Files @ r23774:59b54c2b48f6
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Location: cpp/openttd-patchpack/source/src/newgrf_railtype.cpp

Niels Martin Hansen
Change: Limit in-editor warnings in VS 2019

The AllRules ruleset causes the VS 2019 editor to litter warning squiggles all over the place, about things that would never be fixed. Limit it to the smallest ruleset available. Warnings shown now mainly concern potential arithmetic overflows.
/* $Id$ */

/*
 * 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 newgrf_railtype.cpp NewGRF handling of rail types. */

#include "stdafx.h"
#include "debug.h"
#include "newgrf_railtype.h"
#include "date_func.h"
#include "depot_base.h"
#include "town.h"

#include "safeguards.h"

/* virtual */ uint32 RailTypeScopeResolver::GetRandomBits() const
{
	uint tmp = CountBits(this->tile + (TileX(this->tile) + TileY(this->tile)) * TILE_SIZE);
	return GB(tmp, 0, 2);
}

/* virtual */ uint32 RailTypeScopeResolver::GetVariable(byte variable, uint32 parameter, bool *available) const
{
	if (this->tile == INVALID_TILE) {
		switch (variable) {
			case 0x40: return 0;
			case 0x41: return 0;
			case 0x42: return 0;
			case 0x43: return _date;
			case 0x44: return HZB_TOWN_EDGE;
		}
	}

	switch (variable) {
		case 0x40: return GetTerrainType(this->tile, this->context);
		case 0x41: return 0;
		case 0x42: return IsLevelCrossingTile(this->tile) && IsCrossingBarred(this->tile);
		case 0x43:
			if (IsRailDepotTile(this->tile)) return Depot::GetByTile(this->tile)->build_date;
			return _date;
		case 0x44: {
			const Town *t = nullptr;
			if (IsRailDepotTile(this->tile)) {
				t = Depot::GetByTile(this->tile)->town;
			} else if (IsLevelCrossingTile(this->tile)) {
				t = ClosestTownFromTile(this->tile, UINT_MAX);
			}
			return t != nullptr ? GetTownRadiusGroup(t, this->tile) : HZB_TOWN_EDGE;
		}
	}

	DEBUG(grf, 1, "Unhandled rail type tile variable 0x%X", variable);

	*available = false;
	return UINT_MAX;
}

/* virtual */ const SpriteGroup *RailTypeResolverObject::ResolveReal(const RealSpriteGroup *group) const
{
	if (group->num_loading > 0) return group->loading[0];
	if (group->num_loaded  > 0) return group->loaded[0];
	return nullptr;
}

/**
 * Resolver object for rail types.
 * @param rti Railtype. nullptr in NewGRF Inspect window.
 * @param tile %Tile containing the track. For track on a bridge this is the southern bridgehead.
 * @param context Are we resolving sprites for the upper halftile, or on a bridge?
 * @param rtsg Railpart of interest
 * @param param1 Extra parameter (first parameter of the callback, except railtypes do not have callbacks).
 * @param param2 Extra parameter (second parameter of the callback, except railtypes do not have callbacks).
 */
RailTypeResolverObject::RailTypeResolverObject(const RailtypeInfo *rti, TileIndex tile, TileContext context, RailTypeSpriteGroup rtsg, uint32 param1, uint32 param2)
	: ResolverObject(rti != nullptr ? rti->grffile[rtsg] : nullptr, CBID_NO_CALLBACK, param1, param2), railtype_scope(*this, tile, context)
{
	this->root_spritegroup = rti != nullptr ? rti->group[rtsg] : nullptr;
}

/**
 * Get the sprite to draw for the given tile.
 * @param rti The rail type data (spec).
 * @param tile The tile to get the sprite for.
 * @param rtsg The type of sprite to draw.
 * @param context Where are we drawing the tile?
 * @param[out] num_results If not nullptr, return the number of sprites in the spriteset.
 * @return The sprite to draw.
 */
SpriteID GetCustomRailSprite(const RailtypeInfo *rti, TileIndex tile, RailTypeSpriteGroup rtsg, TileContext context, uint *num_results)
{
	assert(rtsg < RTSG_END);

	if (rti->group[rtsg] == nullptr) return 0;

	RailTypeResolverObject object(rti, tile, context, rtsg);
	const SpriteGroup *group = object.Resolve();
	if (group == nullptr || group->GetNumResults() == 0) return 0;

	if (num_results) *num_results = group->GetNumResults();

	return group->GetResult();
}

/**
 * Get the sprite to draw for a given signal.
 * @param rti The rail type data (spec).
 * @param tile The tile to get the sprite for.
 * @param type Signal type.
 * @param var Signal variant.
 * @param state Signal state.
 * @param gui Is the sprite being used on the map or in the GUI?
 * @return The sprite to draw.
 */
SpriteID GetCustomSignalSprite(const RailtypeInfo *rti, TileIndex tile, SignalType type, SignalVariant var, SignalState state, bool gui)
{
	if (rti->group[RTSG_SIGNALS] == nullptr) return 0;

	uint32 param1 = gui ? 0x10 : 0x00;
	uint32 param2 = (type << 16) | (var << 8) | state;
	RailTypeResolverObject object(rti, tile, TCX_NORMAL, RTSG_SIGNALS, param1, param2);

	const SpriteGroup *group = object.Resolve();
	if (group == nullptr || group->GetNumResults() == 0) return 0;

	return group->GetResult();
}

/**
 * Perform a reverse railtype lookup to get the GRF internal ID.
 * @param railtype The global (OpenTTD) railtype.
 * @param grffile The GRF to do the lookup for.
 * @return the GRF internal ID.
 */
uint8 GetReverseRailTypeTranslation(RailType railtype, const GRFFile *grffile)
{
	/* No rail type table present, return rail type as-is */
	if (grffile == nullptr || grffile->railtype_list.size() == 0) return railtype;

	/* Look for a matching rail type label in the table */
	RailTypeLabel label = GetRailTypeInfo(railtype)->label;

	int idx = find_index(grffile->railtype_list, label);
	if (idx >= 0) return idx;

	/* If not found, return as invalid */
	return 0xFF;
}