordinates), optionally relative to parent sprite.
* @param transparent if true, switch the palette between the provided palette and the transparent palette,
* @param sub Only draw a part of the sprite.
* @param relative Whether coordinates are relative.
*/
void AddChildSpriteScreen(SpriteID image, PaletteID pal, int x, int y, bool transparent, const SubSprite *sub, bool scale, bool relative)
{
assert((image & SPRITE_MASK) < MAX_SPRITES);
/* If the ParentSprite was clipped by the viewport bounds, do not draw the ChildSprites either */
if (_vd.last_child == nullptr) return;
/* make the sprites transparent with the right palette */
if (transparent) {
SetBit(image, PALETTE_MODIFIER_TRANSPARENT);
pal = PALETTE_TO_TRANSPARENT;
}
*_vd.last_child = (uint)_vd.child_screen_sprites_to_draw.size();
ChildScreenSpriteToDraw &cs = _vd.child_screen_sprites_to_draw.emplace_back();
cs.image = image;
cs.pal = pal;
cs.sub = sub;
cs.x = scale ? x * ZOOM_LVL_BASE : x;
cs.y = scale ? y * ZOOM_LVL_BASE : y;
cs.next = -1;
cs.relative = relative;
/* Append the sprite to the active ChildSprite list.
* If the active ParentSprite is a foundation, update last_foundation_child as well.
* Note: ChildSprites of foundations are NOT sequential in the vector, as selection sprites are added at last. */
if (_vd.last_foundation_child[0] == _vd.last_child) _vd.last_foundation_child[0] = &cs.next;
if (_vd.last_foundation_child[1] == _vd.last_child) _vd.last_foundation_child[1] = &cs.next;
_vd.last_child = &cs.next;
}
static void AddStringToDraw(int x, int y, StringID string, uint64 params_1, uint64 params_2, Colours colour, uint16 width)
{
assert(width != 0);
StringSpriteToDraw &ss = _vd.string_sprites_to_draw.emplace_back();
ss.string = string;
ss.x = x;
ss.y = y;
ss.params[0] = params_1;
ss.params[1] = params_2;
ss.width = width;
ss.colour = colour;
}
/**
* Draws sprites between ground sprite and everything above.
*
* The sprite is either drawn as TileSprite or as ChildSprite of the active foundation.
*
* @param image the image to draw.
* @param pal the provided palette.
* @param ti TileInfo Tile that is being drawn
* @param z_offset Z offset relative to the groundsprite. Only used for the sprite position, not for sprite sorting.
* @param foundation_part Foundation part the sprite belongs to.
* @param sub Sub-section of sprite to draw.
*/
void DrawSelectionSprite(SpriteID image, PaletteID pal, const TileInfo *ti, int z_offset, FoundationPart foundation_part, const SubSprite *sub)
{
/* FIXME: This is not totally valid for some autorail highlights that extend over the edges of the tile. */
if (_vd.foundation[foundation_part] == -1) {
/* draw on real ground */
AddTileSpriteToDraw(image, pal, ti->x, ti->y, ti->z + z_offset, sub);
} else {
/* draw on top of foundation */
AddChildSpriteToFoundation(image, pal, sub, foundation_part, 0, -z_offset * ZOOM_LVL_BASE);
}
}
/**
* Draws a selection rectangle on a tile.
*
* @param ti TileInfo Tile that is being drawn
* @param pal Palette to apply.
*/
void DrawTileSelectionRect(const TileInfo *ti, PaletteID pal)
{
if (!IsValidTile(ti->tile)) return;
SpriteID sel;
if (IsHalftileSlope(ti->tileh)) {
Corner halftile_corner = GetHalftileSlopeCorner(ti->tileh);
SpriteID sel2 = SPR_HALFTILE_SELECTION_FLAT + halftile_corner;
DrawSelectionSprite(sel2, pal, ti, 7 + TILE_HEIGHT, FOUNDATION_PART_HALFTILE);
Corner opposite_corner = OppositeCorner(halftile_corner);
if (IsSteepSlope(ti->tileh)) {
sel = SPR_HALFTILE_SELECTION_DOWN;
} else {
sel = ((ti->tileh & SlopeWithOneCornerRaised(opposite_corner)) != 0 ? SPR_HALFTILE_SELECTION_UP : SPR_HALFTILE_SELECTION_FLAT);
}
sel += opposite_corner;
} else {
sel = SPR_SELECT_TILE + SlopeToSpriteOffset(ti->tileh);
}
DrawSelectionSprite(sel, pal, ti, 7, FOUNDATION_PART_NORMAL);
}
static HighLightStyle GetPartOfAutoLine(int px, int py, const Point &selstart, const Point &selend, HighLightStyle dir)
{
if (!IsInRangeInclusive(selstart.x & ~TILE_UNIT_MASK, selend.x & ~TILE_UNIT_MASK, px)) return HT_DIR_END;
if (!IsInRangeInclusive(selstart.y & ~TILE_UNIT_MASK, selend.y & ~TILE_UNIT_MASK, py)) return HT_DIR_END;
px -= selstart.x & ~TILE_UNIT_MASK;
py -= selstart.y & ~TILE_UNIT_MASK;
switch (dir) {
case HT_DIR_X: return (py == 0) ? HT_DIR_X : HT_DIR_END;
case HT_DIR_Y: return (px == 0) ? HT_DIR_Y : HT_DIR_END;
case HT_DIR_HU: return (px == -py) ? HT_DIR_HU : (px == -py - (int)TILE_SIZE) ? HT_DIR_HL : HT_DIR_END;
case HT_DIR_HL: return (px == -py) ? HT_DIR_HL : (px == -py + (int)TILE_SIZE) ? HT_DIR_HU : HT_DIR_END;
case HT_DIR_VL: return (px == py) ? HT_DIR_VL : (px == py + (int)TILE_SIZE) ? HT_DIR_VR : HT_DIR_END;
case HT_DIR_VR: return (px == py) ? HT_DIR_VR : (px == py - (int)TILE_SIZE) ? HT_DIR_VL : HT_DIR_END;
default: NOT_REACHED(); break;
}
return HT_DIR_END;
}
#include "table/autorail.h"
/**
* Draws autorail highlights.
*
* @param *ti TileInfo Tile that is being drawn
* @param autorail_type \c HT_DIR_XXX, offset into _AutorailTilehSprite[][]
* @param pal Palette to use, -1 to autodetect
*/
static void DrawAutorailSelection(const TileInfo *ti, HighLightStyle autorail_type, PaletteID pal = -1)
{
SpriteID image;
FoundationPart foundation_part = FOUNDATION_PART_NORMAL;
int offset;
bool bridge_head_mode = false;
if (IsFlatRailBridgeHeadTile(ti->tile)) {
extern bool IsValidFlatRailBridgeHeadTrackBits(Slope normalised_slope, DiagDirection bridge_direction, TrackBits tracks);
offset = _AutorailTilehSprite[SLOPE_FLAT][autorail_type];
const Slope real_tileh = GetTileSlope(ti->tile, nullptr);
const Slope normalised_tileh = IsSteepSlope(real_tileh) ? SlopeWithOneCornerRaised(GetHighestSlopeCorner(real_tileh)) : real_tileh;
if (!IsValidFlatRailBridgeHeadTrackBits(normalised_tileh, GetTunnelBridgeDirection(ti->tile), TrackToTrackBits((Track) autorail_type))) {
offset = -offset;
}
if (!IsRailCustomBridgeHead(ti->tile)) {
bridge_head_mode = true;
}
} else {
Slope autorail_tileh = RemoveHalftileSlope(ti->tileh);
if (IsHalftileSlope(ti->tileh)) {
static const HighLightStyle _lower_rail[CORNER_END] = { HT_DIR_VR, HT_DIR_HU, HT_DIR_VL, HT_DIR_HL }; // CORNER_W, CORNER_S, CORNER_E, CORNER_N
Corner halftile_corner = GetHalftileSlopeCorner(ti->tileh);
if (autorail_type != _lower_rail[halftile_corner]) {
foundation_part = FOUNDATION_PART_HALFTILE;
/* Here we draw the highlights of the "three-corners-raised"-slope. That looks ok to me. */
autorail_tileh = SlopeWithThreeCornersRaised(OppositeCorner(halftile_corner));
}
}
assert(autorail_type < HT_DIR_END);
offset = _AutorailTilehSprite[autorail_tileh][autorail_type];
}
if (offset >= 0) {
image = SPR_AUTORAIL_BASE + offset;
if (pal == (PaletteID)-1) pal = _thd.make_square_red ? PALETTE_SEL_TILE_RED : PAL_NONE;
} else {
image = SPR_AUTORAIL_BASE - offset;
if (pal == (PaletteID)-1) pal = PALETTE_SEL_TILE_RED;
}
if (bridge_head_mode) {
AddSortableSpriteToDraw(image, pal, ti->x, ti->y, 16, 16, 0, ti->z + 15);
} else {
DrawSelectionSprite(image, pal, ti, 7, foundation_part);
}
}
enum TileHighlightType {
THT_NONE,
THT_WHITE,
THT_BLUE,
THT_RED,
THT_LIGHT_BLUE,
};
const Station *_viewport_highlight_station; ///< Currently selected station for coverage area highlight
const Town *_viewport_highlight_town; ///< Currently selected town for coverage area highlight
/**
* Get tile highlight type of coverage area for a given tile.
* @param t Tile that is being drawn
* @return Tile highlight type to draw
*/
static TileHighlightType GetTileHighlightType(TileIndex t)
{
if (_viewport_highlight_station != nullptr) {
if (IsTileType(t, MP_STATION) && GetStationIndex(t) == _viewport_highlight_station->index) return THT_LIGHT_BLUE;
if (_viewport_highlight_station->TileIsInCatchment(t)) return THT_BLUE;
}
if (_viewport_highlight_town != nullptr) {
if (IsTileType(t, MP_HOUSE)) {
if (GetTownIndex(t) == _viewport_highlight_town->index) {
TileHighlightType type = THT_RED;
for (const Station *st : _viewport_highlight_town->stations_near) {
if (st->owner != _current_company) continue;
if (st->TileIsInCatchment(t)) return THT_BLUE;
}
return type;
}
} else if (IsTileType(t, MP_STATION)) {
for (const Station *st : _viewport_highlight_town->stations_near) {
if (st->owner != _current_company) continue;
if (GetStationIndex(t) == st->index) return THT_WHITE;
}
}
}
return THT_NONE;
}
/**
* Draw tile highlight for coverage area highlight.
* @param *ti TileInfo Tile that is being drawn
* @param tht Highlight type to draw.
*/
static void DrawTileHighlightType(const TileInfo *ti, TileHighlightType tht)
{
switch (tht) {
default:
case THT_NONE: break;
case THT_WHITE: DrawTileSelectionRect(ti, PAL_NONE); break;
case THT_BLUE: DrawTileSelectionRect(ti, PALETTE_SEL_TILE_BLUE); break;
case THT_RED: DrawTileSelectionRect(ti, PALETTE_SEL_TILE_RED); break;
case THT_LIGHT_BLUE: DrawTileSelectionRect(ti, SPR_ZONING_INNER_HIGHLIGHT_LIGHT_BLUE); break;
}
}
/**
* Highlights tiles insede local authority of selected towns.
* @param *ti TileInfo Tile that is being drawn
*/
static void HighlightTownLocalAuthorityTiles(const TileInfo *ti)
{
/* Going through cases in order of computational time. */
if (_town_local_authority_kdtree.Count() == 0) return;
/* Tile belongs to town regardless of distance from town. */
if (GetTileType(ti->tile) == MP_HOUSE) {
if (!Town::GetByTile(ti->tile)->show_zone) return;
DrawTileSelectionRect(ti, PALETTE_CRASH);
return;
}
/* If the closest town in the highlighted list is far, we can stop searching. */
TownID tid = _town_local_authority_kdtree.FindNearest(TileX(ti->tile), TileY(ti->tile));
Town *closest_highlighted_town = Town::Get(tid);
if (DistanceManhattan(ti->tile, closest_highlighted_town->xy) >= _settings_game.economy.dist_local_authority) return;
/* Tile is inside of the local autrhority distance of a highlighted town,
but it is possible that a non-highlighted town is even closer. */
Town *closest_town = ClosestTownFromTile(ti->tile, _settings_game.economy.dist_local_authority);
if (closest_town->show_zone) {
DrawTileSelectionRect(ti, PALETTE_CRASH);
}
}
/**
* Checks if the specified tile is selected and if so draws selection using correct selectionstyle.
* @param *ti TileInfo Tile that is being drawn
*/
static void DrawTileSelection(const TileInfo *ti)
{
/* Highlight tiles insede local authority of selected towns. */
HighlightTownLocalAuthorityTiles(ti);
/* Draw a red error square? */
bool is_redsq = _thd.redsq == ti->tile;
if (is_redsq) DrawTileSelectionRect(ti, PALETTE_TILE_RED_PULSATING);
TileHighlightType tht = GetTileHighlightType(ti->tile);
DrawTileHighlightType(ti, tht);
switch (_thd.drawstyle & HT_DRAG_MASK) {
default: break; // No tile selection active?
case HT_RECT:
if (!is_redsq) {
if (IsInsideSelectedRectangle(ti->x, ti->y)) {
DrawTileSelectionRect(ti, _thd.make_square_red ? PALETTE_SEL_TILE_RED : PAL_NONE);
} else if (_thd.outersize.x > 0 && (tht == THT_NONE || tht == THT_RED) &&
/* Check if it's inside the outer area? */
IsInsideBS(ti->x, _thd.pos.x + _thd.offs.x, _thd.size.x + _thd.outersize.x) &&
IsInsideBS(ti->y, _thd.pos.y + _thd.offs.y, _thd.size.y + _thd.outersize.y)) {
/* Draw a blue rect. */
DrawTileSelectionRect(ti, PALETTE_SEL_TILE_BLUE);
}
}
break;
case HT_POINT:
if (IsInsideSelectedRectangle(ti->x, ti->y)) {
/* Figure out the Z coordinate for the single dot. */
int z = 0;
FoundationPart foundation_part = FOUNDATION_PART_NORMAL;
if (ti->tileh & SLOPE_N) {
z += TILE_HEIGHT;
if (RemoveHalftileSlope(ti->tileh) == SLOPE_STEEP_N) z += TILE_HEIGHT;
}
if (IsHalftileSlope(ti->tileh)) {
Corner halftile_corner = GetHalftileSlopeCorner(ti->tileh);
if ((halftile_corner == CORNER_W) || (halftile_corner == CORNER_E)) z += TILE_HEIGHT;
if (halftile_corner != CORNER_S) {
foundation_part = FOUNDATION_PART_HALFTILE;
if (IsSteepSlope(ti->tileh)) z -= TILE_HEIGHT;
}
}
DrawSelectionSprite(_cur_dpi->zoom <= ZOOM_LVL_DETAIL ? SPR_DOT : SPR_DOT_SMALL, PAL_NONE, ti, z, foundation_part);
}
break;
case HT_RAIL:
if (ti->tile == TileVirtXY(_thd.pos.x, _thd.pos.y)) {
assert((_thd.drawstyle & HT_DIR_MASK) < HT_DIR_END);
DrawAutorailSelection(ti, _thd.drawstyle & HT_DIR_MASK);
}
break;
case HT_LINE: {
HighLightStyle type = GetPartOfAutoLine(ti->x, ti->y, _thd.selstart, _thd.selend, _thd.drawstyle & HT_DIR_MASK);
if (type < HT_DIR_END) {
DrawAutorailSelection(ti, type);
} else if (_thd.dir2 < HT_DIR_END) {
type = GetPartOfAutoLine(ti->x, ti->y, _thd.selstart2, _thd.selend2, _thd.dir2);
if (type < HT_DIR_END) DrawAutorailSelection(ti, type, PALETTE_SEL_TILE_BLUE);
}
break;
}
}
}
/**
* Returns the y coordinate in the viewport coordinate system where the given
* tile is painted.
* @param tile Any tile.
* @return The viewport y coordinate where the tile is painted.
*/
static int GetViewportY(Point tile)
{
/* Each increment in X or Y direction moves down by half a tile, i.e. TILE_PIXELS / 2. */
return (tile.y * (int)(TILE_PIXELS / 2) + tile.x * (int)(TILE_PIXELS / 2) - TilePixelHeightOutsideMap(tile.x, tile.y)) << ZOOM_LVL_SHIFT;
}
/**
* Add the landscape to the viewport, i.e. all ground tiles and buildings.
*/
static void ViewportAddLandscape()
{
assert(_vd.dpi.top <= _vd.dpi.top + _vd.dpi.height);
assert(_vd.dpi.left <= _vd.dpi.left + _vd.dpi.width);
Point upper_left = InverseRemapCoords(_vd.dpi.left, _vd.dpi.top);
Point upper_right = InverseRemapCoords(_vd.dpi.left + _vd.dpi.width, _vd.dpi.top);
/* Transformations between tile coordinates and viewport rows/columns: See vp_column_row
* column = y - x
* row = x + y
* x = (row - column) / 2
* y = (row + column) / 2
* Note: (row, columns) pairs are only valid, if they are both even or both odd.
*/
/* Columns overlap with neighbouring columns by a half tile.
* - Left column is column of upper_left (rounded down) and one column to the left.
* - Right column is column of upper_right (rounded up) and one column to the right.
* Note: Integer-division does not round down for negative numbers, so ensure rounding with another increment/decrement.
*/
int left_column = DivTowardsNegativeInf(upper_left.y - upper_left.x, (int)TILE_SIZE) - 1;
int right_column = DivTowardsPositiveInf(upper_right.y - upper_right.x, (int)TILE_SIZE) + 1;
int potential_bridge_height = ZOOM_LVL_BASE * TILE_HEIGHT * _settings_game.construction.max_bridge_height;
/* Rows overlap with neighbouring rows by a half tile.
* The first row that could possibly be visible is the row above upper_left (if it is at height 0).
* Due to integer-division not rounding down for negative numbers, we need another decrement.
*/
int row = DivTowardsNegativeInf(upper_left.y + upper_left.x, (int)TILE_SIZE) - 1;
bool last_row = false;
for (; !last_row; row++) {
last_row = true;
for (int column = left_column; column <= right_column; column++) {
/* Valid row/column? */
if ((row + column) % 2 != 0) continue;
Point tilecoord;
tilecoord.x = (row - column) / 2;
tilecoord.y = (row + column) / 2;
assert(column == tilecoord.y - tilecoord.x);
assert(row == tilecoord.y + tilecoord.x);
TileType tile_type;
TileInfo tile_info;
_cur_ti = &tile_info;
tile_info.x = tilecoord.x * TILE_SIZE; // FIXME tile_info should use signed integers
tile_info.y = tilecoord.y * TILE_SIZE;
if (IsInsideBS(tilecoord.x, 0, MapSizeX()) && IsInsideBS(tilecoord.y, 0, MapSizeY())) {
/* This includes the south border at MapMaxX / MapMaxY. When terraforming we still draw tile selections there. */
tile_info.tile = TileXY(tilecoord.x, tilecoord.y);
tile_type = GetTileType(tile_info.tile);
} else {
tile_info.tile = INVALID_TILE;
tile_type = MP_VOID;
}
if (tile_type != MP_VOID) {
/* We are inside the map => paint landscape. */
tile_info.tileh = GetTilePixelSlope(tile_info.tile, &tile_info.z);
} else {
/* We are outside the map => paint black. */
tile_info.tileh = GetTilePixelSlopeOutsideMap(tilecoord.x, tilecoord.y, &tile_info.z);
}
int viewport_y = GetViewportY(tilecoord);
if (viewport_y + MAX_TILE_EXTENT_BOTTOM < _vd.dpi.top) {
/* The tile in this column is not visible yet.
* Tiles in other columns may be visible, but we need more rows in any case. */
last_row = false;
continue;
}
int min_visible_height = viewport_y - (_vd.dpi.top + _vd.dpi.height);
bool tile_visible = min_visible_height <= 0;
if (tile_type != MP_VOID) {
/* Is tile with buildings visible? */
if (min_visible_height < MAX_TILE_EXTENT_TOP) tile_visible = true;
if (IsBridgeAbove(tile_info.tile)) {
/* Is the bridge visible? */
TileIndex bridge_tile = GetNorthernBridgeEnd(tile_info.tile);
int bridge_height = ZOOM_LVL_BASE * (GetBridgePixelHeight(bridge_tile) - TilePixelHeight(tile_info.tile));
if (min_visible_height < bridge_height + MAX_TILE_EXTENT_TOP) tile_visible = true;
}
/* Would a higher bridge on a more southern tile be visible?
* If yes, we need to loop over more rows to possibly find one. */
if (min_visible_height < potential_bridge_height + MAX_TILE_EXTENT_TOP) last_row = false;
} else {
/* Outside of map. If we are on the north border of the map, there may still be a bridge visible,
* so we need to loop over more rows to possibly find one. */
if ((tilecoord.x <= 0 || tilecoord.y <= 0) && min_visible_height < potential_bridge_height + MAX_TILE_EXTENT_TOP) last_row = false;
}
if (tile_visible) {
last_row = false;
_vd.foundation_part = FOUNDATION_PART_NONE;
_vd.foundation[0] = -1;
_vd.foundation[1] = -1;
_vd.last_foundation_child[0] = nullptr;
_vd.last_foundation_child[1] = nullptr;
bool no_ground_tiles = min_visible_height > 0;
_tile_type_procs[tile_type]->draw_tile_proc(&tile_info, { min_visible_height, no_ground_tiles });
if (tile_info.tile != INVALID_TILE && min_visible_height <= 0) {
DrawTileSelection(&tile_info);
DrawTileZoning(&tile_info);
}
}
}
}
}
/**
* Add a string to draw in the viewport
* @param dpi current viewport area
* @param small_from Zoomlevel from when the small font should be used
* @param sign sign position and dimension
* @param string_normal String for normal and 2x zoom level
* @param string_small String for 4x and 8x zoom level
* @param string_small_shadow Shadow string for 4x and 8x zoom level; or #STR_NULL if no shadow
* @param colour colour of the sign background; or INVALID_COLOUR if transparent
*/
void ViewportAddString(const DrawPixelInfo *dpi, ZoomLevel small_from, const ViewportSign *sign, StringID string_normal, StringID string_small, StringID string_small_shadow, uint64 params_1, uint64 params_2, Colours colour)
{
bool small = dpi->zoom >= small_from;
int left = dpi->left;
int top = dpi->top;
int right = left + dpi->width;
int bottom = top + dpi->height;
int sign_height = ScaleByZoom(VPSM_TOP + FONT_HEIGHT_NORMAL + VPSM_BOTTOM, dpi->zoom);
int sign_half_width = ScaleByZoom((small ? sign->width_small : sign->width_normal) / 2, dpi->zoom);
if (bottom < sign->top ||
top > sign->top + sign_height ||
right < sign->center - sign_half_width ||
left > sign->center + sign_half_width) {
return;
}
if (!small) {
AddStringToDraw(sign->center - sign_half_width, sign->top, string_normal, params_1, params_2, colour, sign->width_normal);
} else {
int shadow_offset = 0;
if (string_small_shadow != STR_NULL) {
shadow_offset = 4;
AddStringToDraw(sign->center - sign_half_width + shadow_offset, sign->top, string_small_shadow, params_1, params_2, INVALID_COLOUR, sign->width_small);
}
AddStringToDraw(sign->center - sign_half_width, sign->top - shadow_offset, string_small, params_1, params_2,
colour, sign->width_small | 0x8000);
}
}
static Rect ExpandRectWithViewportSignMargins(Rect r, ZoomLevel zoom)
{
/* Pessimistically always use normal font, but also assume small font is never larger in either dimension */
const int fh = FONT_HEIGHT_NORMAL;
const int max_tw = _viewport_sign_maxwidth / 2 + 1;
const int expand_y = ScaleByZoom(VPSM_TOP + fh + VPSM_BOTTOM, zoom);
const int expand_x = ScaleByZoom(VPSM_LEFT + max_tw + VPSM_RIGHT, zoom);
r.left -= expand_x;
r.right += expand_x;
r.top -= expand_y;
r.bottom += expand_y;
return r;
}
static void ViewportAddKdtreeSigns(DrawPixelInfo *dpi, bool towns_only)
{
Rect search_rect{ dpi->left, dpi->top, dpi->left + dpi->width, dpi->top + dpi->height };
search_rect = ExpandRectWithViewportSignMargins(search_rect, dpi->zoom);
bool show_stations = HasBit(_display_opt, DO_SHOW_STATION_NAMES) && _game_mode != GM_MENU && !towns_only;
bool show_waypoints = HasBit(_display_opt, DO_SHOW_WAYPOINT_NAMES) && _game_mode != GM_MENU && !towns_only;
bool show_towns = HasBit(_display_opt, DO_SHOW_TOWN_NAMES) && _game_mode != GM_MENU;
bool show_signs = HasBit(_display_opt, DO_SHOW_SIGNS) && !IsInvisibilitySet(TO_SIGNS) && !towns_only;
bool show_competitors = HasBit(_display_opt, DO_SHOW_COMPETITOR_SIGNS) && !towns_only;
const BaseStation *st;
const Sign *si;
/* Collect all the items first and draw afterwards, to ensure layering */
std::vector<const BaseStation *> stations;
std::vector<const Town *> towns;
std::vector<const Sign *> signs;
_viewport_sign_kdtree.FindContained(search_rect.left, search_rect.top, search_rect.right, search_rect.bottom, [&](const ViewportSignKdtreeItem & item) {
switch (item.type) {
case ViewportSignKdtreeItem::VKI_STATION:
if (!show_stations) break;
st = BaseStation::Get(item.id.station);
/* Don't draw if station is owned by another company and competitor station names are hidden. Stations owned by none are never ignored. */
if (!show_competitors && _local_company != st->owner && st->owner != OWNER_NONE) break;
stations.push_back(st);
break;
case ViewportSignKdtreeItem::VKI_WAYPOINT:
if (!show_waypoints) break;
st = BaseStation::Get(item.id.station);
/* Don't draw if station is owned by another company and competitor station names are hidden. Stations owned by none are never ignored. */
if (!show_competitors && _local_company != st->owner && st->owner != OWNER_NONE) break;
stations.push_back(st);
break;
case ViewportSignKdtreeItem::VKI_TOWN:
if (!show_towns) break;
towns.push_back(Town::Get(item.id.town));
break;
case ViewportSignKdtreeItem::VKI_SIGN:
if (!show_signs) break;
si = Sign::Get(item.id.sign);
/* Don't draw if sign is owned by another company and competitor signs should be hidden.
