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/* $Id$ */
/** @file slope.h Definitions of a slope.
* This file defines the enumeration and helper functions for handling
* the slope info of a tile.
*/
#ifndef SLOPE_H
#define SLOPE_H
/**
* Enumeration of tile corners
*/
enum Corner {
CORNER_W = 0,
CORNER_S = 1,
CORNER_E = 2,
CORNER_N = 3,
CORNER_END
};
/**
* Enumeration for the slope-type.
*
* This enumeration use the chars N,E,S,W corresponding the
* direction north, east, south and west. The top corner of a tile
* is the north-part of the tile. The whole slope is encoded with
* 5 bits, 4 bits for each corner and 1 bit for a steep-flag.
*
* For halftile slopes an extra 3 bits are used to represent this
* properly; 1 bit for a halftile-flag and 2 bits to encode which
* extra side (corner) is leveled when the slope of the first 5
* bits is applied. This means that there can only be one leveled
* slope for steep slopes, which is logical because two leveled
* slopes would mean that it is not a steep slope as halftile
* slopes only span one height level.
*/
enum Slope {
SLOPE_FLAT = 0x00, ///< a flat tile
SLOPE_W = 0x01, ///< the west corner of the tile is raised
SLOPE_S = 0x02, ///< the south corner of the tile is raised
SLOPE_E = 0x04, ///< the east corner of the tile is raised
SLOPE_N = 0x08, ///< the north corner of the tile is raised
SLOPE_STEEP = 0x10, ///< indicates the slope is steep
SLOPE_NW = SLOPE_N | SLOPE_W, ///< north and west corner are raised
SLOPE_SW = SLOPE_S | SLOPE_W, ///< south and west corner are raised
SLOPE_SE = SLOPE_S | SLOPE_E, ///< south and east corner are raised
SLOPE_NE = SLOPE_N | SLOPE_E, ///< north and east corner are raised
SLOPE_EW = SLOPE_E | SLOPE_W, ///< east and west corner are raised
SLOPE_NS = SLOPE_N | SLOPE_S, ///< north and south corner are raised
SLOPE_ELEVATED = SLOPE_N | SLOPE_E | SLOPE_S | SLOPE_W, ///< all corner are raised, similar to SLOPE_FLAT
SLOPE_NWS = SLOPE_N | SLOPE_W | SLOPE_S, ///< north, west and south corner are raised
SLOPE_WSE = SLOPE_W | SLOPE_S | SLOPE_E, ///< west, south and east corner are raised
SLOPE_SEN = SLOPE_S | SLOPE_E | SLOPE_N, ///< south, east and north corner are raised
SLOPE_ENW = SLOPE_E | SLOPE_N | SLOPE_W, ///< east, north and west corner are raised
SLOPE_STEEP_W = SLOPE_STEEP | SLOPE_NWS, ///< a steep slope falling to east (from west)
SLOPE_STEEP_S = SLOPE_STEEP | SLOPE_WSE, ///< a steep slope falling to north (from south)
SLOPE_STEEP_E = SLOPE_STEEP | SLOPE_SEN, ///< a steep slope falling to west (from east)
SLOPE_STEEP_N = SLOPE_STEEP | SLOPE_ENW, ///< a steep slope falling to south (from north)
SLOPE_HALFTILE = 0x20, ///< one halftile is leveled (non continuous slope)
SLOPE_HALFTILE_MASK = 0xE0, ///< three bits used for halftile slopes
SLOPE_HALFTILE_W = SLOPE_HALFTILE | (CORNER_W << 6), ///< the west halftile is leveled (non continuous slope)
SLOPE_HALFTILE_S = SLOPE_HALFTILE | (CORNER_S << 6), ///< the south halftile is leveled (non continuous slope)
SLOPE_HALFTILE_E = SLOPE_HALFTILE | (CORNER_E << 6), ///< the east halftile is leveled (non continuous slope)
SLOPE_HALFTILE_N = SLOPE_HALFTILE | (CORNER_N << 6), ///< the north halftile is leveled (non continuous slope)
};
/**
* Rangecheck for Corner enumeration.
*
* @param corner A #Corner.
* @return true iff corner is in a valid range.
*/
static inline bool IsValidCorner(Corner corner)
{
return IS_INT_INSIDE(corner, 0, CORNER_END);
}
/**
* Checks if a slope is steep.
*
* @param s The given #Slope.
* @return True if the slope is steep, else false.
*/
static inline bool IsSteepSlope(Slope s)
{
return (s & SLOPE_STEEP) != 0;
}
/**
* Checks for non-continuous slope on halftile foundations.
*
* @param s The given #Slope.
* @return True if the slope is non-continuous, else false.
*/
static inline bool IsHalftileSlope(Slope s)
{
return (s & SLOPE_HALFTILE) != 0;
}
/**
* Return the complement of a slope.
*
* This method returns the complement of a slope. The complement of a
* slope is a slope with raised corner which aren't raised in the given
* slope.