* Note: It is intentional that also signs owned by OWNER_NONE are hidden. Bankrupt
* companies can leave OWNER_NONE signs after them. */
if (!show_competitors && si->IsCompetitorOwned()) break;
signs.push_back(si);
break;
default:
NOT_REACHED();
}
});
/* Layering order (bottom to top): Town names, signs, stations */
for (const auto *t : towns) {
ViewportAddString(dpi, ZOOM_LVL_OUT_16X, &t->cache.sign,
t->Label(), t->SmallLabel(), STR_VIEWPORT_TOWN_TINY_BLACK,
t->index, t->cache.population);
}
for (const auto *si : signs) {
ViewportAddString(dpi, ZOOM_LVL_OUT_16X, &si->sign,
STR_WHITE_SIGN,
(IsTransparencySet(TO_SIGNS) || si->owner == OWNER_DEITY) ? STR_VIEWPORT_SIGN_SMALL_WHITE : STR_VIEWPORT_SIGN_SMALL_BLACK, STR_NULL,
si->index, 0, (si->owner == OWNER_NONE) ? COLOUR_GREY : (si->owner == OWNER_DEITY ? INVALID_COLOUR : _company_colours[si->owner]));
}
for (const auto *st : stations) {
if (Station::IsExpected(st)) {
/* Station */
ViewportAddString(dpi, ZOOM_LVL_OUT_16X, &st->sign,
STR_VIEWPORT_STATION, STR_VIEWPORT_STATION + 1, STR_NULL,
st->index, st->facilities, (st->owner == OWNER_NONE || !st->IsInUse()) ? COLOUR_GREY : _company_colours[st->owner]);
} else {
/* Waypoint */
ViewportAddString(dpi, ZOOM_LVL_OUT_16X, &st->sign,
STR_VIEWPORT_WAYPOINT, STR_VIEWPORT_WAYPOINT + 1, STR_NULL,
st->index, st->facilities, (st->owner == OWNER_NONE || !st->IsInUse()) ? COLOUR_GREY : _company_colours[st->owner]);
}
}
}
/**
* Update the position of the viewport sign.
* @param center the (preferred) center of the viewport sign
* @param top the new top of the sign
* @param str the string to show in the sign
* @param str_small the string to show when zoomed out. STR_NULL means same as \a str
*/
void ViewportSign::UpdatePosition(ZoomLevel maxzoom, int center, int top, StringID str, StringID str_small)
{
if (this->width_normal != 0) this->MarkDirty(maxzoom);
this->top = top;
char buffer[DRAW_STRING_BUFFER];
GetString(buffer, str, lastof(buffer));
this->width_normal = VPSM_LEFT + Align(GetStringBoundingBox(buffer).width, 2) + VPSM_RIGHT;
this->center = center;
/* zoomed out version */
if (str_small != STR_NULL) {
GetString(buffer, str_small, lastof(buffer));
}
this->width_small = VPSM_LEFT + Align(GetStringBoundingBox(buffer, FS_SMALL).width, 2) + VPSM_RIGHT;
this->MarkDirty(maxzoom);
}
/**
* Mark the sign dirty in all viewports.
* @param maxzoom Maximum %ZoomLevel at which the text is visible.
*
* @ingroup dirty
*/
void ViewportSign::MarkDirty(ZoomLevel maxzoom) const
{
if (maxzoom == ZOOM_LVL_END) return;
Rect zoomlevels[ZOOM_LVL_COUNT];
for (ZoomLevel zoom = ZOOM_LVL_BEGIN; zoom != ZOOM_LVL_END; zoom++) {
const ZoomLevel small_from = (maxzoom == ZOOM_LVL_OUT_8X) ? ZOOM_LVL_OUT_8X : ZOOM_LVL_OUT_16X;
const int width = (zoom >= small_from) ? this->width_small : this->width_normal ;
zoomlevels[zoom].left = this->center - ScaleByZoom(width / 2 + 1, zoom);
zoomlevels[zoom].top = this->top - ScaleByZoom(1, zoom);
zoomlevels[zoom].right = this->center + ScaleByZoom(width / 2 + 1, zoom);
zoomlevels[zoom].bottom = this->top + ScaleByZoom(VPSM_TOP + FONT_HEIGHT_NORMAL + VPSM_BOTTOM + 1, zoom);
}
for (Viewport *vp : _viewport_window_cache) {
if (vp->zoom <= maxzoom) {
Rect &zl = zoomlevels[vp->zoom];
MarkViewportDirty(vp, zl.left, zl.top, zl.right, zl.bottom, VMDF_NONE);
}
}
}
static void ViewportDrawTileSprites(const TileSpriteToDrawVector *tstdv)
{
for (const TileSpriteToDraw &ts : *tstdv) {
DrawSpriteViewport(ts.image, ts.pal, ts.x, ts.y, ts.sub);
}
}
/** This fallback sprite checker always exists. */
static bool ViewportSortParentSpritesChecker()
{
return true;
}
/** Sort parent sprites pointer array */
static void ViewportSortParentSprites(ParentSpriteToSortVector *psdv)
{
auto psdvend = psdv->end();
auto psd = psdv->begin();
while (psd != psdvend) {
ParentSpriteToDraw *ps = *psd;
if (ps->IsComparisonDone()) {
psd++;
continue;
}
ps->SetComparisonDone(true);
for (auto psd2 = psd + 1; psd2 != psdvend; psd2++) {
ParentSpriteToDraw *ps2 = *psd2;
if (ps2->IsComparisonDone()) continue;
/* Decide which comparator to use, based on whether the bounding
* boxes overlap
*/
if (ps->xmax >= ps2->xmin && ps->xmin <= ps2->xmax && // overlap in X?
ps->ymax >= ps2->ymin && ps->ymin <= ps2->ymax && // overlap in Y?
ps->zmax >= ps2->zmin && ps->zmin <= ps2->zmax) { // overlap in Z?
/* Use X+Y+Z as the sorting order, so sprites closer to the bottom of
* the screen and with higher Z elevation, are drawn in front.
* Here X,Y,Z are the coordinates of the "center of mass" of the sprite,
* i.e. X=(left+right)/2, etc.
* However, since we only care about order, don't actually divide / 2
*/
if (ps->xmin + ps->xmax + ps->ymin + ps->ymax + ps->zmin + ps->zmax <=
ps2->xmin + ps2->xmax + ps2->ymin + ps2->ymax + ps2->zmin + ps2->zmax) {
continue;
}
} else {
/* We only change the order, if it is definite.
* I.e. every single order of X, Y, Z says ps2 is behind ps or they overlap.
* That is: If one partial order says ps behind ps2, do not change the order.
*/
if (ps->xmax < ps2->xmin ||
ps->ymax < ps2->ymin ||
ps->zmax < ps2->zmin) {
continue;
}
}
/* Move ps2 in front of ps */
ParentSpriteToDraw *temp = ps2;
for (auto psd3 = psd2; psd3 > psd; psd3--) {
*psd3 = *(psd3 - 1);
}
*psd = temp;
}
}
}
static void ViewportDrawParentSprites(const ParentSpriteToSortVector *psd, const ChildScreenSpriteToDrawVector *csstdv)
{
for (const ParentSpriteToDraw *ps : *psd) {
if (ps->image != SPR_EMPTY_BOUNDING_BOX) DrawSpriteViewport(ps->image, ps->pal, ps->x, ps->y, ps->sub);
int child_idx = ps->first_child;
while (child_idx >= 0) {
const ChildScreenSpriteToDraw *cs = csstdv->data() + child_idx;
child_idx = cs->next;
int x = cs->x;
int y = cs->y;
if (cs->relative) {
x += ps->left;
y += ps->top;
}
DrawSpriteViewport(cs->image, cs->pal, x, y, cs->sub);
}
}
}
/**
* Draws the bounding boxes of all ParentSprites
* @param psd Array of ParentSprites
*/
static void ViewportDrawBoundingBoxes(const ParentSpriteToSortVector *psd)
{
for (const ParentSpriteToDraw *ps : *psd) {
Point pt1 = RemapCoords(ps->xmax + 1, ps->ymax + 1, ps->zmax + 1); // top front corner
Point pt2 = RemapCoords(ps->xmin , ps->ymax + 1, ps->zmax + 1); // top left corner
Point pt3 = RemapCoords(ps->xmax + 1, ps->ymin , ps->zmax + 1); // top right corner
Point pt4 = RemapCoords(ps->xmax + 1, ps->ymax + 1, ps->zmin ); // bottom front corner
DrawBox( pt1.x, pt1.y,
pt2.x - pt1.x, pt2.y - pt1.y,
pt3.x - pt1.x, pt3.y - pt1.y,
pt4.x - pt1.x, pt4.y - pt1.y);
}
}
static void ViewportMapStoreBridge(const Viewport * const vp, const TileIndex tile)
{
extern LegendAndColour _legend_land_owners[NUM_NO_COMPANY_ENTRIES + MAX_COMPANIES + 1];
extern uint _company_to_list_pos[MAX_COMPANIES];
/* No need to bother for hidden things */
if (!_settings_client.gui.show_bridges_on_map) return;
const Owner o = GetTileOwner(tile);
if (o < MAX_COMPANIES && !_legend_land_owners[_company_to_list_pos[o]].show_on_map) return;
switch (GetTunnelBridgeDirection(tile)) {
case DIAGDIR_NE: {
/* X axis: tile at higher coordinate, facing towards lower coordinate */
auto iter = _vd.bridge_to_map_x.lower_bound(tile);
if (iter != _vd.bridge_to_map_x.begin()) {
auto prev = iter;
--prev;
if (prev->second == tile) return;
}
_vd.bridge_to_map_x.insert(iter, std::make_pair(GetOtherTunnelBridgeEnd(tile), tile));
break;
}
case DIAGDIR_NW: {
/* Y axis: tile at higher coordinate, facing towards lower coordinate */
auto iter = _vd.bridge_to_map_y.lower_bound(tile);
if (iter != _vd.bridge_to_map_y.begin()) {
auto prev = iter;
--prev;
if (prev->second == tile) return;
}
_vd.bridge_to_map_y.insert(iter, std::make_pair(GetOtherTunnelBridgeEnd(tile), tile));
break;
}
case DIAGDIR_SW: {
/* X axis: tile at lower coordinate, facing towards higher coordinate */
auto iter = _vd.bridge_to_map_x.lower_bound(tile);
if (iter != _vd.bridge_to_map_x.end() && iter->first == tile) return;
_vd.bridge_to_map_x.insert(iter, std::make_pair(tile, GetOtherTunnelBridgeEnd(tile)));
break;
}
case DIAGDIR_SE: {
/* Y axis: tile at lower coordinate, facing towards higher coordinate */
auto iter = _vd.bridge_to_map_y.lower_bound(tile);
if (iter != _vd.bridge_to_map_y.end() && iter->first == tile) return;
_vd.bridge_to_map_y.insert(iter, std::make_pair(tile, GetOtherTunnelBridgeEnd(tile)));
break;
}
default:
NOT_REACHED();
}
}
void ViewportMapStoreTunnel(const TileIndex tile, const TileIndex tile_south, const int tunnel_z, const bool insert_sorted)
{
extern LegendAndColour _legend_land_owners[NUM_NO_COMPANY_ENTRIES + MAX_COMPANIES + 1];
extern uint _company_to_list_pos[MAX_COMPANIES];
/* No need to bother for hidden things */
if (!_settings_client.gui.show_tunnels_on_map) return;
const Owner o = GetTileOwner(tile);
if (o < MAX_COMPANIES && !_legend_land_owners[_company_to_list_pos[o]].show_on_map) return;
const Axis axis = (TileX(tile) == TileX(tile_south)) ? AXIS_Y : AXIS_X;
const Point viewport_pt = RemapCoords(TileX(tile) * TILE_SIZE, TileY(tile) * TILE_SIZE, tunnel_z);
int y_intercept;
if (axis == AXIS_X) {
/* NE to SW */
y_intercept = viewport_pt.y + (viewport_pt.x / 2);
} else {
/* NW to SE */
y_intercept = viewport_pt.y - (viewport_pt.x / 2);
}
TunnelToMapStorage &storage = (axis == AXIS_X) ? _vd.tunnel_to_map_x : _vd.tunnel_to_map_y;
TunnelToMap *tbtm;
if (insert_sorted) {
auto iter = std::upper_bound(storage.tunnels.begin(), storage.tunnels.end(), y_intercept, [](int a, const TunnelToMap &b) -> bool {
return a < b.y_intercept;
});
tbtm = &(*(storage.tunnels.emplace(iter)));
} else {
storage.tunnels.emplace_back();
tbtm = &(storage.tunnels.back());
}
/* ensure deterministic ordering, to avoid render flicker */
tbtm->tb.from_tile = tile;
tbtm->tb.to_tile = tile_south;
tbtm->y_intercept = y_intercept;
tbtm->tunnel_z = tunnel_z;
}
void ViewportMapClearTunnelCache()
{
_vd.tunnel_to_map_x.tunnels.clear();
_vd.tunnel_to_map_y.tunnels.clear();
}
void ViewportMapInvalidateTunnelCacheByTile(const TileIndex tile, const Axis axis)
{
if (!_settings_client.gui.show_tunnels_on_map) return;
std::vector<TunnelToMap> &tbtmv = (axis == AXIS_X) ? _vd.tunnel_to_map_x.tunnels : _vd.tunnel_to_map_y.tunnels;
for (auto tbtm = tbtmv.begin(); tbtm != tbtmv.end(); tbtm++) {
if (tbtm->tb.from_tile == tile) {
tbtmv.erase(tbtm);
return;
}
}
}
void ViewportMapBuildTunnelCache()
{
ViewportMapClearTunnelCache();
if (_settings_client.gui.show_tunnels_on_map) {
for (Tunnel *tunnel : Tunnel::Iterate()) {
ViewportMapStoreTunnel(tunnel->tile_n, tunnel->tile_s, tunnel->height, false);
}
auto sorter = [](const TunnelToMap &a, const TunnelToMap &b) -> bool {
return a.y_intercept < b.y_intercept;
};
std::sort(_vd.tunnel_to_map_x.tunnels.begin(), _vd.tunnel_to_map_x.tunnels.end(), sorter);
std::sort(_vd.tunnel_to_map_y.tunnels.begin(), _vd.tunnel_to_map_y.tunnels.end(), sorter);
}
}
/**
* Draw/colour the blocks that have been redrawn.
*/
void ViewportDrawDirtyBlocks()
{
Blitter *blitter = BlitterFactory::GetCurrentBlitter();
const DrawPixelInfo *dpi = _cur_dpi;
void *dst;
int right = UnScaleByZoom(dpi->width, dpi->zoom);
int bottom = UnScaleByZoom(dpi->height, dpi->zoom);
int colour = _string_colourmap[_dirty_block_colour & 0xF];
dst = dpi->dst_ptr;
byte bo = UnScaleByZoom(dpi->left + dpi->top, dpi->zoom) & 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);
}
static void ViewportDrawStrings(ZoomLevel zoom, const StringSpriteToDrawVector *sstdv)
{
for (const StringSpriteToDraw &ss : *sstdv) {
TextColour colour = TC_BLACK;
bool small = HasBit(ss.width, 15);
int w = GB(ss.width, 0, 15);
int x = UnScaleByZoom(ss.x, zoom);
int y = UnScaleByZoom(ss.y, zoom);
int h = VPSM_TOP + (small ? FONT_HEIGHT_SMALL : FONT_HEIGHT_NORMAL) + VPSM_BOTTOM;
SetDParam(0, ss.params[0]);
SetDParam(1, ss.params[1]);
if (ss.colour != INVALID_COLOUR) {
/* Do not draw signs nor station names if they are set invisible */
if (IsInvisibilitySet(TO_SIGNS) && ss.string != STR_WHITE_SIGN) continue;
if (IsTransparencySet(TO_SIGNS) && ss.string != STR_WHITE_SIGN) {
/* Don't draw the rectangle.
* Real colours need the TC_IS_PALETTE_COLOUR flag.
* Otherwise colours from _string_colourmap are assumed. */
colour = (TextColour)_colour_gradient[ss.colour][6] | TC_IS_PALETTE_COLOUR;
} else {
/* Draw the rectangle if 'transparent station signs' is off,
* or if we are drawing a general text sign (STR_WHITE_SIGN). */
DrawFrameRect(
x, y, x + w, y + h, ss.colour,
IsTransparencySet(TO_SIGNS) ? FR_TRANSPARENT : FR_NONE
);
}
}
DrawString(x + VPSM_LEFT, x + w - 1 - VPSM_RIGHT, y + VPSM_TOP, ss.string, colour, SA_HOR_CENTER);
}
}
static inline Vehicle *GetVehicleFromWindow(Window *w)
{
if (w) {
WindowClass wc = w->window_class;
WindowNumber wn = w->window_number;
if (wc == WC_DROPDOWN_MENU) GetParentWindowInfo(w, wc, wn);
switch (wc) {
case WC_VEHICLE_VIEW:
case WC_VEHICLE_ORDERS:
case WC_VEHICLE_TIMETABLE:
case WC_VEHICLE_DETAILS:
case WC_VEHICLE_REFIT:
case WC_VEHICLE_CARGO_TYPE_LOAD_ORDERS:
case WC_VEHICLE_CARGO_TYPE_UNLOAD_ORDERS:
if (wn != INVALID_VEHICLE) return Vehicle::Get(wn);
break;
default:
break;
}
}
return nullptr;
}
static inline TileIndex GetLastValidOrderLocation(const Vehicle *veh)
{
TileIndex tmp, result = INVALID_TILE;
for(const Order *order : veh->Orders()) {
switch (order->GetType()) {
case OT_GOTO_STATION:
case OT_GOTO_WAYPOINT:
case OT_IMPLICIT:
case OT_GOTO_DEPOT:
tmp = order->GetLocation(veh, veh->type == VEH_AIRCRAFT);
if (tmp != INVALID_TILE) result = tmp;
break;
default:
break;
}
}
return result;
}
static inline std::pair<const Order *, bool> GetFinalOrder(const Vehicle *veh, const Order *order)
{
// Use Floyd's cycle-finding algorithm to prevent endless loop
// due to a cycle formed by confitional orders.
auto cycle_check = order;
bool is_conditional = false;
while (order->IsType(OT_CONDITIONAL)) {
if (order->GetConditionVariable() != OCV_UNCONDITIONALLY) is_conditional = true;
order = veh->GetOrder(order->GetConditionSkipToOrder());
if (cycle_check->IsType(OT_CONDITIONAL)) {
cycle_check = veh->GetOrder(cycle_check->GetConditionSkipToOrder());
if (cycle_check->IsType(OT_CONDITIONAL)) {
cycle_check = veh->GetOrder(cycle_check->GetConditionSkipToOrder());
}
}
bool cycle_detected = (order->IsType(OT_CONDITIONAL) && (order == cycle_check));
if (cycle_detected) return std::pair<const Order *, bool>(nullptr, is_conditional);
}
return std::pair<const Order *, bool>(order, is_conditional);
}
static bool ViewportMapPrepareVehicleRoute(const Vehicle * const veh)
{
if (!veh) return false;
if (_vp_route_paths.size() == 0) {
TileIndex from_tile = GetLastValidOrderLocation(veh);
if (from_tile == INVALID_TILE) return false;
for(const Order *order : veh->Orders()) {
auto guard = scope_guard([&]() {
if (order->IsType(OT_CONDITIONAL) && order->GetConditionVariable() == OCV_UNCONDITIONALLY) from_tile = INVALID_TILE;
});
const Order *final_order;
bool conditional;
std::tie(final_order, conditional) = GetFinalOrder(veh, order);
if (final_order == nullptr) continue;
const TileIndex to_tile = final_order->GetLocation(veh, veh->type == VEH_AIRCRAFT);
if (to_tile == INVALID_TILE) continue;
if (from_tile != INVALID_TILE) {
DrawnPathRouteTileLine path = { from_tile, to_tile, !conditional };
if (path.from_tile > path.to_tile) std::swap(path.from_tile, path.to_tile);
_vp_route_paths.push_back(path);
}
const OrderType ot = order->GetType();
if (ot == OT_GOTO_STATION || ot == OT_GOTO_DEPOT || ot == OT_GOTO_WAYPOINT || ot == OT_IMPLICIT) from_tile = to_tile;
}
// remove duplicate lines
std::sort(_vp_route_paths.begin(), _vp_route_paths.end());
_vp_route_paths.erase(std::unique(_vp_route_paths.begin(), _vp_route_paths.end()), _vp_route_paths.end());
}
return true;
}
/** Draw the route of a vehicle. */
static void ViewportMapDrawVehicleRoute(const Viewport *vp)
{
switch (_settings_client.gui.show_vehicle_route) {
/* case 0: return; // No */
case 1: { // Simple
DrawPixelInfo *old_dpi = _cur_dpi;
_cur_dpi = &_dpi_for_text;
for (const auto &iter : _vp_route_paths) {
const int from_tile_x = TileX(iter.from_tile) * TILE_SIZE + TILE_SIZE / 2;
const int from_tile_y = TileY(iter.from_tile) * TILE_SIZE + TILE_SIZE / 2;
Point from_pt = RemapCoords(from_tile_x, from_tile_y, 0);
const int from_x = UnScaleByZoom(from_pt.x, vp->zoom);
const int to_tile_x = TileX(iter.to_tile) * TILE_SIZE + TILE_SIZE / 2;
const int to_tile_y = TileY(iter.to_tile) * TILE_SIZE + TILE_SIZE / 2;
Point to_pt = RemapCoords(to_tile_x, to_tile_y, 0);
const int to_x = UnScaleByZoom(to_pt.x, vp->zoom);
if (from_x < _cur_dpi->left - 1 && to_x < _cur_dpi->left - 1) continue;
if (from_x > _cur_dpi->left + _cur_dpi->width + 1 && to_x > _cur_dpi->left + _cur_dpi->width + 1) continue;
from_pt.y -= GetSlopePixelZ(from_tile_x, from_tile_y) * ZOOM_LVL_BASE;
to_pt.y -= GetSlopePixelZ(to_tile_x, to_tile_y) * ZOOM_LVL_BASE;
const int from_y = UnScaleByZoom(from_pt.y, vp->zoom);
const int to_y = UnScaleByZoom(to_pt.y, vp->zoom);
int line_width = 3;
if (_settings_client.gui.dash_level_of_route_lines == 0) {
GfxDrawLine(from_x, from_y, to_x, to_y, PC_BLACK, 3, _settings_client.gui.dash_level_of_route_lines);
line_width = 1;
}
GfxDrawLine(from_x, from_y, to_x, to_y, iter.order_match ? PC_WHITE : PC_YELLOW, line_width, _settings_client.gui.dash_level_of_route_lines);
}
_cur_dpi = old_dpi;
break;
}
}
}
static inline void DrawRouteStep(const Viewport * const vp, const TileIndex tile, const RankOrderTypeList list)
{
if (tile == INVALID_TILE) return;
const uint step_count = list.size() > max_rank_order_type_count ? 1 : (uint)list.size();
const int x_pos = TileX(tile) * TILE_SIZE + TILE_SIZE / 2;
const int y_pos = TileY(tile) * TILE_SIZE + TILE_SIZE / 2;
Point pt = RemapCoords(x_pos, y_pos, 0);
const int x = UnScaleByZoomLower(pt.x - _vd.dpi.left, _vd.dpi.zoom) - (_vp_route_step_width / 2);
if (x >= _cur_dpi->width || (x + _vp_route_step_width) <= 0) return;
pt.y -= GetSlopePixelZ(x_pos, y_pos) * ZOOM_LVL_BASE;
const int char_height = GetCharacterHeight(FS_SMALL) + 1;
const int rsth = _vp_route_step_height_top + (int) step_count * char_height + _vp_route_step_height_bottom;
const int y = UnScaleByZoomLower(pt.y - _vd.dpi.top, _vd.dpi.zoom) - rsth;
if (y >= _cur_dpi->height || (y + rsth) <= 0) return;
/* Draw the background. */
DrawSprite(SPR_ROUTE_STEP_TOP, PAL_NONE, _cur_dpi->left + x, _cur_dpi->top + y);
uint y2 = y + _vp_route_step_height_top;
for (uint r = step_count; r != 0; r--, y2 += char_height) {
DrawSprite(SPR_ROUTE_STEP_MIDDLE, PAL_NONE, _cur_dpi->left + x, _cur_dpi->top + y2, &_vp_route_step_subsprite);
}
DrawSprite(SPR_ROUTE_STEP_BOTTOM, PAL_NONE, _cur_dpi->left + x, _cur_dpi->top + y2);
SpriteID s = SPR_ROUTE_STEP_BOTTOM_SHADOW;
DrawSprite(SetBit(s, PALETTE_MODIFIER_TRANSPARENT), PALETTE_TO_TRANSPARENT, _cur_dpi->left + x, _cur_dpi->top + y2);
/* Fill with the data. */
DrawPixelInfo *old_dpi = _cur_dpi;
y2 = y + _vp_route_step_height_top;
_cur_dpi = &_dpi_for_text;
if (list.size() > max_rank_order_type_count) {
/* Write order overflow item */
SetDParam(0, list.size());
DrawString(_dpi_for_text.left + x, _dpi_for_text.left + x + _vp_route_step_width - 1, _dpi_for_text.top + y2,
STR_VIEWPORT_SHOW_VEHICLE_ROUTE_STEP_OVERFLOW, TC_FROMSTRING, SA_CENTER, false, FS_SMALL);
} else {
for (RankOrderTypeList::const_iterator cit = list.begin(); cit != list.end(); cit++, y2 += char_height) {
bool ok = true;
switch (cit->second) {
case OT_GOTO_STATION:
SetDParam(1, STR_VIEWPORT_SHOW_VEHICLE_ROUTE_STEP_STATION);
break;
case OT_GOTO_DEPOT:
SetDParam(1, STR_VIEWPORT_SHOW_VEHICLE_ROUTE_STEP_DEPOT);
break;
case OT_GOTO_WAYPOINT:
SetDParam(1, STR_VIEWPORT_SHOW_VEHICLE_ROUTE_STEP_WAYPOINT);
break;
case OT_IMPLICIT:
SetDParam(1, STR_VIEWPORT_SHOW_VEHICLE_ROUTE_STEP_IMPLICIT);
break;
default: // OT_NOTHING OT_LOADING OT_LEAVESTATION OT_DUMMY OT_CONDITIONAL
ok = false;
break;
}
if (ok) {
/* Write order's info */
SetDParam(0, cit->first);
DrawString(_dpi_for_text.left + x, _dpi_for_text.left + x + _vp_route_step_width - 1, _dpi_for_text.top + y2,
STR_VIEWPORT_SHOW_VEHICLE_ROUTE_STEP, TC_FROMSTRING, SA_CENTER, false, FS_SMALL);
}
}
}
_cur_dpi = old_dpi;
}
static bool ViewportPrepareVehicleRouteSteps(const Vehicle * const veh)
{
if (!veh) return false;
if (_vp_route_steps.size() == 0) {
/* Prepare data. */
int order_rank = 0;
for(const Order *order : veh->Orders()) {
const TileIndex tile = order->GetLocation(veh, veh->type == VEH_AIRCRAFT);
order_rank++;
if (tile == INVALID_TILE) continue;
_vp_route_steps[tile].push_back(std::pair<int, OrderType>(order_rank, order->GetType()));
}
}
return true;
}
void ViewportPrepareVehicleRoute()
{
if (!_settings_client.gui.show_vehicle_route_steps && !_settings_client.gui.show_vehicle_route) return;
const Vehicle * const veh = GetVehicleFromWindow(_focused_window);
if (_settings_client.gui.show_vehicle_route_steps && veh && ViewportPrepareVehicleRouteSteps(veh)) {
if (_vp_route_steps != _vp_route_steps_last_mark_dirty) {
for (RouteStepsMap::const_iterator cit = _vp_route_steps.begin(); cit != _vp_route_steps.end(); cit++) {
MarkRouteStepDirty(cit);
}
_vp_route_steps_last_mark_dirty = _vp_route_steps;
}
}
if (_settings_client.gui.show_vehicle_route) {
if (!veh) {
if (!_vp_route_paths.empty()) {
// make sure we remove any leftover paths
MarkRoutePathsDirty(_vp_route_paths);
_vp_route_paths.clear();
_vp_route_paths_last_mark_dirty.clear();
}
return;
} else {
if (ViewportMapPrepareVehicleRoute(veh)) {
if (_vp_route_paths_last_mark_dirty != _vp_route_paths) {
// make sure we're not drawing a partial path
MarkRoutePathsDirty(_vp_route_paths);
_vp_route_paths_last_mark_dirty = _vp_route_paths;
}
} else {
if (!_vp_route_paths.empty()) {
// make sure we remove any leftover paths
MarkRoutePathsDirty(_vp_route_paths);
_vp_route_paths.clear();
_vp_route_paths_last_mark_dirty.clear();
}
return;
}
}
}
}
/** Draw the route steps of a vehicle. */
static void ViewportDrawVehicleRouteSteps(const Viewport * const vp)
{
for (RouteStepsMap::const_iterator cit = _vp_route_steps.begin(); cit != _vp_route_steps.end(); cit++) {
DrawRouteStep(vp, cit->first, cit->second);
}
}
void ViewportDrawPlans(const Viewport *vp)
{
if (Plan::GetNumItems() == 0 && !(_current_plan && _current_plan->temp_line->tiles.size() > 1)) return;
DrawPixelInfo *old_dpi = _cur_dpi;
_cur_dpi = &_dpi_for_text;
const Rect bounds = {
ScaleByZoom(_dpi_for_text.left - 2, vp->zoom),
ScaleByZoom(_dpi_for_text.top - 2, vp->zoom),
ScaleByZoom(_dpi_for_text.left + _dpi_for_text.width + 2, vp->zoom),
ScaleByZoom(_dpi_for_text.top + _dpi_for_text.height + 2, vp->zoom) + (int)(ZOOM_LVL_BASE * TILE_HEIGHT * _settings_game.construction.map_height_limit)
};
const int min_coord_delta = bounds.left / (int)(2 * ZOOM_LVL_BASE * TILE_SIZE);
const int max_coord_delta = (bounds.right / (int)(2 * ZOOM_LVL_BASE * TILE_SIZE)) + 1;
for (Plan *p : Plan::Iterate()) {
if (!p->IsVisible()) continue;
for (PlanLineVector::iterator it = p->lines.begin(); it != p->lines.end(); it++) {
PlanLine *pl = *it;
if (!pl->visible) continue;
if (
bounds.left > pl->viewport_extents.right ||
bounds.right < pl->viewport_extents.left ||
bounds.top > pl->viewport_extents.bottom ||
bounds.bottom < pl->viewport_extents.top
) {
continue;
}
TileIndex to_tile = pl->tiles[0];
int to_coord_delta = (int)TileY(to_tile) - (int)TileX(to_tile);
for (uint i = 1; i < pl->tiles.size(); i++) {
const TileIndex from_tile = to_tile;
const int from_coord_delta = to_coord_delta;
to_tile = pl->tiles[i];
to_coord_delta = (int)TileY(to_tile) - (int)TileX(to_tile);
if (to_coord_delta < min_coord_delta && from_coord_delta < min_coord_delta) continue;
if (to_coord_delta > max_coord_delta && from_coord_delta > max_coord_delta) continue;
const Point from_pt = RemapCoords2(TileX(from_tile) * TILE_SIZE + TILE_SIZE / 2, TileY(from_tile) * TILE_SIZE + TILE_SIZE / 2);
const int from_x = UnScaleByZoom(from_pt.x, vp->zoom);
const int from_y = UnScaleByZoom(from_pt.y, vp->zoom);
const Point to_pt = RemapCoords2(TileX(to_tile) * TILE_SIZE + TILE_SIZE / 2, TileY(to_tile) * TILE_SIZE + TILE_SIZE / 2);
const int to_x = UnScaleByZoom(to_pt.x, vp->zoom);
const int to_y = UnScaleByZoom(to_pt.y, vp->zoom);
GfxDrawLine(from_x, from_y, to_x, to_y, PC_BLACK, 3);
if (pl->focused) {
GfxDrawLine(from_x, from_y, to_x, to_y, PC_RED, 1);
} else {
GfxDrawLine(from_x, from_y, to_x, to_y, _colour_value[p->colour], 1);
}
}
}
}
if (_current_plan && _current_plan->temp_line->tiles.size() > 1) {
PlanLine *pl = _current_plan->temp_line;
TileIndex to_tile = pl->tiles[0];
int to_coord_delta = (int)TileY(to_tile) - (int)TileX(to_tile);
for (uint i = 1; i < pl->tiles.size(); i++) {
const TileIndex from_tile = to_tile;
const int from_coord_delta = to_coord_delta;
to_tile = pl->tiles[i];
to_coord_delta = (int)TileY(to_tile) - (int)TileX(to_tile);
if (to_coord_delta < min_coord_delta && from_coord_delta < min_coord_delta) continue;
if (to_coord_delta > max_coord_delta && from_coord_delta > max_coord_delta) continue;
const Point from_pt = RemapCoords2(TileX(from_tile) * TILE_SIZE + TILE_SIZE / 2, TileY(from_tile) * TILE_SIZE + TILE_SIZE / 2);
const int from_x = UnScaleByZoom(from_pt.x, vp->zoom);
const int from_y = UnScaleByZoom(from_pt.y, vp->zoom);
const Point to_pt = RemapCoords2(TileX(to_tile) * TILE_SIZE + TILE_SIZE / 2, TileY(to_tile) * TILE_SIZE + TILE_SIZE / 2);
const int to_x = UnScaleByZoom(to_pt.x, vp->zoom);
const int to_y = UnScaleByZoom(to_pt.y, vp->zoom);
GfxDrawLine(from_x, from_y, to_x, to_y, _colour_value[_current_plan->colour], 3, 1);
}
}
_cur_dpi = old_dpi;
}
#define SLOPIFY_COLOUR(tile, height, vF, vW, vS, vE, vN, action) { \
if (show_slope) { \
const Slope slope = GetTileSlope((tile), (height)); \
switch (slope) { \
case SLOPE_FLAT: \
case SLOPE_ELEVATED: \
action (vF); break; \
default: { \
switch (slope & SLOPE_EW) { \
case SLOPE_W: action (vW); break; \
case SLOPE_E: action (vE); break; \
default: action (slope & SLOPE_S) ? (vS) : (vN); break; \
} \
break; \
} \
} \
} else { \
action (vF); \
} \
}
#define RETURN_SLOPIFIED_COLOUR(tile, height, colour, colour_light, colour_dark) SLOPIFY_COLOUR(tile, height, colour, colour_light, colour_dark, colour_dark, colour_light, return)
#define ASSIGN_SLOPIFIED_COLOUR(tile, height, colour, colour_light, colour_dark, to_var) SLOPIFY_COLOUR(tile, height, colour, colour_light, colour_dark, colour_dark, colour_light, to_var =)
#define GET_SLOPE_INDEX(slope_index) SLOPIFY_COLOUR(tile, nullptr, 0, 1, 2, 3, 4, slope_index =)
#define COL8TO32(x) _cur_palette.palette[x].data
#define COLOUR_FROM_INDEX(x) ((const uint8 *)&(x))[colour_index]
#define IS32(x) (is_32bpp ? COL8TO32(x) : (x))
/* Variables containing Colour if 32bpp or palette index if 8bpp. */
uint32 _vp_map_vegetation_clear_colours[16][6][8]; ///< [Slope][ClearGround][Multi (see LoadClearGroundMainColours())]
uint32 _vp_map_vegetation_tree_colours[16][5][MAX_TREE_COUNT_BY_LANDSCAPE]; ///< [Slope][TreeGround][max of _tree_count_by_landscape]
uint32 _vp_map_water_colour[5]; ///< [Slope]
static inline uint ViewportMapGetColourIndexMulti(const TileIndex tile, const ClearGround cg)
{
switch (cg) {
case CLEAR_GRASS:
case CLEAR_SNOW:
case CLEAR_DESERT:
return GetClearDensity(tile);
case CLEAR_ROUGH:
return GB(TileX(tile) ^ TileY(tile), 4, 3);
case CLEAR_ROCKS:
return TileHash(TileX(tile), TileY(tile)) & 1;
case CLEAR_FIELDS:
return GetFieldType(tile) & 7;
default: NOT_REACHED();
}
}
static const ClearGround _treeground_to_clearground[5] = {
CLEAR_GRASS, // TREE_GROUND_GRASS
CLEAR_ROUGH, // TREE_GROUND_ROUGH
CLEAR_SNOW, // TREE_GROUND_SNOW_DESERT, make it +1 if _settings_game.game_creation.landscape == LT_TROPIC
CLEAR_GRASS, // TREE_GROUND_SHORE
CLEAR_SNOW, // TREE_GROUND_ROUGH_SNOW, make it +1 if _settings_game.game_creation.landscape == LT_TROPIC
};
template <bool is_32bpp, bool show_slope>
static inline uint32 ViewportMapGetColourVegetation(const TileIndex tile, TileType t, const uint colour_index)
{
uint32 colour;
switch (t) {
case MP_CLEAR: {
Slope slope = show_slope ? (Slope) (GetTileSlope(tile, nullptr) & 15) : SLOPE_FLAT;
uint multi;
ClearGround cg = GetClearGround(tile);
if (cg == CLEAR_FIELDS && colour_index & 1) {
cg = CLEAR_GRASS;
multi = 1;
} else multi = ViewportMapGetColourIndexMulti(tile, cg);
return _vp_map_vegetation_clear_colours[slope][cg][multi];
}
case MP_INDUSTRY:
colour = IsTileForestIndustry(tile) ? (colour_index & 1 ? PC_GREEN : 0x7B) : GREY_SCALE(3);
break;
case MP_TREES: {
const TreeGround tg = GetTreeGround(tile);
const uint td = GetTreeDensity(tile);
Slope slope = show_slope ? (Slope) (GetTileSlope(tile, nullptr) & 15) : SLOPE_FLAT;
if (IsTransparencySet(TO_TREES)) {
ClearGround cg = _treeground_to_clearground[tg];
if (cg == CLEAR_SNOW && _settings_game.game_creation.landscape == LT_TROPIC) cg = CLEAR_DESERT;
uint32 ground_colour = _vp_map_vegetation_clear_colours[slope][cg][td];
if (IsInvisibilitySet(TO_TREES)) {
/* Like ground. */
return ground_colour;
}
/* Take ground and make it darker. */
if (is_32bpp) {
return Blitter_32bppBase::MakeTransparent(ground_colour, 192, 256).data;
} else {
/* 8bpp transparent snow trees give blue. Definitely don't want that. Prefer grey. */
if (cg == CLEAR_SNOW && td > 1) return GREY_SCALE(13 - GetTreeCount(tile));
return _pal2trsp_remap_ptr[ground_colour];
}
} else {
if (tg == TREE_GROUND_SNOW_DESERT || tg == TREE_GROUND_ROUGH_SNOW) {
return _vp_map_vegetation_clear_colours[colour_index ^ slope][_settings_game.game_creation.landscape == LT_TROPIC ? CLEAR_DESERT : CLEAR_SNOW][td];
} else {
const uint rnd = std::min<uint>(GetTreeCount(tile) ^ (((tile & 3) ^ (TileY(tile) & 3)) * td), MAX_TREE_COUNT_BY_LANDSCAPE - 1);
return _vp_map_vegetation_tree_colours[slope][tg][rnd];
}
}
}
case MP_WATER:
if (is_32bpp) {
uint slope_index = 0;
if (IsTileType(tile, MP_WATER) && GetWaterTileType(tile) != WATER_TILE_COAST) GET_SLOPE_INDEX(slope_index);
return _vp_map_water_colour[slope_index];
}
/* FALL THROUGH */
default:
colour = ApplyMask(MKCOLOUR_XXXX(GREY_SCALE(3)), &_smallmap_vehicles_andor[t]);
colour = COLOUR_FROM_INDEX(colour);
break;
}
if (is_32bpp) {
return COL8TO32(colour);
} else {
if (show_slope) ASSIGN_SLOPIFIED_COLOUR(tile, nullptr, colour, _lighten_colour[colour], _darken_colour[colour], colour);
return colour;
}
}
template <bool is_32bpp, bool show_slope>
static inline uint32 ViewportMapGetColourIndustries(const TileIndex tile, const TileType t, const uint colour_index)
{
extern LegendAndColour _legend_from_industries[NUM_INDUSTRYTYPES + 1];
extern uint _industry_to_list_pos[NUM_INDUSTRYTYPES];
extern bool _smallmap_show_heightmap;
TileType t2 = t;
if (t == MP_INDUSTRY) {
/* If industry is allowed to be seen, use its colour on the map. */
const IndustryType it = Industry::GetByTile(tile)->type;
if (_legend_from_industries[_industry_to_list_pos[it]].show_on_map)
return IS32(GetIndustrySpec(it)->map_colour);
/* Otherwise, return the colour which will make it disappear. */
t2 = IsTileOnWater(tile) ? MP_WATER : MP_CLEAR;
}
if (is_32bpp && t2 == MP_WATER) {
uint slope_index = 0;
if (t != MP_INDUSTRY && IsTileType(tile, MP_WATER) && GetWaterTileType(tile) != WATER_TILE_COAST) GET_SLOPE_INDEX(slope_index); ///< Ignore industry on water not shown on map.
return _vp_map_water_colour[slope_index];
}
const int h = TileHeight(tile);
const SmallMapColourScheme * const cs = &_heightmap_schemes[_settings_client.gui.smallmap_land_colour];
const uint32 colours = ApplyMask(_smallmap_show_heightmap ? cs->height_colours[h] : cs->default_colour, &_smallmap_vehicles_andor[t2]);
uint32 colour = COLOUR_FROM_INDEX(colours);
if (show_slope) ASSIGN_SLOPIFIED_COLOUR(tile, nullptr, colour, _lighten_colour[colour], _darken_colour[colour], colour);
return IS32(colour);
}
template <bool is_32bpp, bool show_slope>
static inline uint32 ViewportMapGetColourOwner(const TileIndex tile, TileType t, const uint colour_index)
{
extern LegendAndColour _legend_land_owners[NUM_NO_COMPANY_ENTRIES + MAX_COMPANIES + 1];
extern uint _company_to_list_pos[MAX_COMPANIES];
switch (t) {
case MP_INDUSTRY: return IS32(PC_DARK_GREY);
case MP_HOUSE: return IS32(colour_index & 1 ? PC_DARK_RED : GREY_SCALE(3));
default: break;
}
const Owner o = GetTileOwner(tile);
if ((o < MAX_COMPANIES && !_legend_land_owners[_company_to_list_pos[o]].show_on_map) || o == OWNER_NONE || o == OWNER_WATER) {
if (t == MP_WATER) {
if (is_32bpp) {
uint slope_index = 0;
if (IsTileType(tile, MP_WATER) && GetWaterTileType(tile) != WATER_TILE_COAST) GET_SLOPE_INDEX(slope_index);
return _vp_map_water_colour[slope_index];
} else {
return PC_WATER;
}
}
const int h = TileHeight(tile);
uint32 colour = COLOUR_FROM_INDEX(_heightmap_schemes[_settings_client.gui.smallmap_land_colour].height_colours[h]);
if (show_slope) ASSIGN_SLOPIFIED_COLOUR(tile, nullptr, colour, _lighten_colour[colour], _darken_colour[colour], colour);
return IS32(colour);
} else if (o == OWNER_TOWN) {
return IS32(t == MP_ROAD ? (colour_index & 1 ? PC_BLACK : GREY_SCALE(3)) : PC_DARK_RED);
}
/* Train stations are sometimes hard to spot.
* So we give the player a hint by mixing his colour with black. */
uint32 colour = _legend_land_owners[_company_to_list_pos[o]].colour;
if (t != MP_STATION) {
if (show_slope) ASSIGN_SLOPIFIED_COLOUR(tile, nullptr, colour, _lighten_colour[colour], _darken_colour[colour], colour);
} else {
if (GetStationType(tile) == STATION_RAIL) colour = colour_index & 1 ? colour : PC_BLACK;
}
if (is_32bpp) return COL8TO32(colour);
return colour;
}
template <bool is_32bpp, bool show_slope>
static inline uint32 ViewportMapGetColourRoutes(const TileIndex tile, TileType t, const uint colour_index)
{
uint32 colour;
switch (t) {
case MP_WATER:
if (is_32bpp) {
uint slope_index = 0;
if (IsTileType(tile, MP_WATER) && GetWaterTileType(tile) != WATER_TILE_COAST) GET_SLOPE_INDEX(slope_index);
return _vp_map_water_colour[slope_index];
} else {
return PC_WATER;
}
case MP_INDUSTRY:
return IS32(PC_DARK_GREY);
case MP_HOUSE:
case MP_OBJECT:
return IS32(colour_index & 1 ? PC_DARK_RED : GREY_SCALE(3));
case MP_STATION:
switch (GetStationType(tile)) {
case STATION_RAIL: return IS32(PC_VERY_DARK_BROWN);
case STATION_AIRPORT: return IS32(PC_RED);
case STATION_TRUCK: return IS32(PC_ORANGE);
case STATION_BUS: return IS32(PC_YELLOW);
case STATION_DOCK: return IS32(PC_LIGHT_BLUE);
default: return IS32(0xFF);
}
case MP_RAILWAY: {
colour = GetRailTypeInfo(GetRailType(tile))->map_colour;
break;
}
case MP_ROAD: {
const RoadTypeInfo *rti = nullptr;
if (GetRoadTypeRoad(tile) != INVALID_ROADTYPE) {
rti = GetRoadTypeInfo(GetRoadTypeRoad(tile));
} else {
rti = GetRoadTypeInfo(GetRoadTypeTram(tile));
}
if (rti != nullptr) {
colour = rti->map_colour;
break;
}
FALLTHROUGH;
}
default:
colour = COLOUR_FROM_INDEX(_heightmap_schemes[_settings_client.gui.smallmap_land_colour].height_colours[TileHeight(tile)]);
break;
}
if (show_slope) ASSIGN_SLOPIFIED_COLOUR(tile, nullptr, colour, _lighten_colour[colour], _darken_colour[colour], colour);
return IS32(colour);
}
static inline void ViewportMapStoreBridgeAboveTile(const Viewport * const vp, const TileIndex tile)
{
/* No need to bother for hidden things */
if (!_settings_client.gui.show_bridges_on_map) return;
if (GetBridgeAxis(tile) == AXIS_X) {
auto iter = _vd.bridge_to_map_x.lower_bound(tile);
if (iter != _vd.bridge_to_map_x.end() && iter->first < tile && iter->second > tile) return; /* already covered */
_vd.bridge_to_map_x.insert(iter, std::make_pair(GetNorthernBridgeEnd(tile), GetSouthernBridgeEnd(tile)));
} else {
auto iter = _vd.bridge_to_map_y.lower_bound(tile);
if (iter != _vd.bridge_to_map_y.end() && iter->first < tile && iter->second > tile) return; /* already covered */
_vd.bridge_to_map_y.insert(iter, std::make_pair(GetNorthernBridgeEnd(tile), GetSouthernBridgeEnd(tile)));
}
}
static inline TileIndex ViewportMapGetMostSignificantTileType(const Viewport * const vp, const TileIndex from_tile, TileType * const tile_type)
{
if (vp->zoom <= ZOOM_LVL_OUT_128X || !_settings_client.gui.viewport_map_scan_surroundings) {
const TileType ttype = GetTileType(from_tile);
/* Store bridges and tunnels. */
if (ttype != MP_TUNNELBRIDGE) {
*tile_type = ttype;
if (IsBridgeAbove(from_tile)) ViewportMapStoreBridgeAboveTile(vp, from_tile);
} else {
if (IsBridge(from_tile)) {
ViewportMapStoreBridge(vp, from_tile);
}
switch (GetTunnelBridgeTransportType(from_tile)) {
case TRANSPORT_RAIL: *tile_type = MP_RAILWAY; break;
case TRANSPORT_ROAD: *tile_type = MP_ROAD; break;
case TRANSPORT_WATER: *tile_type = MP_WATER; break;
default: NOT_REACHED(); break;
}
}
return from_tile;
}
const uint8 length = (vp->zoom - ZOOM_LVL_OUT_128X) * 2;
TileArea tile_area = TileArea(from_tile, length, length);
tile_area.ClampToMap();
/* Find the most important tile of the area. */
TileIndex result = from_tile;
uint importance = 0;
TILE_AREA_LOOP_WITH_PREFETCH(tile, tile_area) {
const TileType ttype = GetTileType(tile);
const uint tile_importance = _tiletype_importance[ttype];
if (tile_importance > importance) {
importance = tile_importance;
result = tile;
}
if (ttype != MP_TUNNELBRIDGE && IsBridgeAbove(tile)) {
ViewportMapStoreBridgeAboveTile(vp, tile);
}
}
/* Store bridges and tunnels. */
*tile_type = GetTileType(result);
if (*tile_type == MP_TUNNELBRIDGE) {
if (IsBridge(result)) {
ViewportMapStoreBridge(vp, result);
}
switch (GetTunnelBridgeTransportType(result)) {
case TRANSPORT_RAIL: *tile_type = MP_RAILWAY; break;
case TRANSPORT_ROAD: *tile_type = MP_ROAD; break;
default: *tile_type = MP_WATER; break;
}
}
return result;
}
/** Get the colour of a tile, can be 32bpp RGB or 8bpp palette index. */
template <bool is_32bpp, bool show_slope>
uint32 ViewportMapGetColour(const Viewport * const vp, int x, int y, const uint colour_index)
{
if (x >= static_cast<int>(MapMaxX() * TILE_SIZE) || y >= static_cast<int>(MapMaxY() * TILE_SIZE)) return 0;
/* Very approximative but fast way to get the tile when taking Z into account. */
const TileIndex tile_tmp = TileVirtXY(std::max(0, x), std::max(0, y));
const int z = TileHeight(tile_tmp) * 4;
if (x + z < 0 || y + z < 0 || static_cast<uint>(x + z) >= MapSizeX() << 4) {
/* Wrapping of tile X coordinate causes a graphic glitch below south west border. */
return 0;
}
TileIndex tile = TileVirtXY(x + z, y + z);
if (tile >= MapSize()) return 0;
const int z2 = TileHeight(tile) * 4;
if (unlikely(z2 != z)) {
const int approx_z = (z + z2) / 2;
if (x + approx_z < 0 || y + approx_z < 0 || static_cast<uint>(x + approx_z) >= MapSizeX() << 4) {
/* Wrapping of tile X coordinate causes a graphic glitch below south west border. */
return 0;
}
tile = TileVirtXY(x + approx_z, y + approx_z);
if (tile >= MapSize()) return 0;
}
TileType tile_type = MP_VOID;
tile = ViewportMapGetMostSignificantTileType(vp, tile, &tile_type);
if (tile_type == MP_VOID) return 0;
/* Return the colours. */
switch (vp->map_type) {
default: return ViewportMapGetColourOwner<is_32bpp, show_slope>(tile, tile_type, colour_index);
case VPMT_INDUSTRY: return ViewportMapGetColourIndustries<is_32bpp, show_slope>(tile, tile_type, colour_index);
case VPMT_VEGETATION: return ViewportMapGetColourVegetation<is_32bpp, show_slope>(tile, tile_type, colour_index);
case VPMT_ROUTES: return ViewportMapGetColourRoutes<is_32bpp, show_slope>(tile, tile_type, colour_index);
}
}
/* Taken from http://stereopsis.com/doubleblend.html, PixelBlend() is faster than ComposeColourRGBANoCheck() */
static inline void PixelBlend(uint32 * const d, const uint32 s)
{
const uint32 a = (s >> 24) + 1;
const uint32 dstrb = *d & 0xFF00FF;
const uint32 dstg = *d & 0xFF00;
const uint32 srcrb = s & 0xFF00FF;
const uint32 srcg = s & 0xFF00;
uint32 drb = srcrb - dstrb;
uint32 dg = srcg - dstg;
drb *= a;
dg *= a;
drb >>= 8;
dg >>= 8;
uint32 rb = (drb + dstrb) & 0xFF00FF;
uint32 g = (dg + dstg) & 0xFF00;
*d = rb | g;
}
/** Draw the bounding boxes of the scrolling viewport (right-clicked and dragged) */
static void ViewportMapDrawScrollingViewportBox(const Viewport * const vp)
{
if (_scrolling_viewport && _scrolling_viewport->viewport) {
const Viewport * const vp_scrolling = _scrolling_viewport->viewport;
if (vp_scrolling->zoom < ZOOM_LVL_DRAW_MAP) {
/* Check intersection of dpi and vp_scrolling */
const int mask = ScaleByZoom(-1, vp->zoom);
const int vp_scrolling_virtual_top_mask = vp_scrolling->virtual_top & mask;
const int vp_scrolling_virtual_bottom_mask = (vp_scrolling->virtual_top + vp_scrolling->virtual_height) & mask;
const int t_inter = std::max(vp_scrolling_virtual_top_mask, _vd.dpi.top);
const int b_inter = std::min(vp_scrolling_virtual_bottom_mask, _vd.dpi.top + _vd.dpi.height);
if (t_inter < b_inter) {
const int vp_scrolling_virtual_left_mask = vp_scrolling->virtual_left & mask;
const int vp_scrolling_virtual_right_mask = (vp_scrolling->virtual_left + vp_scrolling->virtual_width) & mask;
const int l_inter = std::max(vp_scrolling_virtual_left_mask, _vd.dpi.left);
const int r_inter = std::min(vp_scrolling_virtual_right_mask, _vd.dpi.left + _vd.dpi.width);
if (l_inter < r_inter) {
/* OK, so we can draw something that tells where the scrolling viewport is */
Blitter * const blitter = BlitterFactory::GetCurrentBlitter();
const int w_inter = UnScaleByZoom(r_inter - l_inter, vp->zoom);
const int h_inter = UnScaleByZoom(b_inter - t_inter, vp->zoom);
const int x = UnScaleByZoom(l_inter - _vd.dpi.left, vp->zoom);
const int y = UnScaleByZoom(t_inter - _vd.dpi.top, vp->zoom);
/* If asked, with 32bpp we can do some blending */
if (_settings_client.gui.show_scrolling_viewport_on_map >= 2 && blitter->GetScreenDepth() == 32)
for (int j = y; j < y + h_inter; j++)
for (int i = x; i < x + w_inter; i++)
PixelBlend((uint32*) blitter->MoveTo(_vd.dpi.dst_ptr, i, j), 0x40FCFCFC);
/* Draw area contour */
if (_settings_client.gui.show_scrolling_viewport_on_map != 2) {
if (t_inter == vp_scrolling_virtual_top_mask)
for (int i = x; i < x + w_inter; i += 2)
blitter->SetPixel(_vd.dpi.dst_ptr, i, y, PC_WHITE);
if (b_inter == vp_scrolling_virtual_bottom_mask)
for (int i = x; i < x + w_inter; i += 2)
blitter->SetPixel(_vd.dpi.dst_ptr, i, y + h_inter, PC_WHITE);
if (l_inter == vp_scrolling_virtual_left_mask)
for (int j = y; j < y + h_inter; j += 2)
blitter->SetPixel(_vd.dpi.dst_ptr, x, j, PC_WHITE);
if (r_inter == vp_scrolling_virtual_right_mask)
for (int j = y; j < y + h_inter; j += 2)
blitter->SetPixel(_vd.dpi.dst_ptr, x + w_inter, j, PC_WHITE);
}
}
}
}
}
}
template <bool is_32bpp>
static void ViewportMapDrawBridgeTunnel(Viewport * const vp, const TunnelBridgeToMap * const tbtm, const int z,
const bool is_tunnel, const int w, const int h, Blitter * const blitter)
{
extern LegendAndColour _legend_land_owners[NUM_NO_COMPANY_ENTRIES + MAX_COMPANIES + 1];
extern uint _company_to_list_pos[MAX_COMPANIES];
TileIndex tile = tbtm->from_tile;
const Owner o = GetTileOwner(tile);
if (o < MAX_COMPANIES && !_legend_land_owners[_company_to_list_pos[o]].show_on_map) return;
uint8 colour;
if (vp->map_type == VPMT_OWNER && _settings_client.gui.use_owner_colour_for_tunnelbridge && o < MAX_COMPANIES) {
colour = _legend_land_owners[_company_to_list_pos[o]].colour;
colour = is_tunnel ? _darken_colour[colour] : _lighten_colour[colour];
} else {
colour = is_tunnel ? PC_BLACK : PC_VERY_LIGHT_YELLOW;
}
TileIndexDiff delta = TileOffsByDiagDir(GetTunnelBridgeDirection(tile));
for (tile += delta; tile != tbtm->to_tile; tile += delta) { // For each tile
const Point pt = RemapCoords(TileX(tile) * TILE_SIZE, TileY(tile) * TILE_SIZE, z);
const int x = UnScaleByZoomLower(pt.x - _vd.dpi.left, _vd.dpi.zoom);
if (IsInsideMM(x, 0, w)) {
const int y = UnScaleByZoomLower(pt.y - _vd.dpi.top, _vd.dpi.zoom);
if (IsInsideMM(y, 0, h)) {
uint idx = (x + _vd.offset_x) + ((y + _vd.offset_y) * vp->width);
if (is_32bpp) {
reinterpret_cast<uint32 *>(vp->land_pixel_cache.data())[idx] = COL8TO32(colour);
} else {
reinterpret_cast<uint8 *>(vp->land_pixel_cache.data())[idx] = colour;
}
}
}
}
}
/** Draw the map on a viewport. */
template <bool is_32bpp, bool show_slope>
void ViewportMapDraw(Viewport * const vp)
{
assert(vp != nullptr);
Blitter * const blitter = BlitterFactory::GetCurrentBlitter();
SmallMapWindow::RebuildColourIndexIfNecessary();
/* Index of colour: _green_map_heights[] contains blocks of 4 colours, say ABCD
* For a XXXY colour block to render nicely, follow the model:
* line 1: ABCDABCDABCD
* line 2: CDABCDABCDAB
* line 3: ABCDABCDABCD
* => colour_index_base's second bit is changed every new line.
*/
const int sx = UnScaleByZoomLower(_vd.dpi.left, _vd.dpi.zoom);
const int sy = UnScaleByZoomLower(_vd.dpi.top, _vd.dpi.zoom);
const uint line_padding = 2 * (sy & 1);
uint colour_index_base = (sx + line_padding) & 3;
const int incr_a = (1 << (vp->zoom - 2)) / ZOOM_LVL_BASE;
const int incr_b = (1 << (vp->zoom - 1)) / ZOOM_LVL_BASE;
const int a = (_vd.dpi.left >> 2) / ZOOM_LVL_BASE;
int b = (_vd.dpi.top >> 1) / ZOOM_LVL_BASE;
const int w = UnScaleByZoom(_vd.dpi.width, vp->zoom);
const int h = UnScaleByZoom(_vd.dpi.height, vp->zoom);
int j = 0;
const int land_cache_start = _vd.offset_x + (_vd.offset_y * vp->width);
uint32 *land_cache_ptr32 = reinterpret_cast<uint32 *>(vp->land_pixel_cache.data()) + land_cache_start;
uint8 *land_cache_ptr8 = reinterpret_cast<uint8 *>(vp->land_pixel_cache.data()) + land_cache_start;
bool cache_updated = false;
/* Render base map. */
do { // For each line
int i = w;
uint colour_index = colour_index_base;
colour_index_base ^= 2;
int c = b - a;
int d = b + a;
do { // For each pixel of a line
if (is_32bpp) {
if (*land_cache_ptr32 == 0xD7D7D7D7) {
*land_cache_ptr32 = ViewportMapGetColour<is_32bpp, show_slope>(vp, c, d, colour_index);
cache_updated = true;
}
land_cache_ptr32++;
} else {
if (*land_cache_ptr8 == 0xD7) {
*land_cache_ptr8 = (uint8) ViewportMapGetColour<is_32bpp, show_slope>(vp, c, d, colour_index);
cache_updated = true;
}
land_cache_ptr8++;
}
colour_index = (colour_index + 1) & 3;
c -= incr_a;
d += incr_a;
} while (--i);
if (is_32bpp) {
land_cache_ptr32 += (vp->width - w);
} else {
land_cache_ptr8 += (vp->width - w);
}
b += incr_b;
} while (++j < h);
auto draw_tunnels = [&](const int y_intercept_min, const int y_intercept_max, const TunnelToMapStorage &storage) {
auto iter = std::lower_bound(storage.tunnels.begin(), storage.tunnels.end(), y_intercept_min, [](const TunnelToMap &a, int b) -> bool {
return a.y_intercept < b;
});
for (; iter != storage.tunnels.end() && iter->y_intercept <= y_intercept_max; ++iter) {
const TunnelToMap &ttm = *iter;
const int tunnel_z = ttm.tunnel_z * TILE_HEIGHT;
const Point pt_from = RemapCoords(TileX(ttm.tb.from_tile) * TILE_SIZE, TileY(ttm.tb.from_tile) * TILE_SIZE, tunnel_z);
const Point pt_to = RemapCoords(TileX(ttm.tb.to_tile) * TILE_SIZE, TileY(ttm.tb.to_tile) * TILE_SIZE, tunnel_z);
/* check if tunnel is wholly outside redrawing area */
const int x_from = UnScaleByZoomLower(pt_from.x - _vd.dpi.left, _vd.dpi.zoom);
const int x_to = UnScaleByZoomLower(pt_to.x - _vd.dpi.left, _vd.dpi.zoom);
if ((x_from < 0 && x_to < 0) || (x_from > w && x_to > w)) continue;
const int y_from = UnScaleByZoomLower(pt_from.y - _vd.dpi.top, _vd.dpi.zoom);
const int y_to = UnScaleByZoomLower(pt_to.y - _vd.dpi.top, _vd.dpi.zoom);
if ((y_from < 0 && y_to < 0) || (y_from > h && y_to > h)) continue;
ViewportMapDrawBridgeTunnel<is_32bpp>(vp, &ttm.tb, tunnel_z, true, w, h, blitter);
}
};
if (cache_updated) {
/* Render tunnels */
if (_settings_client.gui.show_tunnels_on_map && _vd.tunnel_to_map_x.tunnels.size() != 0) {
const int y_intercept_min = _vd.dpi.top + (_vd.dpi.left / 2);
const int y_intercept_max = _vd.dpi.top + _vd.dpi.height + ((_vd.dpi.left + _vd.dpi.width) / 2);
draw_tunnels(y_intercept_min, y_intercept_max, _vd.tunnel_to_map_x);
}
if (_settings_client.gui.show_tunnels_on_map && _vd.tunnel_to_map_y.tunnels.size() != 0) {
const int y_intercept_min = _vd.dpi.top - ((_vd.dpi.left + _vd.dpi.width) / 2);
const int y_intercept_max = _vd.dpi.top + _vd.dpi.height - (_vd.dpi.left / 2);
draw_tunnels(y_intercept_min, y_intercept_max, _vd.tunnel_to_map_y);
}
/* Render bridges */
if (_settings_client.gui.show_bridges_on_map && _vd.bridge_to_map_x.size() != 0) {
for (const auto &it : _vd.bridge_to_map_x) { // For each bridge
TunnelBridgeToMap tbtm { it.first, it.second };
ViewportMapDrawBridgeTunnel<is_32bpp>(vp, &tbtm, (GetBridgeHeight(tbtm.from_tile) - 1) * TILE_HEIGHT, false, w, h, blitter);
}
}
if (_settings_client.gui.show_bridges_on_map && _vd.bridge_to_map_y.size() != 0) {
for (const auto &it : _vd.bridge_to_map_y) { // For each bridge
TunnelBridgeToMap tbtm { it.first, it.second };
ViewportMapDrawBridgeTunnel<is_32bpp>(vp, &tbtm, (GetBridgeHeight(tbtm.from_tile) - 1) * TILE_HEIGHT, false, w, h, blitter);
}
}
}
if (is_32bpp) {
blitter->SetRect32(_vd.dpi.dst_ptr, 0, 0, reinterpret_cast<uint32 *>(vp->land_pixel_cache.data()) + land_cache_start, h, w, vp->width);
} else {
blitter->SetRect(_vd.dpi.dst_ptr, 0, 0, reinterpret_cast<uint8 *>(vp->land_pixel_cache.data()) + land_cache_start, h, w, vp->width);
}
if (unlikely(HasBit(_viewport_debug_flags, VDF_SHOW_NO_LANDSCAPE_MAP_DRAW)) && !cache_updated) {
ViewportDrawDirtyBlocks();
++_dirty_block_colour;
}
}
static void ViewportProcessParentSprites()
{
if (_vd.parent_sprites_to_sort.size() > 60 && (_cur_dpi->width >= 256 || _cur_dpi->height >= 256) && !_draw_bounding_boxes && !HasBit(_viewport_debug_flags, VDF_DISABLE_DRAW_SPLIT)) {
/* split drawing region */
ParentSpriteToSortVector all_sprites = std::move(_vd.parent_sprites_to_sort);
_vd.parent_sprites_to_sort.clear();
void *saved_dst_ptr = _cur_dpi->dst_ptr;
if (_cur_dpi->height > _cur_dpi->width) {
/* vertical split: upper half */
const int orig_height = _cur_dpi->height;
const int orig_top = _cur_dpi->top;
_cur_dpi->height = (orig_height / 2) & ScaleByZoom(-1, _cur_dpi->zoom);
int split = _cur_dpi->top + _cur_dpi->height;
for (ParentSpriteToDraw *psd : all_sprites) {
if (psd->top < split) _vd.parent_sprites_to_sort.push_back(psd);
}
ViewportProcessParentSprites();
_vd.parent_sprites_to_sort.clear();
/* vertical split: lower half */
_cur_dpi->dst_ptr = BlitterFactory::GetCurrentBlitter()->MoveTo(_cur_dpi->dst_ptr, 0, UnScaleByZoom(_cur_dpi->height, _cur_dpi->zoom));
_cur_dpi->top = split;
_cur_dpi->height = orig_height - _cur_dpi->height;
for (ParentSpriteToDraw *psd : all_sprites) {
psd->SetComparisonDone(false);
if (psd->top + psd->height > _cur_dpi->top) {
_vd.parent_sprites_to_sort.push_back(psd);
}
}
ViewportProcessParentSprites();
/* restore _cur_dpi */
_cur_dpi->height = orig_height;
_cur_dpi->top = orig_top;
} else {
/* horizontal split: left half */
const int orig_width = _cur_dpi->width;
const int orig_left = _cur_dpi->left;
_cur_dpi->width = (orig_width / 2) & ScaleByZoom(-1, _cur_dpi->zoom);
const int margin = UnScaleByZoom(128, _cur_dpi->zoom); // Half tile (1 column) margin either side of split
const int split = _cur_dpi->left + _cur_dpi->width;
for (ParentSpriteToDraw *psd : all_sprites) {
if (psd->left < split + margin) _vd.parent_sprites_to_sort.push_back(psd);
}
ViewportProcessParentSprites();
_vd.parent_sprites_to_sort.clear();
/* horizontal split: right half */
_cur_dpi->dst_ptr = BlitterFactory::GetCurrentBlitter()->MoveTo(_cur_dpi->dst_ptr, UnScaleByZoom(_cur_dpi->width, _cur_dpi->zoom), 0);
_cur_dpi->left = split;
_cur_dpi->width = orig_width - _cur_dpi->width;
for (ParentSpriteToDraw *psd : all_sprites) {
psd->SetComparisonDone(false);
if (psd->left + psd->width > _cur_dpi->left - margin) {
_vd.parent_sprites_to_sort.push_back(psd);
}
}
ViewportProcessParentSprites();
/* restore _cur_dpi */
_cur_dpi->width = orig_width;
_cur_dpi->left = orig_left;
}
_cur_dpi->dst_ptr = saved_dst_ptr;
} else {
_vp_sprite_sorter(&_vd.parent_sprites_to_sort);
ViewportDrawParentSprites(&_vd.parent_sprites_to_sort, &_vd.child_screen_sprites_to_draw);
if (_draw_dirty_blocks && HasBit(_viewport_debug_flags, VDF_DIRTY_BLOCK_PER_SPLIT)) {
ViewportDrawDirtyBlocks();
++_dirty_block_colour;
}
}
}
void ViewportDoDraw(Viewport *vp, int left, int top, int right, int bottom)
{
DrawPixelInfo *old_dpi = _cur_dpi;
_cur_dpi = &_vd.dpi;
_vd.dpi.zoom = vp->zoom;
int mask = ScaleByZoom(-1, vp->zoom);
_vd.combine_sprites = SPRITE_COMBINE_NONE;
_vd.dpi.width = (right - left) & mask;
_vd.dpi.height = (bottom - top) & mask;
_vd.dpi.left = left & mask;
_vd.dpi.top = top & mask;
_vd.dpi.pitch = old_dpi->pitch;
_vd.last_child = nullptr;
_vd.offset_x = UnScaleByZoomLower(_vd.dpi.left - (vp->virtual_left & mask), vp->zoom);
_vd.offset_y = UnScaleByZoomLower(_vd.dpi.top - (vp->virtual_top & mask), vp->zoom);
int x = _vd.offset_x + vp->left;
int y = _vd.offset_y + vp->top;
_vd.dpi.dst_ptr = BlitterFactory::GetCurrentBlitter()->MoveTo(old_dpi->dst_ptr, x - old_dpi->left, y - old_dpi->top);
_dpi_for_text = _vd.dpi;
_dpi_for_text.left = UnScaleByZoom(_dpi_for_text.left, _dpi_for_text.zoom);
_dpi_for_text.top = UnScaleByZoom(_dpi_for_text.top, _dpi_for_text.zoom);
_dpi_for_text.width = UnScaleByZoom(_dpi_for_text.width, _dpi_for_text.zoom);
_dpi_for_text.height = UnScaleByZoom(_dpi_for_text.height, _dpi_for_text.zoom);
_dpi_for_text.zoom = ZOOM_LVL_NORMAL;
if (vp->zoom >= ZOOM_LVL_DRAW_MAP) {
/* Here the rendering is like smallmap. */
if (BlitterFactory::GetCurrentBlitter()->GetScreenDepth() == 32) {
if (_settings_client.gui.show_slopes_on_viewport_map) ViewportMapDraw<true, true>(vp);
else ViewportMapDraw<true, false>(vp);
} else {
_pal2trsp_remap_ptr = IsTransparencySet(TO_TREES) ? GetNonSprite(GB(PALETTE_TO_TRANSPARENT, 0, PALETTE_WIDTH), ST_RECOLOUR) + 1 : nullptr;
if (_settings_client.gui.show_slopes_on_viewport_map) ViewportMapDraw<false, true>(vp);
else ViewportMapDraw<false, false>(vp);
}
ViewportMapDrawVehicles(&_vd.dpi, vp);
if (_scrolling_viewport && _settings_client.gui.show_scrolling_viewport_on_map) ViewportMapDrawScrollingViewportBox(vp);
if (vp->zoom < ZOOM_LVL_OUT_256X) ViewportAddKdtreeSigns(&_vd.dpi, true);
} else {
/* Classic rendering. */
ViewportAddLandscape();
ViewportAddVehicles(&_vd.dpi, vp->update_vehicles);
ViewportAddKdtreeSigns(&_vd.dpi, false);
DrawTextEffects(&_vd.dpi);
if (_vd.tile_sprites_to_draw.size() != 0) ViewportDrawTileSprites(&_vd.tile_sprites_to_draw);
for (auto &psd : _vd.parent_sprites_to_draw) {
_vd.parent_sprites_to_sort.push_back(&psd);
}
ViewportProcessParentSprites();
if (_draw_bounding_boxes) ViewportDrawBoundingBoxes(&_vd.parent_sprites_to_sort);
}
if (_draw_dirty_blocks && !(HasBit(_viewport_debug_flags, VDF_DIRTY_BLOCK_PER_SPLIT) && vp->zoom < ZOOM_LVL_DRAW_MAP)) {
ViewportDrawDirtyBlocks();
if (HasBit(_viewport_debug_flags, VDF_DIRTY_BLOCK_PER_DRAW)) ++_dirty_block_colour;
}
DrawPixelInfo dp = _vd.dpi;
ZoomLevel zoom = _vd.dpi.zoom;
dp.zoom = ZOOM_LVL_NORMAL;
dp.width = UnScaleByZoom(dp.width, zoom);
dp.height = UnScaleByZoom(dp.height, zoom);
_cur_dpi = &dp;
if (vp->overlay != nullptr && vp->overlay->GetCargoMask() != 0 && vp->overlay->GetCompanyMask() != 0) {
/* translate to window coordinates */
dp.left = x;
dp.top = y;
vp->overlay->Draw(&dp);
}
if (_settings_client.gui.show_vehicle_route) ViewportMapDrawVehicleRoute(vp);
if (_vd.string_sprites_to_draw.size() != 0) {
/* translate to world coordinates */
dp.left = UnScaleByZoom(_vd.dpi.left, zoom);
dp.top = UnScaleByZoom(_vd.dpi.top, zoom);
ViewportDrawStrings(zoom, &_vd.string_sprites_to_draw);
}
if (_settings_client.gui.show_vehicle_route_steps) ViewportDrawVehicleRouteSteps(vp);
ViewportDrawPlans(vp);
_cur_dpi = old_dpi;
_vd.bridge_to_map_x.clear();
_vd.bridge_to_map_y.clear();
_vd.string_sprites_to_draw.clear();
_vd.tile_sprites_to_draw.clear();
_vd.parent_sprites_to_draw.clear();
_vd.parent_sprites_to_sort.clear();
_vd.child_screen_sprites_to_draw.clear();
}
/**
* Make sure we don't draw a too big area at a time.
* If we do, the sprite sorter will run into major performance problems and the sprite memory may overflow.
*/
void ViewportDrawChk(Viewport *vp, int left, int top, int right, int bottom)
{
if ((vp->zoom < ZOOM_LVL_DRAW_MAP) && ((int64)ScaleByZoom(bottom - top, vp->zoom) * (int64)ScaleByZoom(right - left, vp->zoom) > (int64)(1000000 * ZOOM_LVL_BASE * ZOOM_LVL_BASE))) {
if ((bottom - top) > (right - left)) {
int t = (top + bottom) >> 1;
ViewportDrawChk(vp, left, top, right, t);
ViewportDrawChk(vp, left, t, right, bottom);
} else {
int t = (left + right) >> 1;
ViewportDrawChk(vp, left, top, t, bottom);
ViewportDrawChk(vp, t, top, right, bottom);
}
} else {
ViewportDoDraw(vp,
ScaleByZoom(left - vp->left, vp->zoom) + vp->virtual_left,
ScaleByZoom(top - vp->top, vp->zoom) + vp->virtual_top,
ScaleByZoom(right - vp->left, vp->zoom) + vp->virtual_left,
ScaleByZoom(bottom - vp->top, vp->zoom) + vp->virtual_top
);
}
}
static inline void ViewportDraw(Viewport *vp, int left, int top, int right, int bottom)
{
if (right <= vp->left || bottom <= vp->top) return;
if (left >= vp->left + vp->width) return;
if (left < vp->left) left = vp->left;
if (right > vp->left + vp->width) right = vp->left + vp->width;
if (top >= vp->top + vp->height) return;
if (top < vp->top) top = vp->top;
if (bottom > vp->top + vp->height) bottom = vp->top + vp->height;
vp->is_drawn = true;
ViewportDrawChk(vp, left, top, right, bottom);
}
/**
* Draw the viewport of this window.
*/
void Window::DrawViewport() const
{
PerformanceAccumulator framerate(PFE_DRAWWORLD);
DrawPixelInfo *dpi = _cur_dpi;
dpi->left += this->left;
dpi->top += this->top;
ViewportDraw(this->viewport, dpi->left, dpi->top, dpi->left + dpi->width, dpi->top + dpi->height);
dpi->left -= this->left;
dpi->top -= this->top;
}
/**
* Ensure that a given viewport has a valid scroll position.
*
* There must be a visible piece of the map in the center of the viewport.
* If there isn't, the viewport will be scrolled to nearest such location.
*
* @param vp The viewport.
* @param[in,out] scroll_x Viewport X scroll.
* @param[in,out] scroll_y Viewport Y scroll.
*/
static inline void ClampViewportToMap(const Viewport *vp, int *scroll_x, int *scroll_y)
{
/* Centre of the viewport is hot spot. */
Point pt = {
*scroll_x + vp->virtual_width / 2,
*scroll_y + vp->virtual_height / 2
};
/* Find nearest tile that is within borders of the map. */
bool clamped;
pt = InverseRemapCoords2(pt.x, pt.y, true, &clamped);
if (clamped) {
/* Convert back to viewport coordinates and remove centering. */
pt = RemapCoords2(pt.x, pt.y);
*scroll_x = pt.x - vp->virtual_width / 2;
*scroll_y = pt.y - vp->virtual_height / 2;
}
}
/**
* Update the viewport position being displayed.
* @param w %Window owning the viewport.
*/
void UpdateViewportPosition(Window *w)
{
const Viewport *vp = w->viewport;
if (w->viewport->follow_vehicle != INVALID_VEHICLE) {
const Vehicle *veh = Vehicle::Get(w->viewport->follow_vehicle);
Point pt = MapXYZToViewport(vp, veh->x_pos, veh->y_pos, veh->z_pos);
w->viewport->scrollpos_x = pt.x;
w->viewport->scrollpos_y = pt.y;
SetViewportPosition(w, pt.x, pt.y, false);
} else {
/* Ensure the destination location is within the map */
ClampViewportToMap(vp, &w->viewport->dest_scrollpos_x, &w->viewport->dest_scrollpos_y);
int delta_x = w->viewport->dest_scrollpos_x - w->viewport->scrollpos_x;
int delta_y = w->viewport->dest_scrollpos_y - w->viewport->scrollpos_y;
bool update_overlay = false;
if (delta_x != 0 || delta_y != 0) {
if (_settings_client.gui.smooth_scroll) {
int max_scroll = ScaleByMapSize1D(512 * ZOOM_LVL_BASE);
/* Not at our desired position yet... */
w->viewport->scrollpos_x += Clamp(DivAwayFromZero(delta_x, 4), -max_scroll, max_scroll);
w->viewport->scrollpos_y += Clamp(DivAwayFromZero(delta_y, 4), -max_scroll, max_scroll);
} else {
w->viewport->scrollpos_x = w->viewport->dest_scrollpos_x;
w->viewport->scrollpos_y = w->viewport->dest_scrollpos_y;
}
update_overlay = (w->viewport->scrollpos_x == w->viewport->dest_scrollpos_x &&
w->viewport->scrollpos_y == w->viewport->dest_scrollpos_y);
}
ClampViewportToMap(vp, &w->viewport->scrollpos_x, &w->viewport->scrollpos_y);
if (_scrolling_viewport == w) UpdateActiveScrollingViewport(w);
SetViewportPosition(w, w->viewport->scrollpos_x, w->viewport->scrollpos_y, update_overlay);
}
}
void UpdateViewportSizeZoom(Viewport *vp)
{
vp->dirty_blocks_per_column = CeilDiv(vp->height, vp->GetDirtyBlockHeight());
vp->dirty_blocks_per_row = CeilDiv(vp->width, vp->GetDirtyBlockWidth());
uint size = vp->dirty_blocks_per_row * vp->dirty_blocks_per_column;
vp->dirty_blocks.assign(size, false);
UpdateViewportDirtyBlockLeftMargin(vp);
if (vp->zoom >= ZOOM_LVL_DRAW_MAP) {
memset(vp->map_draw_vehicles_cache.done_hash_bits, 0, sizeof(vp->map_draw_vehicles_cache.done_hash_bits));
vp->map_draw_vehicles_cache.vehicle_pixels.assign(vp->width * vp->height, false);
if (BlitterFactory::GetCurrentBlitter()->GetScreenDepth() == 32) {
vp->land_pixel_cache.assign(vp->height * vp->width * 4, 0xD7);
} else {
vp->land_pixel_cache.assign(vp->height * vp->width, 0xD7);
}
} else {
vp->map_draw_vehicles_cache.vehicle_pixels.clear();
vp->land_pixel_cache.clear();
vp->land_pixel_cache.shrink_to_fit();
}
vp->update_vehicles = true;
FillViewportCoverageRect();
}
void UpdateActiveScrollingViewport(Window *w)
{
if (w && (!_settings_client.gui.show_scrolling_viewport_on_map || w->viewport->zoom >= ZOOM_LVL_DRAW_MAP)) w = nullptr;
const bool bound_valid = (_scrolling_viewport_bound.left != _scrolling_viewport_bound.right);
if (!w && !bound_valid) return;
const int gap = ScaleByZoom(1, ZOOM_LVL_MAX);
auto get_bounds = [&gap](const ViewportData *vp) -> Rect {
int lr_low = vp->virtual_left;
int lr_hi = vp->dest_scrollpos_x;
if (lr_low > lr_hi) Swap(lr_low, lr_hi);
int right = lr_hi + vp->virtual_width + gap;
int tb_low = vp->virtual_top;
int tb_hi = vp->scrollpos_y;
if (tb_low > tb_hi) Swap(tb_low, tb_hi);
int bottom = tb_hi + vp->virtual_height + gap;
return { lr_low, tb_low, right, bottom };
};
if (w && !bound_valid) {
const Rect bounds = get_bounds(w->viewport);
MarkAllViewportMapsDirty(bounds.left, bounds.top, bounds.right, bounds.bottom);
_scrolling_viewport_bound = bounds;
} else if (!w && bound_valid) {
const Rect &bounds = _scrolling_viewport_bound;
MarkAllViewportMapsDirty(bounds.left, bounds.top, bounds.right, bounds.bottom);
_scrolling_viewport_bound = { 0, 0, 0, 0 };
} else {
/* Calculate symmetric difference of two rectangles */
const Rect a = get_bounds(w->viewport);
const Rect &b = _scrolling_viewport_bound;
if (a.left != b.left) MarkAllViewportMapsDirty(std::min(a.left, b.left) - gap, std::min(a.top, b.top) - gap, std::max(a.left, b.left) + gap, std::max(a.bottom, b.bottom) + gap);
if (a.top != b.top) MarkAllViewportMapsDirty(std::min(a.left, b.left) - gap, std::min(a.top, b.top) - gap, std::max(a.right, b.right) + gap, std::max(a.top, b.top) + gap);
if (a.right != b.right) MarkAllViewportMapsDirty(std::min(a.right, b.right) - (2 * gap), std::min(a.top, b.top) - gap, std::max(a.right, b.right) + gap, std::max(a.bottom, b.bottom) + gap);
if (a.bottom != b.bottom) MarkAllViewportMapsDirty(std::min(a.left, b.left) - gap, std::min(a.bottom, b.bottom) - (2 * gap), std::max(a.right, b.right) + gap, std::max(a.bottom, b.bottom) + gap);
_scrolling_viewport_bound = a;
}
}
/**
* Marks a viewport as dirty for repaint if it displays (a part of) the area the needs to be repainted.
* @param vp The viewport to mark as dirty
* @param left Left edge of area to repaint
* @param top Top edge of area to repaint
* @param right Right edge of area to repaint
* @param bottom Bottom edge of area to repaint
* @ingroup dirty
*/
void MarkViewportDirty(Viewport * const vp, int left, int top, int right, int bottom, ViewportMarkDirtyFlags flags)
{
/* Rounding wrt. zoom-out level */
right += (1 << vp->zoom) - 1;
bottom += (1 << vp->zoom) - 1;
right -= vp->virtual_left;
if (right <= 0) return;
right = std::min(right, vp->virtual_width);
bottom -= vp->virtual_top;
if (bottom <= 0) return;
bottom = std::min(bottom, vp->virtual_height);
left = std::max(0, left - vp->virtual_left);
if (left >= vp->virtual_width) return;
top = std::max(0, top - vp->virtual_top);
if (top >= vp->virtual_height) return;
uint x = std::max<int>(0, UnScaleByZoomLower(left, vp->zoom) - vp->dirty_block_left_margin) >> vp->GetDirtyBlockWidthShift();
uint y = UnScaleByZoomLower(top, vp->zoom) >> vp->GetDirtyBlockHeightShift();
uint w = (std::max<int>(0, UnScaleByZoomLower(right, vp->zoom) - 1 - vp->dirty_block_left_margin) >> vp->GetDirtyBlockWidthShift()) + 1 - x;
uint h = ((UnScaleByZoom(bottom, vp->zoom) - 1) >> vp->GetDirtyBlockHeightShift()) + 1 - y;
uint column_skip = vp->dirty_blocks_per_column - h;
uint pos = (x * vp->dirty_blocks_per_column) + y;
for (uint i = 0; i < w; i++) {
for (uint j = 0; j < h; j++) {
vp->dirty_blocks[pos] = true;
pos++;
}
pos += column_skip;
}
vp->is_dirty = true;
if (unlikely(vp->zoom >= ZOOM_LVL_DRAW_MAP && !(flags & VMDF_NOT_LANDSCAPE))) {
uint l = UnScaleByZoomLower(left, vp->zoom);
uint t = UnScaleByZoomLower(top, vp->zoom);
uint w = UnScaleByZoom(right, vp->zoom) - l;
uint h = UnScaleByZoom(bottom, vp->zoom) - t;
uint bitdepth = BlitterFactory::GetCurrentBlitter()->GetScreenDepth() / 8;
uint8 *land_cache = vp->land_pixel_cache.data() + ((l + (t * vp->width)) * bitdepth);
while (--h) {
memset(land_cache, 0xD7, w * bitdepth);
land_cache += vp->width * bitdepth;
}
}
}
/**
* Mark all viewports that display an area as dirty (in need of repaint).
* @param left Left edge of area to repaint. (viewport coordinates, that is wrt. #ZOOM_LVL_NORMAL)
* @param top Top edge of area to repaint. (viewport coordinates, that is wrt. #ZOOM_LVL_NORMAL)
* @param right Right edge of area to repaint. (viewport coordinates, that is wrt. #ZOOM_LVL_NORMAL)
* @param bottom Bottom edge of area to repaint. (viewport coordinates, that is wrt. #ZOOM_LVL_NORMAL)
* @param flags To tell if an update is relevant or not (for example, animations in map mode are not)
* @ingroup dirty
*/
void MarkAllViewportsDirty(int left, int top, int right, int bottom, ViewportMarkDirtyFlags flags)
{
for (uint i = 0; i < _viewport_window_cache.size(); i++) {
if (flags & VMDF_NOT_MAP_MODE && _viewport_window_cache[i]->zoom >= ZOOM_LVL_DRAW_MAP) continue;
const Rect &r = _viewport_coverage_rects[i];
if (left >= r.right ||
right <= r.left ||
top >= r.bottom ||
bottom <= r.top) {
continue;
}
MarkViewportDirty(_viewport_window_cache[i], left, top, right, bottom, flags);
}
}
static void MarkRouteStepDirty(RouteStepsMap::const_iterator cit)
{
const uint size = cit->second.size() > max_rank_order_type_count ? 1 : (uint)cit->second.size();
MarkRouteStepDirty(cit->first, size);
}
static void MarkRouteStepDirty(const TileIndex tile, uint order_nr)
{
assert(tile != INVALID_TILE);
const Point pt = RemapCoords2(TileX(tile) * TILE_SIZE + TILE_SIZE / 2, TileY(tile) * TILE_SIZE + TILE_SIZE / 2);
const int char_height = GetCharacterHeight(FS_SMALL) + 1;
for (Viewport * const vp : _viewport_window_cache) {
const int half_width = ScaleByZoom((_vp_route_step_width / 2) + 1, vp->zoom);
const int height = ScaleByZoom(_vp_route_step_height_top + char_height * order_nr + _vp_route_step_height_bottom, vp->zoom);
MarkViewportDirty(vp, pt.x - half_width, pt.y - height, pt.x + half_width, pt.y, VMDF_NOT_LANDSCAPE);
}
}
void MarkAllRouteStepsDirty(const Vehicle *veh)
{
ViewportPrepareVehicleRouteSteps(veh);
for (RouteStepsMap::const_iterator cit = _vp_route_steps.begin(); cit != _vp_route_steps.end(); cit++) {
MarkRouteStepDirty(cit);
}
_vp_route_steps_last_mark_dirty.swap(_vp_route_steps);
_vp_route_steps.clear();
}
/**
* Mark all viewports in map mode that display an area as dirty (in need of repaint).
* @param left Left edge of area to repaint
* @param top Top edge of area to repaint
* @param right Right edge of area to repaint
* @param bottom Bottom edge of area to repaint
* @ingroup dirty
*/
void MarkAllViewportMapsDirty(int left, int top, int right, int bottom)
{
for (Window *w : Window::IterateFromBack()) {
Viewport *vp = w->viewport;
if (vp != nullptr && vp->zoom >= ZOOM_LVL_DRAW_MAP) {
MarkViewportDirty(vp, left, top, right, bottom, VMDF_NOT_LANDSCAPE);
}
}
}
void MarkAllViewportMapLandscapesDirty()
{
for (Window *w : Window::IterateFromBack()) {
Viewport *vp = w->viewport;
if (vp != nullptr && vp->zoom >= ZOOM_LVL_DRAW_MAP) {
ClearViewportLandPixelCache(vp);
w->SetDirty();
}
}
}
void MarkWholeNonMapViewportsDirty()
{
for (Window *w : Window::IterateFromBack()) {
Viewport *vp = w->viewport;
if (vp != nullptr && vp->zoom < ZOOM_LVL_DRAW_MAP) {
w->SetDirty();
}
}
}
/**
* Mark all viewport overlays for a specific station dirty (in need of repaint).
* @param st Station
* @ingroup dirty
*/
void MarkAllViewportOverlayStationLinksDirty(const Station *st)
{
for (Window *w : Window::IterateFromBack()) {
Viewport *vp = w->viewport;
if (vp != nullptr && vp->overlay != nullptr) {
vp->overlay->MarkStationViewportLinksDirty(st);
}
}
}
void ConstrainAllViewportsZoom()
{
for (Window *w : Window::IterateFromFront()) {
if (w->viewport == nullptr) continue;
ZoomLevel zoom = static_cast<ZoomLevel>(Clamp(w->viewport->zoom, _settings_client.gui.zoom_min, _settings_client.gui.zoom_max));
if (zoom != w->viewport->zoom) {
while (w->viewport->zoom < zoom) DoZoomInOutWindow(ZOOM_OUT, w);
while (w->viewport->zoom > zoom) DoZoomInOutWindow(ZOOM_IN, w);
}
}
}
/**
* Mark a tile given by its index dirty for repaint.
* @param tile The tile to mark dirty.
* @param flags To tell if an update is relevant or not (for example, animations in map mode are not).
* @param bridge_level_offset Height of bridge on tile to also mark dirty. (Height level relative to north corner.)
* @param tile_height_override Height of the tile (#TileHeight).
* @ingroup dirty
*/
void MarkTileDirtyByTile(TileIndex tile, ViewportMarkDirtyFlags flags, int bridge_level_offset, int tile_height_override)
{
Point pt = RemapCoords(TileX(tile) * TILE_SIZE, TileY(tile) * TILE_SIZE, tile_height_override * TILE_HEIGHT);
MarkAllViewportsDirty(
pt.x - 31 * ZOOM_LVL_BASE,
pt.y - 122 * ZOOM_LVL_BASE - ZOOM_LVL_BASE * TILE_HEIGHT * bridge_level_offset,
pt.x - 31 * ZOOM_LVL_BASE + 67 * ZOOM_LVL_BASE,
pt.y - 122 * ZOOM_LVL_BASE + 154 * ZOOM_LVL_BASE,
flags
);
}
void MarkTileGroundDirtyByTile(TileIndex tile, ViewportMarkDirtyFlags flags)
{
int x = TileX(tile) * TILE_SIZE;
int y = TileY(tile) * TILE_SIZE;
Point top = RemapCoords(x, y, GetTileMaxPixelZ(tile));
Point bot = RemapCoords(x + TILE_SIZE, y + TILE_SIZE, GetTilePixelZ(tile));
MarkAllViewportsDirty(top.x - TILE_PIXELS * ZOOM_LVL_BASE, top.y - TILE_HEIGHT * ZOOM_LVL_BASE, top.x + TILE_PIXELS * ZOOM_LVL_BASE, bot.y, flags);
}
void MarkViewportLineDirty(Viewport * const vp, const Point from_pt, const Point to_pt, const int block_radius, ViewportMarkDirtyFlags flags)
{
int x1 = from_pt.x / block_radius;
int y1 = from_pt.y / block_radius;
const int x2 = to_pt.x / block_radius;
const int y2 = to_pt.y / block_radius;
/* http://en.wikipedia.org/wiki/Bresenham%27s_line_algorithm#Simplification */
const int dx = abs(x2 - x1);
const int dy = abs(y2 - y1);
const int sx = (x1 < x2) ? 1 : -1;
const int sy = (y1 < y2) ? 1 : -1;
int err = dx - dy;
for (;;) {
MarkViewportDirty(
vp,
(x1 - 2) * block_radius,
(y1 - 2) * block_radius,
(x1 + 2) * block_radius,
(y1 + 2) * block_radius,
flags
);
if (x1 == x2 && y1 == y2) break;
const int e2 = 2 * err;
if (e2 > -dy) {
err -= dy;
x1 += sx;
}
if (e2 < dx) {
err += dx;
y1 += sy;
}
}
}
void MarkTileLineDirty(const TileIndex from_tile, const TileIndex to_tile, ViewportMarkDirtyFlags flags)
{
assert(from_tile != INVALID_TILE);
assert(to_tile != INVALID_TILE);
const Point from_pt = RemapCoords2(TileX(from_tile) * TILE_SIZE + TILE_SIZE / 2, TileY(from_tile) * TILE_SIZE + TILE_SIZE / 2);
const Point to_pt = RemapCoords2(TileX(to_tile) * TILE_SIZE + TILE_SIZE / 2, TileY(to_tile) * TILE_SIZE + TILE_SIZE / 2);
for (Viewport * const vp : _viewport_window_cache) {
if (flags & VMDF_NOT_MAP_MODE && vp->zoom >= ZOOM_LVL_DRAW_MAP) continue;
const int block_shift = 2 + vp->zoom;
int x1 = from_pt.x >> block_shift;
int y1 = from_pt.y >> block_shift;
const int x2 = to_pt.x >> block_shift;
const int y2 = to_pt.y >> block_shift;
/* http://en.wikipedia.org/wiki/Bresenham%27s_line_algorithm#Simplification */
const int dx = abs(x2 - x1);
const int dy = abs(y2 - y1);
const int sx = (x1 < x2) ? 1 : -1;
const int sy = (y1 < y2) ? 1 : -1;
int err = dx - dy;
for (;;) {
MarkViewportDirty(
vp,
(x1 - 1) << block_shift,
(y1 - 1) << block_shift,
(x1 + 2) << block_shift,
(y1 + 2) << block_shift,
flags
);
if (x1 == x2 && y1 == y2) break;
const int e2 = 2 * err;
if (e2 > -dy) {
err -= dy;
x1 += sx;
}
if (e2 < dx) {
err += dx;
y1 += sy;
}
}
}
}
static void MarkRoutePathsDirty(const std::vector<DrawnPathRouteTileLine> &lines)
{
for (std::vector<DrawnPathRouteTileLine>::const_iterator it = lines.begin(); it != lines.end(); ++it) {
MarkTileLineDirty(it->from_tile, it->to_tile, VMDF_NOT_LANDSCAPE);
}
}
void MarkAllRoutePathsDirty(const Vehicle *veh)
{
switch (_settings_client.gui.show_vehicle_route) {
case 0: // No
return;
case 1: // Simple
ViewportMapPrepareVehicleRoute(veh);
break;
}
for (const auto &iter : _vp_route_paths) {
MarkTileLineDirty(iter.from_tile, iter.to_tile, VMDF_NOT_LANDSCAPE);
}
_vp_route_paths_last_mark_dirty.swap(_vp_route_paths);
_vp_route_paths.clear();
}
void CheckMarkDirtyFocusedRoutePaths(const Vehicle *veh)
{
const Vehicle *focused_veh = GetVehicleFromWindow(_focused_window);
if (focused_veh && veh == focused_veh) {
MarkAllRoutePathsDirty(veh);
MarkAllRouteStepsDirty(veh);
}
}
/**
* Marks the selected tiles as dirty.
*
* This function marks the selected tiles as dirty for repaint
*
* @ingroup dirty
*/
static void SetSelectionTilesDirty()
{
int x_size = _thd.size.x;
int y_size = _thd.size.y;
if (!_thd.diagonal) { // Selecting in a straight rectangle (or a single square)
int x_start = _thd.pos.x;
int y_start = _thd.pos.y;
if (_thd.outersize.x != 0 || _thd.outersize.y != 0) {
x_size += _thd.outersize.x;
x_start += _thd.offs.x;
y_size += _thd.outersize.y;
y_start += _thd.offs.y;
}
x_size -= TILE_SIZE;
y_size -= TILE_SIZE;
assert(x_size >= 0);
assert(y_size >= 0);
int x_end = Clamp(x_start + x_size, 0, MapSizeX() * TILE_SIZE - TILE_SIZE);
int y_end = Clamp(y_start + y_size, 0, MapSizeY() * TILE_SIZE - TILE_SIZE);
x_start = Clamp(x_start, 0, MapSizeX() * TILE_SIZE - TILE_SIZE);
y_start = Clamp(y_start, 0, MapSizeY() * TILE_SIZE - TILE_SIZE);
/* make sure everything is multiple of TILE_SIZE */
assert((x_end | y_end | x_start | y_start) % TILE_SIZE == 0);
/* How it works:
* Suppose we have to mark dirty rectangle of 3x4 tiles:
* x
* xxx
* xxxxx
* xxxxx
* xxx
* x
* This algorithm marks dirty columns of tiles, so it is done in 3+4-1 steps:
* 1) x 2) x
* xxx Oxx
* Oxxxx xOxxx
* xxxxx Oxxxx
* xxx xxx
* x x
* And so forth...
*/
int top_x = x_end; // coordinates of top dirty tile
int top_y = y_start;
int bot_x = top_x; // coordinates of bottom dirty tile
int bot_y = top_y;
do {
/* topmost dirty point */
TileIndex top_tile = TileVirtXY(top_x, top_y);
Point top = RemapCoords(top_x, top_y, GetTileMaxPixelZ(top_tile));
/* bottommost point */
TileIndex bottom_tile = TileVirtXY(bot_x, bot_y);
Point bot = RemapCoords(bot_x + TILE_SIZE, bot_y + TILE_SIZE, GetTilePixelZ(bottom_tile)); // bottommost point
/* the 'x' coordinate of 'top' and 'bot' is the same (and always in the same distance from tile middle),
* tile height/slope affects only the 'y' on-screen coordinate! */
int l = top.x - TILE_PIXELS * ZOOM_LVL_BASE; // 'x' coordinate of left side of the dirty rectangle
int t = top.y; // 'y' coordinate of top side of the dirty rectangle
int r = top.x + TILE_PIXELS * ZOOM_LVL_BASE; // 'x' coordinate of right side of the dirty rectangle
int b = bot.y; // 'y' coordinate of bottom side of the dirty rectangle
static const int OVERLAY_WIDTH = 4 * ZOOM_LVL_BASE; // part of selection sprites is drawn outside the selected area (in particular: terraforming)
/* For halftile foundations on SLOPE_STEEP_S the sprite extents some more towards the top */
MarkAllViewportsDirty(l - OVERLAY_WIDTH, t - OVERLAY_WIDTH - TILE_HEIGHT * ZOOM_LVL_BASE, r + OVERLAY_WIDTH, b + OVERLAY_WIDTH, VMDF_NOT_MAP_MODE);
/* haven't we reached the topmost tile yet? */
if (top_x != x_start) {
top_x -= TILE_SIZE;
} else {
top_y += TILE_SIZE;
}
/* the way the bottom tile changes is different when we reach the bottommost tile */
if (bot_y != y_end) {
bot_y += TILE_SIZE;
} else {
bot_x -= TILE_SIZE;
}
} while (bot_x >= top_x);
} else { // Selecting in a 45 degrees rotated (diagonal) rectangle.
/* a_size, b_size describe a rectangle with rotated coordinates */
int a_size = x_size + y_size, b_size = x_size - y_size;
int interval_a = a_size < 0 ? -(int)TILE_SIZE : (int)TILE_SIZE;
int interval_b = b_size < 0 ? -(int)TILE_SIZE : (int)TILE_SIZE;
for (int a = -interval_a; a != a_size + interval_a; a += interval_a) {
for (int b = -interval_b; b != b_size + interval_b; b += interval_b) {
uint x = (_thd.pos.x + (a + b) / 2) / TILE_SIZE;
uint y = (_thd.pos.y + (a - b) / 2) / TILE_SIZE;
if (x < MapMaxX() && y < MapMaxY()) {
MarkTileDirtyByTile(TileXY(x, y), VMDF_NOT_MAP_MODE);
}
}
}
}
}
void SetSelectionRed(bool b)
{
_thd.make_square_red = b;
SetSelectionTilesDirty();
}
/**
* Test whether a sign is below the mouse
* @param vp the clicked viewport
* @param x X position of click
* @param y Y position of click
* @param sign the sign to check
* @return true if the sign was hit
*/
static bool CheckClickOnViewportSign(const Viewport *vp, int x, int y, const ViewportSign *sign)
{
bool small = (vp->zoom >= ZOOM_LVL_OUT_16X);
int sign_half_width = ScaleByZoom((small ? sign->width_small : sign->width_normal) / 2, vp->zoom);
int sign_height = ScaleByZoom(VPSM_TOP + (small ? FONT_HEIGHT_SMALL : FONT_HEIGHT_NORMAL) + VPSM_BOTTOM, vp->zoom);
return y >= sign->top && y < sign->top + sign_height &&
x >= sign->center - sign_half_width && x < sign->center + sign_half_width;
}
/**
* Check whether any viewport sign was clicked, and dispatch the click.
* @param vp the clicked viewport
* @param x X position of click
* @param y Y position of click
* @return true if the sign was hit
*/
static bool CheckClickOnViewportSign(const Viewport *vp, int x, int y)
{
if (_game_mode == GM_MENU) return false;
x = ScaleByZoom(x - vp->left, vp->zoom) + vp->virtual_left;
y = ScaleByZoom(y - vp->top, vp->zoom) + vp->virtual_top;
Rect search_rect{ x - 1, y - 1, x + 1, y + 1 };
search_rect = ExpandRectWithViewportSignMargins(search_rect, vp->zoom);
bool show_stations = HasBit(_display_opt, DO_SHOW_STATION_NAMES) && !IsInvisibilitySet(TO_SIGNS);
bool show_waypoints = HasBit(_display_opt, DO_SHOW_WAYPOINT_NAMES) && !IsInvisibilitySet(TO_SIGNS);
bool show_towns = HasBit(_display_opt, DO_SHOW_TOWN_NAMES);
bool show_signs = HasBit(_display_opt, DO_SHOW_SIGNS) && !IsInvisibilitySet(TO_SIGNS);
bool show_competitors = HasBit(_display_opt, DO_SHOW_COMPETITOR_SIGNS);
/* Topmost of each type that was hit */
BaseStation *st = nullptr, *last_st = nullptr;
Town *t = nullptr, *last_t = nullptr;
Sign *si = nullptr, *last_si = nullptr;
/* See ViewportAddKdtreeSigns() for details on the search logic */
_viewport_sign_kdtree.FindContained(search_rect.left, search_rect.top, search_rect.right, search_rect.bottom, [&](const ViewportSignKdtreeItem & item) {
switch (item.type) {
case ViewportSignKdtreeItem::VKI_STATION:
if (!show_stations) break;
st = BaseStation::Get(item.id.station);
if (!show_competitors && _local_company != st->owner && st->owner != OWNER_NONE) break;
if (CheckClickOnViewportSign(vp, x, y, &st->sign)) last_st = st;
break;
case ViewportSignKdtreeItem::VKI_WAYPOINT:
if (!show_waypoints) break;
st = BaseStation::Get(item.id.station);
if (!show_competitors && _local_company != st->owner && st->owner != OWNER_NONE) break;
if (CheckClickOnViewportSign(vp, x, y, &st->sign)) last_st = st;
break;
case ViewportSignKdtreeItem::VKI_TOWN:
if (!show_towns) break;
t = Town::Get(item.id.town);
if (CheckClickOnViewportSign(vp, x, y, &t->cache.sign)) last_t = t;
break;
case ViewportSignKdtreeItem::VKI_SIGN:
if (!show_signs) break;
si = Sign::Get(item.id.sign);
if (!show_competitors && _local_company != si->owner && si->owner != OWNER_DEITY) break;
if (CheckClickOnViewportSign(vp, x, y, &si->sign)) last_si = si;
break;
default:
NOT_REACHED();
}
});
/* Select which hit to handle based on priority */
if (last_st != nullptr) {
if (Station::IsExpected(last_st)) {
ShowStationViewWindow(last_st->index);
} else {
ShowWaypointWindow(Waypoint::From(last_st));
}
return true;
} else if (last_t != nullptr) {
ShowTownViewWindow(last_t->index);
return true;
} else if (last_si != nullptr) {
HandleClickOnSign(last_si);
return true;
} else {
return false;
}
}
ViewportSignKdtreeItem ViewportSignKdtreeItem::MakeStation(StationID id)
{
ViewportSignKdtreeItem item;
item.type = VKI_STATION;
item.id.station = id;
const Station *st = Station::Get(id);
assert(st->sign.kdtree_valid);
item.center = st->sign.center;
item.top = st->sign.top;
/* Assume the sign can be a candidate for drawing, so measure its width */
_viewport_sign_maxwidth = std::max<int>(_viewport_sign_maxwidth, st->sign.width_normal);
return item;
}
ViewportSignKdtreeItem ViewportSignKdtreeItem::MakeWaypoint(StationID id)
{
ViewportSignKdtreeItem item;
item.type = VKI_WAYPOINT;
item.id.station = id;
const Waypoint *st = Waypoint::Get(id);
assert(st->sign.kdtree_valid);
item.center = st->sign.center;
item.top = st->sign.top;
/* Assume the sign can be a candidate for drawing, so measure its width */
_viewport_sign_maxwidth = std::max<int>(_viewport_sign_maxwidth, st->sign.width_normal);
return item;
}
ViewportSignKdtreeItem ViewportSignKdtreeItem::MakeTown(TownID id)
{
ViewportSignKdtreeItem item;
item.type = VKI_TOWN;
item.id.town = id;
const Town *town = Town::Get(id);
assert(town->cache.sign.kdtree_valid);
item.center = town->cache.sign.center;
item.top = town->cache.sign.top;
/* Assume the sign can be a candidate for drawing, so measure its width */
_viewport_sign_maxwidth = std::max<int>(_viewport_sign_maxwidth, town->cache.sign.width_normal);
return item;
}
ViewportSignKdtreeItem ViewportSignKdtreeItem::MakeSign(SignID id)
{
ViewportSignKdtreeItem item;
item.type = VKI_SIGN;
item.id.sign = id;
const Sign *sign = Sign::Get(id);
assert(sign->sign.kdtree_valid);
item.center = sign->sign.center;
item.top = sign->sign.top;
/* Assume the sign can be a candidate for drawing, so measure its width */
_viewport_sign_maxwidth = std::max<int>(_viewport_sign_maxwidth, sign->sign.width_normal);
return item;
}
void RebuildViewportKdtree()
{
/* Reset biggest size sign seen */
_viewport_sign_maxwidth = 0;
if (_network_dedicated) {
_viewport_sign_kdtree_valid = false;
_viewport_sign_kdtree.Build<ViewportSignKdtreeItem*>(nullptr, nullptr);
return;
}
_viewport_sign_kdtree_valid = true;
std::vector<ViewportSignKdtreeItem> items;
items.reserve(BaseStation::GetNumItems() + Town::GetNumItems() + Sign::GetNumItems());
for (const Station *st : Station::Iterate()) {
if (st->sign.kdtree_valid) items.push_back(ViewportSignKdtreeItem::MakeStation(st->index));
}
for (const Waypoint *wp : Waypoint::Iterate()) {
if (wp->sign.kdtree_valid) items.push_back(ViewportSignKdtreeItem::MakeWaypoint(wp->index));
}
for (const Town *town : Town::Iterate()) {
if (town->cache.sign.kdtree_valid) items.push_back(ViewportSignKdtreeItem::MakeTown(town->index));
}
for (const Sign *sign : Sign::Iterate()) {
if (sign->sign.kdtree_valid) items.push_back(ViewportSignKdtreeItem::MakeSign(sign->index));
}
_viewport_sign_kdtree.Build(items.begin(), items.end());
}
static bool CheckClickOnLandscape(const Viewport *vp, int x, int y)
{
Point pt = TranslateXYToTileCoord(vp, x, y);
_tile_fract_coords.x = pt.x & TILE_UNIT_MASK;
_tile_fract_coords.y = pt.y & TILE_UNIT_MASK;
if (pt.x != -1) return ClickTile(TileVirtXY(pt.x, pt.y));
return true;
}
static void PlaceObject()
{
Point pt;
Window *w;
pt = GetTileBelowCursor();
if (pt.x == -1) return;
if ((_thd.place_mode & HT_DRAG_MASK) == HT_POINT) {
pt.x += TILE_SIZE / 2;
pt.y += TILE_SIZE / 2;
}
_tile_fract_coords.x = pt.x & TILE_UNIT_MASK;
_tile_fract_coords.y = pt.y & TILE_UNIT_MASK;
w = _thd.GetCallbackWnd();
if (w != nullptr) w->OnPlaceObject(pt, TileVirtXY(pt.x, pt.y));
}
bool HandleViewportDoubleClicked(Window *w, int x, int y)
{
Viewport *vp = w->viewport;
if (vp->zoom < ZOOM_LVL_DRAW_MAP) return false;
switch (_settings_client.gui.action_when_viewport_map_is_dblclicked) {
case 0: // Do nothing
return false;
case 1: // Zoom in main viewport
while (vp->zoom != ZOOM_LVL_VIEWPORT)
ZoomInOrOutToCursorWindow(true, w);
return true;
case 2: // Open an extra viewport
ShowExtraViewportWindowForTileUnderCursor();
return true;
default:
return false;
}
}
HandleViewportClickedResult HandleViewportClicked(const Viewport *vp, int x, int y, bool double_click)
{
/* No click in smallmap mode except for plan making and left-button scrolling. */
if (vp->zoom >= ZOOM_LVL_DRAW_MAP && !(_thd.place_mode & HT_MAP)) return HVCR_SCROLL_ONLY;
const Vehicle *v = CheckClickOnVehicle(vp, x, y);
if (_thd.place_mode & HT_VEHICLE) {
if (v != nullptr && VehicleClicked(v)) return HVCR_DENY;
}
/* Vehicle placement mode already handled above. */
if ((_thd.place_mode & HT_DRAG_MASK) != HT_NONE) {
if (_thd.place_mode & HT_POLY) {
/* In polyline mode double-clicking on a single white line, finishes current polyline.
* If however the user double-clicks on a line that has a white and a blue section,
* both lines (white and blue) will be constructed consecutively. */
static bool stop_snap_on_double_click = false;
if (double_click && stop_snap_on_double_click) {
SetRailSnapMode(RSM_NO_SNAP);
HideMeasurementTooltips();
return HVCR_DENY;
}
stop_snap_on_double_click = !(_thd.drawstyle & HT_LINE) || (_thd.dir2 == HT_DIR_END);
}
PlaceObject();
return HVCR_DENY;
}
if (vp->zoom >= ZOOM_LVL_DRAW_MAP) return HVCR_SCROLL_ONLY;
if (CheckClickOnViewportSign(vp, x, y)) return HVCR_DENY;
bool result = CheckClickOnLandscape(vp, x, y);
if (v != nullptr) {
DEBUG(misc, 2, "Vehicle %d (index %d) at %p", v->unitnumber, v->index, v);
if (IsCompanyBuildableVehicleType(v)) {
v = v->First();
WindowClass wc = _thd.GetCallbackWnd()->window_class;
if (_ctrl_pressed && v->owner == _local_company) {
StartStopVehicle(v, true);
} else if (wc != WC_CREATE_TEMPLATE && wc != WC_TEMPLATEGUI_MAIN) {
ShowVehicleViewWindow(v);
}
}
return HVCR_DENY;
}
return result ? HVCR_DENY : HVCR_ALLOW;
}
void RebuildViewportOverlay(Window *w, bool incremental)
{
if (w->viewport->overlay != nullptr &&
w->viewport->overlay->GetCompanyMask() != 0 &&
w->viewport->overlay->GetCargoMask() != 0) {
w->viewport->overlay->RebuildCache(incremental);
if (!incremental) w->SetDirty();
}
}
bool IsViewportOverlayOutsideCachedRegion(Window *w)
{
if (w->viewport->overlay != nullptr &&
w->viewport->overlay->GetCompanyMask() != 0 &&
w->viewport->overlay->GetCargoMask() != 0) {
return !w->viewport->overlay->CacheStillValid();
} else {
return false;
}
}
/**
* Scrolls the viewport in a window to a given location.
* @param x Desired x location of the map to scroll to (world coordinate).
* @param y Desired y location of the map to scroll to (world coordinate).
* @param z Desired z location of the map to scroll to (world coordinate). Use \c -1 to scroll to the height of the map at the \a x, \a y location.
* @param w %Window containing the viewport.
* @param instant Jump to the location instead of slowly moving to it.
* @return Destination of the viewport was changed (to activate other actions when the viewport is already at the desired position).
*/
bool ScrollWindowTo(int x, int y, int z, Window *w, bool instant)
{
/* The slope cannot be acquired outside of the map, so make sure we are always within the map. */
if (z == -1) {
if ( x >= 0 && x <= (int)MapSizeX() * (int)TILE_SIZE - 1
&& y >= 0 && y <= (int)MapSizeY() * (int)TILE_SIZE - 1) {
z = GetSlopePixelZ(x, y);
} else {
z = TileHeightOutsideMap(x / (int)TILE_SIZE, y / (int)TILE_SIZE);
}
}
Point pt = MapXYZToViewport(w->viewport, x, y, z);
w->viewport->follow_vehicle = INVALID_VEHICLE;
if (w->viewport->dest_scrollpos_x == pt.x && w->viewport->dest_scrollpos_y == pt.y) return false;
if (instant) {
w->viewport->scrollpos_x = pt.x;
w->viewport->scrollpos_y = pt.y;
RebuildViewportOverlay(w, true);
}
w->viewport->dest_scrollpos_x = pt.x;
w->viewport->dest_scrollpos_y = pt.y;
return true;
}
/**
* Scrolls the viewport in a window to a given location.
* @param tile Desired tile to center on.
* @param w %Window containing the viewport.
* @param instant Jump to the location instead of slowly moving to it.
* @return Destination of the viewport was changed (to activate other actions when the viewport is already at the desired position).
*/
bool ScrollWindowToTile(TileIndex tile, Window *w, bool instant)
{
return ScrollWindowTo(TileX(tile) * TILE_SIZE, TileY(tile) * TILE_SIZE, -1, w, instant);
}
/**
* Scrolls the viewport of the main window to a given location.
* @param tile Desired tile to center on.
* @param instant Jump to the location instead of slowly moving to it.
* @return Destination of the viewport was changed (to activate other actions when the viewport is already at the desired position).
*/
bool ScrollMainWindowToTile(TileIndex tile, bool instant)
{
return ScrollMainWindowTo(TileX(tile) * TILE_SIZE + TILE_SIZE / 2, TileY(tile) * TILE_SIZE + TILE_SIZE / 2, -1, instant);
}
/**
* Set a tile to display a red error square.
* @param tile Tile that should show the red error square.
*/
void SetRedErrorSquare(TileIndex tile)
{
TileIndex old;
old = _thd.redsq;
_thd.redsq = tile;
if (tile != old) {
if (tile != INVALID_TILE) MarkTileDirtyByTile(tile, VMDF_NOT_MAP_MODE);
if (old != INVALID_TILE) MarkTileDirtyByTile(old, VMDF_NOT_MAP_MODE);
}
}
/**
* Highlight \a w by \a h tiles at the cursor.
* @param w Width of the highlighted tiles rectangle.
* @param h Height of the highlighted tiles rectangle.
*/
void SetTileSelectSize(int w, int h)
{
_thd.new_size.x = w * TILE_SIZE;
_thd.new_size.y = h * TILE_SIZE;
_thd.new_outersize.x = 0;
_thd.new_outersize.y = 0;
}
void SetTileSelectBigSize(int ox, int oy, int sx, int sy)
{
_thd.new_offs.x = ox * TILE_SIZE;
_thd.new_offs.y = oy * TILE_SIZE;
_thd.new_outersize.x = sx * TILE_SIZE;
_thd.new_outersize.y = sy * TILE_SIZE;
}
/** returns the best autorail highlight type from map coordinates */
static HighLightStyle GetAutorailHT(int x, int y)
{
return HT_RAIL | _autorail_piece[x & TILE_UNIT_MASK][y & TILE_UNIT_MASK];
}
/**
* Reset tile highlighting.
*/
void TileHighlightData::Reset()
{
this->pos.x = 0;
this->pos.y = 0;
this->new_pos.x = 0;
this->new_pos.y = 0;
}
/**
* Is the user dragging a 'diagonal rectangle'?
* @return User is dragging a rotated rectangle.
*/
bool TileHighlightData::IsDraggingDiagonal()
{
return (this->place_mode & HT_DIAGONAL) != 0 && _ctrl_pressed && _left_button_down;
}
/**
* Get the window that started the current highlighting.
* @return The window that requested the current tile highlighting, or \c nullptr if not available.
*/
Window *TileHighlightData::GetCallbackWnd()
{
return FindWindowById(this->window_class, this->window_number);
}
static HighLightStyle CalcPolyrailDrawstyle(Point pt, bool dragging);
static inline void CalcNewPolylineOutersize()
{
/* use the 'outersize' to mark the second (blue) part of a polyline selection */
if (_thd.dir2 < HT_DIR_END) {
/* get bounds of the second part */
int outer_x1 = _thd.selstart2.x & ~TILE_UNIT_MASK;
int outer_y1 = _thd.selstart2.y & ~TILE_UNIT_MASK;
int outer_x2 = _thd.selend2.x & ~TILE_UNIT_MASK;
int outer_y2 = _thd.selend2.y & ~TILE_UNIT_MASK;
if (outer_x1 > outer_x2) Swap(outer_x1, outer_x2);
if (outer_y1 > outer_y2) Swap(outer_y1, outer_y2);
/* include the first part */
outer_x1 = std::min<int>(outer_x1, _thd.new_pos.x);
outer_y1 = std::min<int>(outer_y1, _thd.new_pos.y);
outer_x2 = std::max<int>(outer_x2, _thd.new_pos.x + _thd.new_size.x - TILE_SIZE);
outer_y2 = std::max<int>(outer_y2, _thd.new_pos.y + _thd.new_size.y - TILE_SIZE);
/* write new values */
_thd.new_offs.x = outer_x1 - _thd.new_pos.x;
_thd.new_offs.y = outer_y1 - _thd.new_pos.y;
_thd.new_outersize.x = outer_x2 - outer_x1 + TILE_SIZE - _thd.new_size.x;
_thd.new_outersize.y = outer_y2 - outer_y1 + TILE_SIZE - _thd.new_size.y;
} else {
_thd.new_offs.x = 0;
_thd.new_offs.y = 0;
_thd.new_outersize.x = 0;
_thd.new_outersize.y = 0;
}
}
/**
* Updates tile highlighting for all cases.
* Uses _thd.selstart and _thd.selend and _thd.place_mode (set elsewhere) to determine _thd.pos and _thd.size
* Also drawstyle is determined. Uses _thd.new.* as a buffer and calls SetSelectionTilesDirty() twice,
* Once for the old and once for the new selection.
* _thd is TileHighlightData, found in viewport.h
*/
void UpdateTileSelection()
{
int x1;
int y1;
if (_thd.freeze) return;
HighLightStyle new_drawstyle = HT_NONE;
bool new_diagonal = false;
if ((_thd.place_mode & HT_DRAG_MASK) == HT_SPECIAL) {
x1 = _thd.selend.x;
y1 = _thd.selend.y;
if (x1 != -1) {
int x2 = _thd.selstart.x & ~TILE_UNIT_MASK;
int y2 = _thd.selstart.y & ~TILE_UNIT_MASK;
x1 &= ~TILE_UNIT_MASK;
y1 &= ~TILE_UNIT_MASK;
if (_thd.IsDraggingDiagonal()) {
new_diagonal = true;
} else {
if (x1 >= x2) Swap(x1, x2);
if (y1 >= y2) Swap(y1, y2);
}
_thd.new_pos.x = x1;
_thd.new_pos.y = y1;
_thd.new_size.x = x2 - x1;
_thd.new_size.y = y2 - y1;
if (!new_diagonal) {
_thd.new_size.x += TILE_SIZE;
_thd.new_size.y += TILE_SIZE;
}
new_drawstyle = _thd.next_drawstyle;
}
} else if ((_thd.place_mode & HT_DRAG_MASK) != HT_NONE) {
Point pt = GetTileBelowCursor();
x1 = pt.x;
y1 = pt.y;
if (x1 != -1) {
switch (_thd.place_mode & HT_DRAG_MASK) {
case HT_RECT:
new_drawstyle = HT_RECT;
break;
case HT_POINT:
new_drawstyle = HT_POINT;
x1 += TILE_SIZE / 2;
y1 += TILE_SIZE / 2;
break;
case HT_RAIL:
case HT_LINE:
/* HT_POLY */
if (_thd.place_mode & HT_POLY) {
RailSnapMode snap_mode = GetRailSnapMode();
if (snap_mode == RSM_NO_SNAP ||
(snap_mode == RSM_SNAP_TO_TILE && GetRailSnapTile() == TileVirtXY(pt.x, pt.y))) {
new_drawstyle = GetAutorailHT(pt.x, pt.y);
_thd.new_offs.x = 0;
_thd.new_offs.y = 0;
_thd.new_outersize.x = 0;
_thd.new_outersize.y = 0;
_thd.dir2 = HT_DIR_END;
} else {
new_drawstyle = CalcPolyrailDrawstyle(pt, false);
if (new_drawstyle != HT_NONE) {
x1 = _thd.selstart.x & ~TILE_UNIT_MASK;
y1 = _thd.selstart.y & ~TILE_UNIT_MASK;
int x2 = _thd.selend.x & ~TILE_UNIT_MASK;
int y2 = _thd.selend.y & ~TILE_UNIT_MASK;
if (x1 > x2) Swap(x1, x2);
if (y1 > y2) Swap(y1, y2);
_thd.new_pos.x = x1;
_thd.new_pos.y = y1;
_thd.new_size.x = x2 - x1 + TILE_SIZE;
_thd.new_size.y = y2 - y1 + TILE_SIZE;
}
}
break;
}
/* HT_RAIL */
if (_thd.place_mode & HT_RAIL) {
/* Draw one highlighted tile in any direction */
new_drawstyle = GetAutorailHT(pt.x, pt.y);
break;
}
/* HT_LINE */
switch (_thd.place_mode & HT_DIR_MASK) {
case HT_DIR_X: new_drawstyle = HT_LINE | HT_DIR_X; break;
case HT_DIR_Y: new_drawstyle = HT_LINE | HT_DIR_Y; break;
case HT_DIR_HU:
case HT_DIR_HL:
new_drawstyle = (pt.x & TILE_UNIT_MASK) + (pt.y & TILE_UNIT_MASK) <= TILE_SIZE ? HT_LINE | HT_DIR_HU : HT_LINE | HT_DIR_HL;
break;
case HT_DIR_VL:
case HT_DIR_VR:
new_drawstyle = (pt.x & TILE_UNIT_MASK) > (pt.y & TILE_UNIT_MASK) ? HT_LINE | HT_DIR_VL : HT_LINE | HT_DIR_VR;
break;
default: NOT_REACHED();
}
_thd.selstart.x = x1 & ~TILE_UNIT_MASK;
_thd.selstart.y = y1 & ~TILE_UNIT_MASK;
_thd.selend.x = x1;
_thd.selend.y = y1;
break;
default:
NOT_REACHED();
}
_thd.new_pos.x = x1 & ~TILE_UNIT_MASK;
_thd.new_pos.y = y1 & ~TILE_UNIT_MASK;
}
}
if (new_drawstyle & HT_LINE) CalcNewPolylineOutersize();
/* redraw selection */
if (_thd.drawstyle != new_drawstyle ||
_thd.pos.x != _thd.new_pos.x || _thd.pos.y != _thd.new_pos.y ||
_thd.size.x != _thd.new_size.x || _thd.size.y != _thd.new_size.y ||
_thd.offs.x != _thd.new_offs.x || _thd.offs.y != _thd.new_offs.y ||
_thd.outersize.x != _thd.new_outersize.x ||
_thd.outersize.y != _thd.new_outersize.y ||
_thd.diagonal != new_diagonal) {
/* Clear the old tile selection? */
if ((_thd.drawstyle & HT_DRAG_MASK) != HT_NONE) SetSelectionTilesDirty();
_thd.drawstyle = new_drawstyle;
_thd.pos = _thd.new_pos;
_thd.size = _thd.new_size;
_thd.offs = _thd.new_offs;
_thd.outersize = _thd.new_outersize;
_thd.diagonal = new_diagonal;
_thd.dirty = 0xff;
/* Draw the new tile selection? */
if ((new_drawstyle & HT_DRAG_MASK) != HT_NONE) SetSelectionTilesDirty();
}
}
/**
* Displays the measurement tooltips when selecting multiple tiles
* @param str String to be displayed
* @param paramcount number of params to deal with
* @param params (optional) up to 5 pieces of additional information that may be added to a tooltip
* @param close_cond Condition for closing this tooltip.
*/
static inline void ShowMeasurementTooltips(StringID str, uint paramcount, const uint64 params[], TooltipCloseCondition close_cond = TCC_EXIT_VIEWPORT)
{
if (!_settings_client.gui.measure_tooltip) return;
GuiShowTooltips(_thd.GetCallbackWnd(), str, paramcount, params, close_cond);
}
static void HideMeasurementTooltips()
{
DeleteWindowById(WC_TOOLTIPS, 0);
}
/** highlighting tiles while only going over them with the mouse */
void VpStartPlaceSizing(TileIndex tile, ViewportPlaceMethod method, ViewportDragDropSelectionProcess process)
{
_thd.select_method = method;
_thd.select_proc = process;
_thd.selend.x = TileX(tile) * TILE_SIZE;
_thd.selstart.x = TileX(tile) * TILE_SIZE;
_thd.selend.y = TileY(tile) * TILE_SIZE;
_thd.selstart.y = TileY(tile) * TILE_SIZE;
/* Needed so several things (road, autoroad, bridges, ...) are placed correctly.
* In effect, placement starts from the centre of a tile
*/
if (method == VPM_X_OR_Y || method == VPM_FIX_X || method == VPM_FIX_Y) {
_thd.selend.x += TILE_SIZE / 2;
_thd.selend.y += TILE_SIZE / 2;
_thd.selstart.x += TILE_SIZE / 2;
_thd.selstart.y += TILE_SIZE / 2;
}
HighLightStyle others = _thd.place_mode & ~(HT_DRAG_MASK | HT_DIR_MASK);
if ((_thd.place_mode & HT_DRAG_MASK) == HT_RECT) {
_thd.place_mode = HT_SPECIAL | others;
_thd.next_drawstyle = HT_RECT | others;
} else if (_thd.place_mode & (HT_RAIL | HT_LINE)) {
_thd.place_mode = HT_SPECIAL | others;
_thd.next_drawstyle = _thd.drawstyle | others;
_current_snap_lock.x = -1;
if ((_thd.place_mode & HT_POLY) != 0 && GetRailSnapMode() == RSM_NO_SNAP) {
SetRailSnapMode(RSM_SNAP_TO_TILE);
SetRailSnapTile(tile);
}
} else {
_thd.place_mode = HT_SPECIAL | others;
_thd.next_drawstyle = HT_POINT | others;
}
_special_mouse_mode = WSM_SIZING;
}
/** Drag over the map while holding the left mouse down. */
void VpStartDragging(ViewportDragDropSelectionProcess process)
{
_thd.select_method = VPM_X_AND_Y;
_thd.select_proc = process;
_thd.selstart.x = 0;
_thd.selstart.y = 0;
_thd.next_drawstyle = HT_RECT;
_special_mouse_mode = WSM_DRAGGING;
}
void VpSetPlaceSizingLimit(int limit)
{
_thd.sizelimit = limit;
}
/**
* Highlights all tiles between a set of two tiles. Used in dock and tunnel placement
* @param from TileIndex of the first tile to highlight
* @param to TileIndex of the last tile to highlight
*/
void VpSetPresizeRange(TileIndex from, TileIndex to)
{
uint64 distance = DistanceManhattan(from, to) + 1;
_thd.selend.x = TileX(to) * TILE_SIZE;
_thd.selend.y = TileY(to) * TILE_SIZE;
_thd.selstart.x = TileX(from) * TILE_SIZE;
_thd.selstart.y = TileY(from) * TILE_SIZE;
_thd.next_drawstyle = HT_RECT;
/* show measurement only if there is any length to speak of */
if (distance > 1) {
ShowMeasurementTooltips(STR_MEASURE_LENGTH, 1, &distance);
} else {
HideMeasurementTooltips();
}
}
static void VpStartPreSizing()
{
_thd.selend.x = -1;
_special_mouse_mode = WSM_PRESIZE;
}
/**
* returns information about the 2x1 piece to be build.
* The lower bits (0-3) are the track type.
*/
static HighLightStyle Check2x1AutoRail(int mode)
{
int fxpy = _tile_fract_coords.x + _tile_fract_coords.y;
int sxpy = (_thd.selend.x & TILE_UNIT_MASK) + (_thd.selend.y & TILE_UNIT_MASK);
int fxmy = _tile_fract_coords.x - _tile_fract_coords.y;
int sxmy = (_thd.selend.x & TILE_UNIT_MASK) - (_thd.selend.y & TILE_UNIT_MASK);
switch (mode) {
default: NOT_REACHED();
case 0: // end piece is lower right
if (fxpy >= 20 && sxpy <= 12) return HT_DIR_HL;
if (fxmy < -3 && sxmy > 3) return HT_DIR_VR;
return HT_DIR_Y;
case 1:
if (fxmy > 3 && sxmy < -3) return HT_DIR_VL;
if (fxpy <= 12 && sxpy >= 20) return HT_DIR_HU;
return HT_DIR_Y;
case 2:
if (fxmy > 3 && sxmy < -3) return HT_DIR_VL;
if (fxpy >= 20 && sxpy <= 12) return HT_DIR_HL;
return HT_DIR_X;
case 3:
if (fxmy < -3 && sxmy > 3) return HT_DIR_VR;
if (fxpy <= 12 && sxpy >= 20) return HT_DIR_HU;
return HT_DIR_X;
}
}
/**
* Check if the direction of start and end tile should be swapped based on
* the dragging-style. Default directions are:
* in the case of a line (HT_RAIL, HT_LINE): DIR_NE, DIR_NW, DIR_N, DIR_E
* in the case of a rect (HT_RECT, HT_POINT): DIR_S, DIR_E
* For example dragging a rectangle area from south to north should be swapped to
* north-south (DIR_S) to obtain the same results with less code. This is what
* the return value signifies.
* @param style HighLightStyle dragging style
* @param start_tile start tile of drag
* @param end_tile end tile of drag
* @return boolean value which when true means start/end should be swapped
*/
static bool SwapDirection(HighLightStyle style, TileIndex start_tile, TileIndex end_tile)
{
uint start_x = TileX(start_tile);
uint start_y = TileY(start_tile);
uint end_x = TileX(end_tile);
uint end_y = TileY(end_tile);
switch (style & HT_DRAG_MASK) {
case HT_RAIL:
case HT_LINE: return (end_x > start_x || (end_x == start_x && end_y > start_y));
case HT_RECT:
case HT_POINT: return (end_x != start_x && end_y < start_y);
default: NOT_REACHED();
}
return false;
}
/**
* Calculates height difference between one tile and another.
* Multiplies the result to suit the standard given by #TILE_HEIGHT_STEP.
*
* To correctly get the height difference we need the direction we are dragging
* in, as well as with what kind of tool we are dragging. For example a horizontal
* autorail tool that starts in bottom and ends at the top of a tile will need the
* maximum of SW, S and SE, N corners respectively. This is handled by the lookup table below
* See #_tileoffs_by_dir in map.cpp for the direction enums if you can't figure out the values yourself.
* @param style Highlighting style of the drag. This includes direction and style (autorail, rect, etc.)
* @param distance Number of tiles dragged, important for horizontal/vertical drags, ignored for others.
* @param start_tile Start tile of the drag operation.
* @param end_tile End tile of the drag operation.
* @return Height difference between two tiles. The tile measurement tool utilizes this value in its tooltip.
*/
static int CalcHeightdiff(HighLightStyle style, uint distance, TileIndex start_tile, TileIndex end_tile)
{
bool swap = SwapDirection(style, start_tile, end_tile);
uint h0, h1; // Start height and end height.
if (start_tile == end_tile) return 0;
if (swap) Swap(start_tile, end_tile);
switch (style & HT_DRAG_MASK) {
case HT_RECT: {
static const TileIndexDiffC heightdiff_area_by_dir[] = {
/* Start */ {1, 0}, /* Dragging east */ {0, 0}, // Dragging south
/* End */ {0, 1}, /* Dragging east */ {1, 1} // Dragging south
};
/* In the case of an area we can determine whether we were dragging south or
* east by checking the X-coordinates of the tiles */
byte style_t = (byte)(TileX(end_tile) > TileX(start_tile));
start_tile = TILE_ADD(start_tile, ToTileIndexDiff(heightdiff_area_by_dir[style_t]));
end_tile = TILE_ADD(end_tile, ToTileIndexDiff(heightdiff_area_by_dir[2 + style_t]));
FALLTHROUGH;
}
case HT_POINT:
h0 = TileHeight(start_tile);
h1 = TileHeight(end_tile);
break;
default: { // All other types, this is mostly only line/autorail
static const HighLightStyle flip_style_direction[] = {
HT_DIR_X, HT_DIR_Y, HT_DIR_HL, HT_DIR_HU, HT_DIR_VR, HT_DIR_VL
};
static const TileIndexDiffC heightdiff_line_by_dir[] = {
/* Start */ {1, 0}, {1, 1}, /* HT_DIR_X */ {0, 1}, {1, 1}, // HT_DIR_Y
/* Start */ {1, 0}, {0, 0}, /* HT_DIR_HU */ {1, 0}, {1, 1}, // HT_DIR_HL
/* Start */ {1, 0}, {1, 1}, /* HT_DIR_VL */ {0, 1}, {1, 1}, // HT_DIR_VR
/* Start */ {0, 1}, {0, 0}, /* HT_DIR_X */ {1, 0}, {0, 0}, // HT_DIR_Y
/* End */ {0, 1}, {0, 0}, /* HT_DIR_HU */ {1, 1}, {0, 1}, // HT_DIR_HL
/* End */ {1, 0}, {0, 0}, /* HT_DIR_VL */ {0, 0}, {0, 1}, // HT_DIR_VR
};
distance %= 2; // we're only interested if the distance is even or uneven
style &= HT_DIR_MASK;
/* To handle autorail, we do some magic to be able to use a lookup table.
* Firstly if we drag the other way around, we switch start&end, and if needed
* also flip the drag-position. Eg if it was on the left, and the distance is even
* that means the end, which is now the start is on the right */
if (swap && distance == 0) style = flip_style_direction[style];
/* Use lookup table for start-tile based on HighLightStyle direction */
byte style_t = style * 2;
assert(style_t < lengthof(heightdiff_line_by_dir) - 13);
h0 = TileHeight(TILE_ADD(start_tile, ToTileIndexDiff(heightdiff_line_by_dir[style_t])));
uint ht = TileHeight(TILE_ADD(start_tile, ToTileIndexDiff(heightdiff_line_by_dir[style_t + 1])));
h0 = std::max(h0, ht);
/* Use lookup table for end-tile based on HighLightStyle direction
* flip around side (lower/upper, left/right) based on distance */
if (distance == 0) style_t = flip_style_direction[style] * 2;
assert(style_t < lengthof(heightdiff_line_by_dir) - 13);
h1 = TileHeight(TILE_ADD(end_tile, ToTileIndexDiff(heightdiff_line_by_dir[12 + style_t])));
ht = TileHeight(TILE_ADD(end_tile, ToTileIndexDiff(heightdiff_line_by_dir[12 + style_t + 1])));
h1 = std::max(h1, ht);
break;
}
}
if (swap) Swap(h0, h1);
return (int)(h1 - h0) * TILE_HEIGHT_STEP;
}
static void ShowLengthMeasurement(HighLightStyle style, TileIndex start_tile, TileIndex end_tile, TooltipCloseCondition close_cond = TCC_EXIT_VIEWPORT, bool show_single_tile_length = false)
{
static const StringID measure_strings_length[] = {STR_NULL, STR_MEASURE_LENGTH, STR_MEASURE_LENGTH_HEIGHTDIFF};
if (_settings_client.gui.measure_tooltip) {
uint distance = DistanceManhattan(start_tile, end_tile) + 1;
byte index = 0;
uint64 params[2];
if (show_single_tile_length || distance != 1) {
int heightdiff = CalcHeightdiff(style, distance, start_tile, end_tile);
/* If we are showing a tooltip for horizontal or vertical drags,
* 2 tiles have a length of 1. To bias towards the ceiling we add
* one before division. It feels more natural to count 3 lengths as 2 */
if ((style & HT_DIR_MASK) != HT_DIR_X && (style & HT_DIR_MASK) != HT_DIR_Y) {
distance = CeilDiv(distance, 2);
}
params[index++] = distance;
if (heightdiff != 0) params[index++] = heightdiff;
}
ShowMeasurementTooltips(measure_strings_length[index], index, params, close_cond);
}
}
/**
* Check for underflowing the map.
* @param test the variable to test for underflowing
* @param other the other variable to update to keep the line
* @param mult the constant to multiply the difference by for \c other
*/
static void CheckUnderflow(int &test, int &other, int mult)
{
if (test >= 0) return;
other += mult * test;
test = 0;
}
/**
* Check for overflowing the map.
* @param test the variable to test for overflowing
* @param other the other variable to update to keep the line
* @param max the maximum value for the \c test variable
* @param mult the constant to multiply the difference by for \c other
*/
static void CheckOverflow(int &test, int &other, int max, int mult)
{
if (test <= max) return;
other += mult * (test - max);
test = max;
}
static const uint X_DIRS = (1 << DIR_NE) | (1 << DIR_SW);
static const uint Y_DIRS = (1 << DIR_SE) | (1 << DIR_NW);
static const uint HORZ_DIRS = (1 << DIR_W) | (1 << DIR_E);
//static const uint VERT_DIRS = (1 << DIR_N) | (1 << DIR_S);
Trackdir PointDirToTrackdir(const Point &pt, Direction dir)
{
Trackdir ret;
if (IsDiagonalDirection(dir)) {
ret = DiagDirToDiagTrackdir(DirToDiagDir(dir));
} else {
int x = pt.x & TILE_UNIT_MASK;
int y = pt.y & TILE_UNIT_MASK;
int ns = x + y;
int we = y - x;
if (HasBit(HORZ_DIRS, dir)) {
ret = TrackDirectionToTrackdir(ns < (int)TILE_SIZE ? TRACK_UPPER : TRACK_LOWER, dir);
} else {
ret = TrackDirectionToTrackdir(we < 0 ? TRACK_LEFT : TRACK_RIGHT, dir);
}
}
return ret;
}
static bool FindPolyline(const Point &pt, const LineSnapPoint &start, PolylineInfo *ret)
{
/* relative coordinats of the mouse point (offset against the snap point) */
int x = pt.x - start.x;
int y = pt.y - start.y;
int we = y - x;
int ns = x + y;
/* in-tile alignment of the snap point (there are two variants: [0, 8] or [8, 0]) */
uint align_x = start.x & TILE_UNIT_MASK;
uint align_y = start.y & TILE_UNIT_MASK;
assert((align_x == TILE_SIZE / 2 && align_y == 0 && !(start.dirs & X_DIRS)) || (align_x == 0 && align_y == TILE_SIZE / 2 && !(start.dirs & Y_DIRS)));
/* absolute distance between points (in tiles) */
uint d_x = abs(RoundDivSU(x < 0 ? x - align_y : x + align_y, TILE_SIZE));
uint d_y = abs(RoundDivSU(y < 0 ? y - align_x : y + align_x, TILE_SIZE));
uint d_ns = abs(RoundDivSU(ns, TILE_SIZE));
uint d_we = abs(RoundDivSU(we, TILE_SIZE));
/* Find on which quadrant is the mouse point (reltively to the snap point).
* Numeration (clockwise like in Direction):
* ortho diag
* \ 2 / 2 | 3
* \ / --+---> [we]
* 1 X 3 1 | 0
* / \ v
* [x] 0 [y] [ns] */
uint ortho_quadrant = 2 * (x < 0) + ((x < 0) != (y < 0)); // implicit cast: false/true --> 0/1
uint diag_quadrant = 2 * (ns < 0) + ((ns < 0) != (we < 0));
/* direction from the snap point to the mouse point */
Direction ortho_line_dir = ChangeDir(DIR_S, (DirDiff)(2 * ortho_quadrant)); // DIR_S is the middle of the ortho quadrant no. 0
Direction diag_line_dir = ChangeDir(DIR_SE, (DirDiff)(2 * diag_quadrant)); // DIR_SE is the middle of the diag quadrant no. 0
if (!HasBit(start.dirs, ortho_line_dir) && !HasBit(start.dirs, diag_line_dir)) return false;
/* length of booth segments of auto line (choosing orthogonal direction first) */
uint ortho_len = 0, ortho_len2 = 0;
if (HasBit(start.dirs, ortho_line_dir)) {
bool is_len_even = (align_x != 0) ? d_x >= d_y : d_x <= d_y;
ortho_len = 2 * std::min(d_x, d_y) - (int)is_len_even;
assert((int)ortho_len >= 0);
if (d_ns == 0 || d_we == 0) { // just single segment?
ortho_len++;
} else {
ortho_len2 = abs((int)d_x - (int)d_y) + (int)is_len_even;
}
}
/* length of booth segments of auto line (choosing diagonal direction first) */
uint diag_len = 0, diag_len2 = 0;
if (HasBit(start.dirs, diag_line_dir)) {
if (d_x == 0 || d_y == 0) { // just single segment?
diag_len = d_x + d_y;
} else {
diag_len = std::min(d_ns, d_we);
diag_len2 = d_x + d_y - diag_len;
}
}
/* choose the best variant */
if (ortho_len != 0 && diag_len != 0) {
/* in the first place, choose this line whose first segment ends up closer
* to the mouse point (thus the second segment is shorter) */
int cmp = ortho_len2 - diag_len2;
/* if equeal, choose the shorter line */
if (cmp == 0) cmp = ortho_len - diag_len;
/* finally look at small "units" and choose the line which is closer to the mouse point */
if (cmp == 0) cmp = std::min(abs(we), abs(ns)) - std::min(abs(x), abs(y));
/* based on comparison, disable one of variants */
if (cmp > 0) {
ortho_len = 0;
} else {
diag_len = 0;
}
}
/* store results */
if (ortho_len != 0) {
ret->first_dir = ortho_line_dir;
ret->first_len = ortho_len;
ret->second_dir = (ortho_len2 != 0) ? diag_line_dir : INVALID_DIR;
ret->second_len = ortho_len2;
} else if (diag_len != 0) {
ret->first_dir = diag_line_dir;
ret->first_len = diag_len;
ret->second_dir = (diag_len2 != 0) ? ortho_line_dir : INVALID_DIR;
ret->second_len = diag_len2;
} else {
return false;
}
ret->start = start;
return true;
}
/**
* Calculate squared euclidean distance between two points.
* @param a the first point
* @param b the second point
* @return |b - a| ^ 2
*/
static inline uint SqrDist(const Point &a, const Point &b)
{
return (b.x - a.x) * (b.x - a.x) + (b.y - a.y) * (b.y - a.y);
}
static LineSnapPoint *FindBestPolyline(const Point &pt, LineSnapPoint *snap_points, uint num_points, PolylineInfo *ret)
{
/* Find the best polyline (a pair of two lines - the white one and the blue
* one) led from any of saved snap points to the mouse cursor. */
LineSnapPoint *best_snap_point = nullptr; // the best polyline we found so far is led from this snap point
for (int i = 0; i < (int)num_points; i++) {
/* try to fit a polyline */
PolylineInfo polyline;
if (!FindPolyline(pt, snap_points[i], &polyline)) continue; // skip non-matching snap points
/* check whether we've found a better polyline */
if (best_snap_point != nullptr) {
/* firstly choose shorter polyline (the one with smaller amount of
* track pieces composing booth the white and the blue line) */
uint cur_len = polyline.first_len + polyline.second_len;
uint best_len = ret->first_len + ret->second_len;
if (cur_len > best_len) continue;
/* secondly choose that polyline which has longer first (white) line */
if (cur_len == best_len && polyline.first_len < ret->first_len) continue;
/* finally check euclidean distance to snap points and choose the
* one which is closer */
if (cur_len == best_len && polyline.first_len == ret->first_len && SqrDist(pt, snap_points[i]) >= SqrDist(pt, *best_snap_point)) continue;
}
/* save the found polyline */
*ret = polyline;
best_snap_point = &snap_points[i];
}
return best_snap_point;
}
/** while dragging */
static void CalcRaildirsDrawstyle(int x, int y, int method)
{
HighLightStyle b;
int dx = _thd.selstart.x - (_thd.selend.x & ~TILE_UNIT_MASK);
int dy = _thd.selstart.y - (_thd.selend.y & ~TILE_UNIT_MASK);
uint w = abs(dx) + TILE_SIZE;
uint h = abs(dy) + TILE_SIZE;
if (method & ~(VPM_RAILDIRS | VPM_SIGNALDIRS)) {
/* We 'force' a selection direction; first four rail buttons. */
method &= ~(VPM_RAILDIRS | VPM_SIGNALDIRS);
int raw_dx = _thd.selstart.x - _thd.selend.x;
int raw_dy = _thd.selstart.y - _thd.selend.y;
switch (method) {
case VPM_FIX_X:
b = HT_LINE | HT_DIR_Y;
x = _thd.selstart.x;
break;
case VPM_FIX_Y:
b = HT_LINE | HT_DIR_X;
y = _thd.selstart.y;
break;
case VPM_FIX_HORIZONTAL:
if (dx == -dy) {
/* We are on a straight horizontal line. Determine the 'rail'
* to build based the sub tile location. */
b = (x & TILE_UNIT_MASK) + (y & TILE_UNIT_MASK) >= TILE_SIZE ? HT_LINE | HT_DIR_HL : HT_LINE | HT_DIR_HU;
} else {
/* We are not on a straight line. Determine the rail to build
* based on whether we are above or below it. */
b = dx + dy >= (int)TILE_SIZE ? HT_LINE | HT_DIR_HU : HT_LINE | HT_DIR_HL;
/* Calculate where a horizontal line through the start point and
* a vertical line from the selected end point intersect and
* use that point as the end point. */
int offset = (raw_dx - raw_dy) / 2;
x = _thd.selstart.x - (offset & ~TILE_UNIT_MASK);
y = _thd.selstart.y + (offset & ~TILE_UNIT_MASK);
/* 'Build' the last half rail tile if needed */
if ((offset & TILE_UNIT_MASK) > (TILE_SIZE / 2)) {
if (dx + dy >= (int)TILE_SIZE) {
x += (dx + dy < 0) ? (int)TILE_SIZE : -(int)TILE_SIZE;
} else {
y += (dx + dy < 0) ? (int)TILE_SIZE : -(int)TILE_SIZE;
}
}
/* Make sure we do not overflow the map! */
CheckUnderflow(x, y, 1);
CheckUnderflow(y, x, 1);
CheckOverflow(x, y, (MapMaxX() - 1) * TILE_SIZE, 1);
CheckOverflow(y, x, (MapMaxY() - 1) * TILE_SIZE, 1);
assert(x >= 0 && y >= 0 && x <= (int)(MapMaxX() * TILE_SIZE) && y <= (int)(MapMaxY() * TILE_SIZE));
}
break;
case VPM_FIX_VERTICAL:
if (dx == dy) {
/* We are on a straight vertical line. Determine the 'rail'
* to build based the sub tile location. */
b = (x & TILE_UNIT_MASK) > (y & TILE_UNIT_MASK) ? HT_LINE | HT_DIR_VL : HT_LINE | HT_DIR_VR;
} else {
/* We are not on a straight line. Determine the rail to build
* based on whether we are left or right from it. */
b = dx < dy ? HT_LINE | HT_DIR_VL : HT_LINE | HT_DIR_VR;
/* Calculate where a vertical line through the start point and
* a horizontal line from the selected end point intersect and
* use that point as the end point. */
int offset = (raw_dx + raw_dy + (int)TILE_SIZE) / 2;
x = _thd.selstart.x - (offset & ~TILE_UNIT_MASK);
y = _thd.selstart.y - (offset & ~TILE_UNIT_MASK);
/* 'Build' the last half rail tile if needed */
if ((offset & TILE_UNIT_MASK) > (TILE_SIZE / 2)) {
if (dx - dy < 0) {
y += (dx > dy) ? (int)TILE_SIZE : -(int)TILE_SIZE;
} else {
x += (dx < dy) ? (int)TILE_SIZE : -(int)TILE_SIZE;
}
}
/* Make sure we do not overflow the map! */
CheckUnderflow(x, y, -1);
CheckUnderflow(y, x, -1);
CheckOverflow(x, y, (MapMaxX() - 1) * TILE_SIZE, -1);
CheckOverflow(y, x, (MapMaxY() - 1) * TILE_SIZE, -1);
assert(x >= 0 && y >= 0 && x <= (int)(MapMaxX() * TILE_SIZE) && y <= (int)(MapMaxY() * TILE_SIZE));
}
break;
default:
NOT_REACHED();
}
} else if (TileVirtXY(_thd.selstart.x, _thd.selstart.y) == TileVirtXY(x, y)) { // check if we're only within one tile
if (method & VPM_RAILDIRS) {
b = GetAutorailHT(x, y);
} else { // rect for autosignals on one tile
b = HT_RECT;
}
} else if (h == TILE_SIZE) { // Is this in X direction?
if (dx == (int)TILE_SIZE) { // 2x1 special handling
b = (Check2x1AutoRail(3)) | HT_LINE;
} else if (dx == -(int)TILE_SIZE) {
b = (Check2x1AutoRail(2)) | HT_LINE;
} else {
b = HT_LINE | HT_DIR_X;
}
y = _thd.selstart.y;
} else if (w == TILE_SIZE) { // Or Y direction?
if (dy == (int)TILE_SIZE) { // 2x1 special handling
b = (Check2x1AutoRail(1)) | HT_LINE;
} else if (dy == -(int)TILE_SIZE) { // 2x1 other direction
b = (Check2x1AutoRail(0)) | HT_LINE;
} else {
b = HT_LINE | HT_DIR_Y;
}
x = _thd.selstart.x;
} else if (w > h * 2) { // still count as x dir?
b = HT_LINE | HT_DIR_X;
y = _thd.selstart.y;
} else if (h > w * 2) { // still count as y dir?
b = HT_LINE | HT_DIR_Y;
x = _thd.selstart.x;
} else { // complicated direction
int d = w - h;
_thd.selend.x = _thd.selend.x & ~TILE_UNIT_MASK;
_thd.selend.y = _thd.selend.y & ~TILE_UNIT_MASK;
/* four cases. */
if (x > _thd.selstart.x) {
if (y > _thd.selstart.y) {
/* south */
if (d == 0) {
b = (x & TILE_UNIT_MASK) > (y & TILE_UNIT_MASK) ? HT_LINE | HT_DIR_VL : HT_LINE | HT_DIR_VR;
} else if (d >= 0) {
x = _thd.selstart.x + h;
b = HT_LINE | HT_DIR_VL;
} else {
y = _thd.selstart.y + w;
b = HT_LINE | HT_DIR_VR;
}
} else {
/* west */
if (d == 0) {
b = (x & TILE_UNIT_MASK) + (y & TILE_UNIT_MASK) >= TILE_SIZE ? HT_LINE | HT_DIR_HL : HT_LINE | HT_DIR_HU;
} else if (d >= 0) {
x = _thd.selstart.x + h;
b = HT_LINE | HT_DIR_HL;
} else {
y = _thd.selstart.y - w;
b = HT_LINE | HT_DIR_HU;
}
}
} else {
if (y > _thd.selstart.y) {
/* east */
if (d == 0) {
b = (x & TILE_UNIT_MASK) + (y & TILE_UNIT_MASK) >= TILE_SIZE ? HT_LINE | HT_DIR_HL : HT_LINE | HT_DIR_HU;
} else if (d >= 0) {
x = _thd.selstart.x - h;
b = HT_LINE | HT_DIR_HU;
} else {
y = _thd.selstart.y + w;
b = HT_LINE | HT_DIR_HL;
}
} else {
/* north */
if (d == 0) {
b = (x & TILE_UNIT_MASK) > (y & TILE_UNIT_MASK) ? HT_LINE | HT_DIR_VL : HT_LINE | HT_DIR_VR;
} else if (d >= 0) {
x = _thd.selstart.x - h;
b = HT_LINE | HT_DIR_VR;
} else {
y = _thd.selstart.y - w;
b = HT_LINE | HT_DIR_VL;
}
}
}
}
_thd.selend.x = x;
_thd.selend.y = y;
_thd.dir2 = HT_DIR_END;
_thd.next_drawstyle = b;
ShowLengthMeasurement(b, TileVirtXY(_thd.selstart.x, _thd.selstart.y), TileVirtXY(_thd.selend.x, _thd.selend.y));
}
static HighLightStyle CalcPolyrailDrawstyle(Point pt, bool dragging)
{
RailSnapMode snap_mode = GetRailSnapMode();
/* are we only within one tile? */
if (snap_mode == RSM_SNAP_TO_TILE && GetRailSnapTile() == TileVirtXY(pt.x, pt.y)) {
_thd.selend.x = pt.x;
_thd.selend.y = pt.y;
HideMeasurementTooltips();
return GetAutorailHT(pt.x, pt.y);
}
/* find the best track */
PolylineInfo line;
bool lock_snapping = dragging && snap_mode == RSM_SNAP_TO_RAIL;
if (!lock_snapping) _current_snap_lock.x = -1;
const LineSnapPoint *snap_point;
if (_current_snap_lock.x != -1) {
snap_point = FindBestPolyline(pt, &_current_snap_lock, 1, &line);
} else if (snap_mode == RSM_SNAP_TO_TILE) {
snap_point = FindBestPolyline(pt, _tile_snap_points.data(), (uint)_tile_snap_points.size(), &line);
} else {
assert(snap_mode == RSM_SNAP_TO_RAIL);
snap_point = FindBestPolyline(pt, _rail_snap_points.data(), (uint)_rail_snap_points.size(), &line);
}
if (snap_point == nullptr) {
HideMeasurementTooltips();
return HT_NONE; // no match
}
if (lock_snapping && _current_snap_lock.x == -1) {
/* lock down the snap point */
_current_snap_lock = *snap_point;
_current_snap_lock.dirs &= (1 << line.first_dir) | (1 << ReverseDir(line.first_dir));
}
TileIndexDiffC first_dir = TileIndexDiffCByDir(line.first_dir);
_thd.selstart.x = line.start.x;
_thd.selstart.y = line.start.y;
_thd.selend.x = _thd.selstart.x + line.first_len * first_dir.x * (IsDiagonalDirection(line.first_dir) ? TILE_SIZE : TILE_SIZE / 2);
_thd.selend.y = _thd.selstart.y + line.first_len * first_dir.y * (IsDiagonalDirection(line.first_dir) ? TILE_SIZE : TILE_SIZE / 2);
_thd.selstart2.x = _thd.selend.x;
_thd.selstart2.y = _thd.selend.y;
_thd.selstart.x += first_dir.x;
_thd.selstart.y += first_dir.y;
_thd.selend.x -= first_dir.x;
_thd.selend.y -= first_dir.y;
Trackdir seldir = PointDirToTrackdir(_thd.selstart, line.first_dir);
_thd.selstart.x &= ~TILE_UNIT_MASK;
_thd.selstart.y &= ~TILE_UNIT_MASK;
if (line.second_len != 0) {
TileIndexDiffC second_dir = TileIndexDiffCByDir(line.second_dir);
_thd.selend2.x = _thd.selstart2.x + line.second_len * second_dir.x * (IsDiagonalDirection(line.second_dir) ? TILE_SIZE : TILE_SIZE / 2);
_thd.selend2.y = _thd.selstart2.y + line.second_len * second_dir.y * (IsDiagonalDirection(line.second_dir) ? TILE_SIZE : TILE_SIZE / 2);
_thd.selstart2.x += second_dir.x;
_thd.selstart2.y += second_dir.y;
_thd.selend2.x -= second_dir.x;
_thd.selend2.y -= second_dir.y;
Trackdir seldir2 = PointDirToTrackdir(_thd.selstart2, line.second_dir);
_thd.selstart2.x &= ~TILE_UNIT_MASK;
_thd.selstart2.y &= ~TILE_UNIT_MASK;
_thd.dir2 = (HighLightStyle)TrackdirToTrack(seldir2);
} else {
_thd.dir2 = HT_DIR_END;
}
HighLightStyle ret = HT_LINE | (HighLightStyle)TrackdirToTrack(seldir);
ShowLengthMeasurement(ret, TileVirtXY(_thd.selstart.x, _thd.selstart.y), TileVirtXY(_thd.selend.x, _thd.selend.y), TCC_EXIT_VIEWPORT, true);
return ret;
}
/**
* Selects tiles while dragging
* @param x X coordinate of end of selection
* @param y Y coordinate of end of selection
* @param method modifies the way tiles are selected. Possible
* methods are VPM_* in viewport.h
*/
void VpSelectTilesWithMethod(int x, int y, ViewportPlaceMethod method)
{
int sx, sy;
HighLightStyle style;
if (x == -1) {
_thd.selend.x = -1;
return;
}
if ((_thd.place_mode & HT_POLY) && GetRailSnapMode() != RSM_NO_SNAP) {
Point pt = { x, y };
_thd.next_drawstyle = CalcPolyrailDrawstyle(pt, true);
return;
}
/* Special handling of drag in any (8-way) direction */
if (method & (VPM_RAILDIRS | VPM_SIGNALDIRS)) {
_thd.selend.x = x;
_thd.selend.y = y;
CalcRaildirsDrawstyle(x, y, method);
return;
}
/* Needed so level-land is placed correctly */
if ((_thd.next_drawstyle & HT_DRAG_MASK) == HT_POINT) {
x += TILE_SIZE / 2;
y += TILE_SIZE / 2;
}
sx = _thd.selstart.x;
sy = _thd.selstart.y;
int limit = 0;
switch (method) {
case VPM_X_OR_Y: // drag in X or Y direction
if (abs(sy - y) < abs(sx - x)) {
y = sy;
style = HT_DIR_X;
} else {
x = sx;
style = HT_DIR_Y;
}
goto calc_heightdiff_single_direction;
case VPM_X_LIMITED: // Drag in X direction (limited size).
limit = (_thd.sizelimit - 1) * TILE_SIZE;
FALLTHROUGH;
case VPM_FIX_X: // drag in Y direction
x = sx;
style = HT_DIR_Y;
goto calc_heightdiff_single_direction;
case VPM_Y_LIMITED: // Drag in Y direction (limited size).
limit = (_thd.sizelimit - 1) * TILE_SIZE;
FALLTHROUGH;
case VPM_FIX_Y: // drag in X direction
y = sy;
style = HT_DIR_X;
calc_heightdiff_single_direction:;
if (limit > 0) {
x = sx + Clamp(x - sx, -limit, limit);
y = sy + Clamp(y - sy, -limit, limit);
}
/* With current code passing a HT_LINE style to calculate the height
* difference is enough. However if/when a point-tool is created
* with this method, function should be called with new_style (below)
* instead of HT_LINE | style case HT_POINT is handled specially
* new_style := (_thd.next_drawstyle & HT_RECT) ? HT_LINE | style : _thd.next_drawstyle; */
ShowLengthMeasurement(HT_LINE | style, TileVirtXY(sx, sy), TileVirtXY(x, y));
break;
case VPM_A_B_LINE: { // drag an A to B line
TileIndex t0 = TileVirtXY(sx, sy);
TileIndex t1 = TileVirtXY(x, y);
uint dx = Delta(TileX(t0), TileX(t1)) + 1;
uint dy = Delta(TileY(t0), TileY(t1)) + 1;
byte index = 0;
uint64 params[5];
memset( params, 0, sizeof( params ) );
/* If dragging an area (eg dynamite tool) and it is actually a single
* row/column, change the type to 'line' to get proper calculation for height */
style = (HighLightStyle)_thd.next_drawstyle;
if (style & HT_RECT) {
if (dx == 1) {
style = HT_LINE | HT_DIR_Y;
} else if (dy == 1) {
style = HT_LINE | HT_DIR_X;
}
}
int heightdiff = 0;
if (dx != 1 || dy != 1) {
heightdiff = CalcHeightdiff(style, 0, t0, t1);
params[index++] = DistanceManhattan(t0, t1);
params[index++] = sqrtl(dx * dx + dy * dy); //DistanceSquare does not like big numbers
} else {
index += 2;
}
params[index++] = DistanceFromEdge(t1);
params[index++] = GetTileMaxZ(t1) * TILE_HEIGHT_STEP;
params[index++] = heightdiff;
//Show always the measurement tooltip
GuiShowTooltips(_thd.GetCallbackWnd(),STR_MEASURE_DIST_HEIGHTDIFF, index, params, TCC_EXIT_VIEWPORT);
break;
}
case VPM_X_AND_Y_LIMITED: // Drag an X by Y constrained rect area.
limit = (_thd.sizelimit - 1) * TILE_SIZE;
x = sx + Clamp(x - sx, -limit, limit);
y = sy + Clamp(y - sy, -limit, limit);
FALLTHROUGH;
case VPM_X_AND_Y: // drag an X by Y area
if (_settings_client.gui.measure_tooltip) {
static const StringID measure_strings_area[] = {
STR_NULL, STR_NULL, STR_MEASURE_AREA, STR_MEASURE_AREA_HEIGHTDIFF
};
TileIndex t0 = TileVirtXY(sx, sy);
TileIndex t1 = TileVirtXY(x, y);
uint dx = Delta(TileX(t0), TileX(t1)) + 1;
uint dy = Delta(TileY(t0), TileY(t1)) + 1;
byte index = 0;
uint64 params[3];
/* If dragging an area (eg dynamite tool) and it is actually a single
* row/column, change the type to 'line' to get proper calculation for height */
style = (HighLightStyle)_thd.next_drawstyle;
if (_thd.IsDraggingDiagonal()) {
/* Determine the "area" of the diagonal dragged selection.
* We assume the area is the number of tiles along the X
* edge and the number of tiles along the Y edge. However,
* multiplying these two numbers does not give the exact
* number of tiles; basically we are counting the black
* squares on a chess board and ignore the white ones to
* make the tile counts at the edges match up. There is no
* other way to make a proper count though.
*
* First convert to the rotated coordinate system. */
int dist_x = TileX(t0) - TileX(t1);
int dist_y = TileY(t0) - TileY(t1);
int a_max = dist_x + dist_y;
int b_max = dist_y - dist_x;
/* Now determine the size along the edge, but due to the
* chess board principle this counts double. */
a_max = abs(a_max + (a_max > 0 ? 2 : -2)) / 2;
b_max = abs(b_max + (b_max > 0 ? 2 : -2)) / 2;
/* We get a 1x1 on normal 2x1 rectangles, due to it being
* a seen as two sides. As the result for actual building
* will be the same as non-diagonal dragging revert to that
* behaviour to give it a more normally looking size. */
if (a_max != 1 || b_max != 1) {
dx = a_max;
dy = b_max;
}
} else if (style & HT_RECT) {
if (dx == 1) {
style = HT_LINE | HT_DIR_Y;
} else if (dy == 1) {
style = HT_LINE | HT_DIR_X;
}
}
if (dx != 1 || dy != 1) {
int heightdiff = CalcHeightdiff(style, 0, t0, t1);
params[index++] = dx - (style & HT_POINT ? 1 : 0);
params[index++] = dy - (style & HT_POINT ? 1 : 0);
if (heightdiff != 0) params[index++] = heightdiff;
}
ShowMeasurementTooltips(measure_strings_area[index], index, params);
}
break;
default: NOT_REACHED();
}
_thd.selend.x = x;
_thd.selend.y = y;
_thd.dir2 = HT_DIR_END;
}
/**
* Handle the mouse while dragging for placement/resizing.
* @return State of handling the event.
*/
EventState VpHandlePlaceSizingDrag()
{
if (_special_mouse_mode != WSM_SIZING && _special_mouse_mode != WSM_DRAGGING) return ES_NOT_HANDLED;
/* stop drag mode if the window has been closed */
Window *w = _thd.GetCallbackWnd();
if (w == nullptr) {
ResetObjectToPlace();
return ES_HANDLED;
}
if (_left_button_down && _special_mouse_mode == WSM_DRAGGING) {
/* Only register a drag event when the mouse moved. */
if (_thd.new_pos.x == _thd.selstart.x && _thd.new_pos.y == _thd.selstart.y) return ES_HANDLED;
_thd.selstart.x = _thd.new_pos.x;
_thd.selstart.y = _thd.new_pos.y;
}
/* While dragging execute the drag procedure of the corresponding window (mostly VpSelectTilesWithMethod() ).
* Do it even if the button is no longer pressed to make sure that OnPlaceDrag was called at least once. */
w->OnPlaceDrag(_thd.select_method, _thd.select_proc, GetTileBelowCursor());
if (_left_button_down) return ES_HANDLED;
/* Mouse button released. */
_special_mouse_mode = WSM_NONE;
if (_special_mouse_mode == WSM_DRAGGING) return ES_HANDLED;
/* Keep the selected tool, but reset it to the original mode. */
HighLightStyle others = _thd.place_mode & ~(HT_DRAG_MASK | HT_DIR_MASK);
if ((_thd.next_drawstyle & HT_DRAG_MASK) == HT_RECT) {
_thd.place_mode = HT_RECT | others;
} else if (_thd.select_method & VPM_SIGNALDIRS) {
_thd.place_mode = HT_RECT | others;
} else if (_thd.select_method & VPM_RAILDIRS) {
_thd.place_mode = (_thd.select_method & ~VPM_RAILDIRS ? _thd.next_drawstyle : HT_RAIL) | others;
} else {
_thd.place_mode = HT_POINT | others;
}
SetTileSelectSize(1, 1);
if (_thd.place_mode & HT_POLY) {
if (GetRailSnapMode() == RSM_SNAP_TO_TILE) SetRailSnapMode(RSM_NO_SNAP);
if (_thd.drawstyle == HT_NONE) return ES_HANDLED;
}
HideMeasurementTooltips();
w->OnPlaceMouseUp(_thd.select_method, _thd.select_proc, _thd.selend, TileVirtXY(_thd.selstart.x, _thd.selstart.y), TileVirtXY(_thd.selend.x, _thd.selend.y));
return ES_HANDLED;
}
/**
* Change the cursor and mouse click/drag handling to a mode for performing special operations like tile area selection, object placement, etc.
* @param icon New shape of the mouse cursor.
* @param pal Palette to use.
* @param mode Mode to perform.
* @param w %Window requesting the mode change.
*/
void SetObjectToPlaceWnd(CursorID icon, PaletteID pal, HighLightStyle mode, Window *w)
{
SetObjectToPlace(icon, pal, mode, w->window_class, w->window_number);
}
#include "table/animcursors.h"
/**
* Change the cursor and mouse click/drag handling to a mode for performing special operations like tile area selection, object placement, etc.
* @param icon New shape of the mouse cursor.
* @param pal Palette to use.
* @param mode Mode to perform.
* @param window_class %Window class of the window requesting the mode change.
* @param window_num Number of the window in its class requesting the mode change.
*/
void SetObjectToPlace(CursorID icon, PaletteID pal, HighLightStyle mode, WindowClass window_class, WindowNumber window_num)
{
if (_thd.window_class != WC_INVALID) {
/* Undo clicking on button and drag & drop */
Window *w = _thd.GetCallbackWnd();
/* Call the abort function, but set the window class to something
* that will never be used to avoid infinite loops. Setting it to
* the 'next' window class must not be done because recursion into
* this function might in some cases reset the newly set object to
* place or not properly reset the original selection. */
_thd.window_class = WC_INVALID;
if (w != nullptr) {
w->OnPlaceObjectAbort();
HideMeasurementTooltips();
}
}
/* Mark the old selection dirty, in case the selection shape or colour changes */
if ((_thd.drawstyle & HT_DRAG_MASK) != HT_NONE) SetSelectionTilesDirty();
SetTileSelectSize(1, 1);
_thd.make_square_red = false;
if (mode == HT_DRAG) { // HT_DRAG is for dragdropping trains in the depot window
mode = HT_NONE;
_special_mouse_mode = WSM_DRAGDROP;
} else {
_special_mouse_mode = WSM_NONE;
}
_thd.place_mode = mode;
_thd.window_class = window_class;
_thd.window_number = window_num;
if ((mode & HT_DRAG_MASK) == HT_SPECIAL) { // special tools, like tunnels or docks start with presizing mode
VpStartPreSizing();
}
if (mode & HT_POLY) {
SetRailSnapMode((mode & HT_NEW_POLY) == HT_NEW_POLY ? RSM_NO_SNAP : RSM_SNAP_TO_RAIL);
}
if ((icon & ANIMCURSOR_FLAG) != 0) {
SetAnimatedMouseCursor(_animcursors[icon & ~ANIMCURSOR_FLAG]);
} else {
SetMouseCursor(icon, pal);
}
}
/** Reset the cursor and mouse mode handling back to default (normal cursor, only clicking in windows). */
void ResetObjectToPlace()
{
SetObjectToPlace(SPR_CURSOR_MOUSE, PAL_NONE, HT_NONE, WC_MAIN_WINDOW, 0);
}
void ChangeRenderMode(Viewport *vp, bool down) {
ViewportMapType map_type = vp->map_type;
if (vp->zoom < ZOOM_LVL_DRAW_MAP) return;
ClearViewportLandPixelCache(vp);
if (down) {
vp->map_type = (map_type == VPMT_MIN) ? VPMT_MAX : (ViewportMapType) (map_type - 1);
} else {
vp->map_type = (map_type == VPMT_MAX) ? VPMT_MIN : (ViewportMapType) (map_type + 1);
}
}
Point GetViewportStationMiddle(const Viewport *vp, const Station *st)
{
int x = TileX(st->xy) * TILE_SIZE;
int y = TileY(st->xy) * TILE_SIZE;
int z = GetSlopePixelZ(Clamp(x, 0, MapSizeX() * TILE_SIZE - 1), Clamp(y, 0, MapSizeY() * TILE_SIZE - 1));
Point p = RemapCoords(x, y, z);
p.x = UnScaleByZoom(p.x - vp->virtual_left, vp->zoom) + vp->left;
p.y = UnScaleByZoom(p.y - vp->virtual_top, vp->zoom) + vp->top;
return p;
}
/** Helper class for getting the best sprite sorter. */
struct ViewportSSCSS {
VpSorterChecker fct_checker; ///< The check function.
VpSpriteSorter fct_sorter; ///< The sorting function.
};
/** List of sorters ordered from best to worst. */
static ViewportSSCSS _vp_sprite_sorters[] = {
#ifdef WITH_SSE
{ &ViewportSortParentSpritesSSE41Checker, &ViewportSortParentSpritesSSE41 },
#endif
{ &ViewportSortParentSpritesChecker, &ViewportSortParentSprites }
};
/** Choose the "best" sprite sorter and set _vp_sprite_sorter. */
void InitializeSpriteSorter()
{
for (uint i = 0; i < lengthof(_vp_sprite_sorters); i++) {
if (_vp_sprite_sorters[i].fct_checker()) {
_vp_sprite_sorter = _vp_sprite_sorters[i].fct_sorter;
break;
}
}
assert(_vp_sprite_sorter != nullptr);
}
/**
* Scroll players main viewport.
* @param tile tile to center viewport on
* @param flags type of operation
* @param p1 ViewportScrollTarget of scroll target
* @param p2 company or client id depending on the target
* @param text unused
* @return the cost of this operation or an error
*/
CommandCost CmdScrollViewport(TileIndex tile, DoCommandFlag flags, uint32 p1, uint32 p2, const char *text)
{
if (_current_company != OWNER_DEITY) return CMD_ERROR;
ViewportScrollTarget target = (ViewportScrollTarget)p1;
switch (target) {
case VST_EVERYONE:
break;
case VST_COMPANY:
if (_local_company != (CompanyID)p2) return CommandCost();
break;
case VST_CLIENT:
if (_network_own_client_id != (ClientID)p2) return CommandCost();
break;
default:
return CMD_ERROR;
}
if (flags & DC_EXEC) {
ResetObjectToPlace();
ScrollMainWindowToTile(tile);
}
return CommandCost();
}
static LineSnapPoint LineSnapPointAtRailTrackEndpoint(TileIndex tile, DiagDirection exit_dir, bool bidirectional)
{
LineSnapPoint ret;
ret.x = (TILE_SIZE / 2) * (uint)(2 * TileX(tile) + TileIndexDiffCByDiagDir(exit_dir).x + 1);
ret.y = (TILE_SIZE / 2) * (uint)(2 * TileY(tile) + TileIndexDiffCByDiagDir(exit_dir).y + 1);
ret.dirs = 0;
SetBit(ret.dirs, DiagDirToDir(exit_dir));
SetBit(ret.dirs, ChangeDir(DiagDirToDir(exit_dir), DIRDIFF_45LEFT));
SetBit(ret.dirs, ChangeDir(DiagDirToDir(exit_dir), DIRDIFF_45RIGHT));
if (bidirectional) ret.dirs |= ROR<uint8>(ret.dirs, DIRDIFF_REVERSE);
return ret;
}
/**
* Store the position of lastly built rail track; for highlighting purposes.
*
* In "polyline" highlighting mode, the stored end point will be used as a snapping point for new
* tracks allowing to place multi-segment polylines.
*
* @param start_tile tile where the track starts
* @param end_tile tile where the track ends
* @param start_track track piece on the start_tile
* @param bidirectional_exit whether to allow to highlight next track in any direction; otherwise new track will have to fallow the stored one (usefull when placing tunnels and bridges)
*/
void StoreRailPlacementEndpoints(TileIndex start_tile, TileIndex end_tile, Track start_track, bool bidirectional_exit)
{
if (start_tile != INVALID_TILE && end_tile != INVALID_TILE) {
/* calculate trackdirs at booth ends of the track */
Trackdir exit_trackdir_at_start = TrackToTrackdir(start_track);
Trackdir exit_trackdir_at_end = ReverseTrackdir(TrackToTrackdir(start_track));
if (start_tile != end_tile) { // multi-tile case
/* determine proper direction (pointing outside of the track) */
uint distance = DistanceManhattan(start_tile, end_tile);
if (distance > DistanceManhattan(TileAddByDiagDir(start_tile, TrackdirToExitdir(exit_trackdir_at_start)), end_tile)) {
Swap(exit_trackdir_at_start, exit_trackdir_at_end);
}
/* determine proper track on the end tile - switch between upper/lower or left/right based on the length */
if (distance % 2 != 0) exit_trackdir_at_end = NextTrackdir(exit_trackdir_at_end);
}
LineSnapPoint snap_start = LineSnapPointAtRailTrackEndpoint(start_tile, TrackdirToExitdir(exit_trackdir_at_start), bidirectional_exit);
LineSnapPoint snap_end = LineSnapPointAtRailTrackEndpoint(end_tile, TrackdirToExitdir(exit_trackdir_at_end), bidirectional_exit);
/* Find if we already had these coordinates before. */
bool had_start = false;
bool had_end = false;
for (const LineSnapPoint &snap : _rail_snap_points) {
had_start |= (snap.x == snap_start.x && snap.y == snap_start.y);
had_end |= (snap.x == snap_end.x && snap.y == snap_end.y);
}
/* Create new snap point set. */
if (had_start && had_end) {
/* just stop snaping, don't forget snap points */
SetRailSnapMode(RSM_NO_SNAP);
} else {
/* include only new points */
_rail_snap_points.clear();
if (!had_start) _rail_snap_points.push_back(snap_start);
if (!had_end) _rail_snap_points.push_back(snap_end);
SetRailSnapMode(RSM_SNAP_TO_RAIL);
}
}
}
static void MarkCatchmentTilesDirty()
{
if (_viewport_highlight_town != nullptr) {
MarkWholeNonMapViewportsDirty();
return;
}
if (_viewport_highlight_station != nullptr) {
if (_viewport_highlight_station->catchment_tiles.tile == INVALID_TILE) {
MarkWholeNonMapViewportsDirty();
_viewport_highlight_station = nullptr;
} else {
BitmapTileIterator it(_viewport_highlight_station->catchment_tiles);
for (TileIndex tile = it; tile != INVALID_TILE; tile = ++it) {
MarkTileDirtyByTile(tile, VMDF_NOT_MAP_MODE);
}
}
}
}
bool CurrentlySnappingRailPlacement()
{
return (_thd.place_mode & HT_POLY) && GetRailSnapMode() == RSM_SNAP_TO_RAIL;
}
static RailSnapMode GetRailSnapMode()
{
if (_rail_snap_mode == RSM_SNAP_TO_TILE && _tile_snap_points.size() == 0) return RSM_NO_SNAP;
if (_rail_snap_mode == RSM_SNAP_TO_RAIL && _rail_snap_points.size() == 0) return RSM_NO_SNAP;
return _rail_snap_mode;
}
static void SetRailSnapMode(RailSnapMode mode)
{
_rail_snap_mode = mode;
if ((_thd.place_mode & HT_POLY) && (GetRailSnapMode() == RSM_NO_SNAP)) {
SetTileSelectSize(1, 1);
}
}
static TileIndex GetRailSnapTile()
{
if (_tile_snap_points.size() == 0) return INVALID_TILE;
return TileVirtXY(_tile_snap_points[DIAGDIR_NE].x, _tile_snap_points[DIAGDIR_NE].y);
}
static void SetRailSnapTile(TileIndex tile)
{
_tile_snap_points.clear();
if (tile == INVALID_TILE) return;
for (DiagDirection dir = DIAGDIR_BEGIN; dir < DIAGDIR_END; dir++) {
_tile_snap_points.push_back(LineSnapPointAtRailTrackEndpoint(tile, dir, false));
LineSnapPoint &point = _tile_snap_points.back();
point.dirs = ROR<uint8>(point.dirs, DIRDIFF_REVERSE);
}
}
void ResetRailPlacementSnapping()
{
_rail_snap_mode = RSM_NO_SNAP;
_tile_snap_points.clear();
_rail_snap_points.clear();
_current_snap_lock.x = -1;
}
/**
* Select or deselect station for coverage area highlight.
* Selecting a station will deselect a town.
* @param *st Station in question
* @param sel Select or deselect given station
*/
void SetViewportCatchmentStation(const Station *st, bool sel)
{
if (_viewport_highlight_station != nullptr) SetWindowDirty(WC_STATION_VIEW, _viewport_highlight_station->index);
if (_viewport_highlight_town != nullptr) SetWindowDirty(WC_TOWN_VIEW, _viewport_highlight_town->index);
if (sel && _viewport_highlight_station != st) {
MarkCatchmentTilesDirty();
_viewport_highlight_station = st;
_viewport_highlight_town = nullptr;
MarkCatchmentTilesDirty();
} else if (!sel && _viewport_highlight_station == st) {
MarkCatchmentTilesDirty();
_viewport_highlight_station = nullptr;
}
if (_viewport_highlight_station != nullptr) SetWindowDirty(WC_STATION_VIEW, _viewport_highlight_station->index);
}
/**
* Select or deselect town for coverage area highlight.
* Selecting a town will deselect a station.
* @param *t Town in question
* @param sel Select or deselect given town
*/
void SetViewportCatchmentTown(const Town *t, bool sel)
{
if (_viewport_highlight_town != nullptr) SetWindowDirty(WC_TOWN_VIEW, _viewport_highlight_town->index);
if (_viewport_highlight_station != nullptr) SetWindowDirty(WC_STATION_VIEW, _viewport_highlight_station->index);
if (sel && _viewport_highlight_town != t) {
_viewport_highlight_station = nullptr;
_viewport_highlight_town = t;
MarkWholeNonMapViewportsDirty();
} else if (!sel && _viewport_highlight_town == t) {
_viewport_highlight_town = nullptr;
MarkWholeNonMapViewportsDirty();
}
if (_viewport_highlight_town != nullptr) SetWindowDirty(WC_TOWN_VIEW, _viewport_highlight_town->index);
}
int GetSlopeTreeBrightnessAdjust(Slope slope)
{
switch (slope) {
case SLOPE_NW:
case SLOPE_STEEP_N:
case SLOPE_STEEP_W:
return 8;
case SLOPE_N:
case SLOPE_W:
case SLOPE_ENW:
case SLOPE_NWS:
return 4;
case SLOPE_SE:
return -10;
case SLOPE_STEEP_S:
case SLOPE_STEEP_E:
return -4;
case SLOPE_NE:
return -8;
case SLOPE_SW:
return -4;
case SLOPE_S:
case SLOPE_E:
case SLOPE_SEN:
case SLOPE_WSE:
return -6;
default:
return 0;
}
}