*
* @pre The slope must neither be steep nor a halftile slope.
* @param s The #Slope to get the complement.
* @return a complement Slope of the given slope.
*/
static inline Slope ComplementSlope(Slope s)
{
assert(!IsSteepSlope(s) && !IsHalftileSlope(s));
return (Slope)(0xF ^ s);
}
/**
* Tests if a slope has a highest corner (i.e. one corner raised or a steep slope).
*
* Note: A halftile slope is ignored.
*
* @param s The #Slope.
* @return true iff the slope has a highest corner.
*/
static inline bool HasSlopeHighestCorner(Slope s)
{
s = (Slope)(s & ~SLOPE_HALFTILE_MASK);
return IsSteepSlope(s) || (s == SLOPE_W) || (s == SLOPE_S) || (s == SLOPE_E) || (s == SLOPE_N);
}
/**
* Returns the highest corner of a slope (one corner raised or a steep slope).
*
* @pre The slope must be a slope with one corner raised or a steep slope. A halftile slope is ignored.
* @param s The #Slope.
* @return Highest corner.
*/
static inline Corner GetHighestSlopeCorner(Slope s)
{
switch (s & ~SLOPE_HALFTILE_MASK) {
case SLOPE_W:
case SLOPE_STEEP_W: return CORNER_W;
case SLOPE_S:
case SLOPE_STEEP_S: return CORNER_S;
case SLOPE_E:
case SLOPE_STEEP_E: return CORNER_E;
case SLOPE_N:
case SLOPE_STEEP_N: return CORNER_N;
default: NOT_REACHED();
}
}
/**
* Returns the leveled halftile of a halftile slope.
*
* @pre The slope must be a halftile slope.
* @param s The #Slope.
* @return The corner of the leveled halftile.
*/
static inline Corner GetHalftileSlopeCorner(Slope s)
{
assert(IsHalftileSlope(s));
return (Corner)((s >> 6) & 3);
}
/**
* Returns the height of the highest corner of a slope relative to TileZ (= minimal height)
*
* @param s The #Slope.
* @return Relative height of highest corner.
*/
static inline uint GetSlopeMaxZ(Slope s)
{
if (s == SLOPE_FLAT) return 0;
if (IsSteepSlope(s)) return 2 * TILE_HEIGHT;
return TILE_HEIGHT;
}
/**
* Returns the opposite corner.
*
* @param corner A #Corner.
* @return The opposite corner to "corner".
*/
static inline Corner OppositeCorner(Corner corner)
{
return (Corner)(corner ^ 2);
}
/**
* Returns the slope with a specific corner raised.
*
* @param corner The #Corner.
* @return The #Slope with corner "corner" raised.
*/
static inline Slope SlopeWithOneCornerRaised(Corner corner)
{
assert(IsValidCorner(corner));
return (Slope)(1 << corner);
}
/**
* Returns the slope with all except one corner raised.
*
* @param corner The #Corner.
* @return The #Slope with all corners but "corner" raised.
*/
static inline Slope SlopeWithThreeCornersRaised(Corner corner)
{
return ComplementSlope(SlopeWithOneCornerRaised(corner));
}
/**
* Adds a halftile slope to a slope.
*
* @param s #Slope without a halftile slope.
* @param corner The #Corner of the halftile.
* @return The #Slope s with the halftile slope added.
*/
static inline Slope HalftileSlope(Slope s, Corner corner)
{
assert(IsValidCorner(corner));
return (Slope)(s | SLOPE_HALFTILE | (corner << 6));
}
/**
* Enumeration for Foundations.
*/
enum Foundation {
FOUNDATION_NONE, ///< The tile has no foundation, the slope remains unchanged.
FOUNDATION_LEVELED, ///< The tile is leveled up to a flat slope.
FOUNDATION_INCLINED_X, ///< The tile has an along X-axis inclined foundation.
FOUNDATION_INCLINED_Y, ///< The tile has an along Y-axis inclined foundation.
FOUNDATION_STEEP_LOWER, ///< The tile has a steep slope. The lowerst corner is raised by a foundation to allow building railroad on the lower halftile.
FOUNDATION_STEEP_HIGHER, ///< The tile has a steep slope. Three corners are raised by a foundation to allow building railroad on the higher halftile.
FOUNDATION_INVALID = 0xFF ///< Used inside "rail_cmd.cpp" to indicate invalid slope/track combination.
};
/**
* Tests for FOUNDATION_NONE.
*
* @param f Maybe a #Foundation.
* @return true iff f is a foundation.
*/
static inline bool IsFoundation(Foundation f)
{
return f != FOUNDATION_NONE;
}
/**
* Tests if the foundation is a leveled foundation.
*
* @param f The #Foundation.
* @return true iff f is a leveled foundation.
*/
static inline bool IsLeveledFoundation(Foundation f)
{
return f == FOUNDATION_LEVELED;
}
/**
* Tests if the foundation is an inclined foundation.
*
* @param f The #Foundation.
* @return true iff f is an inclined foundation.
*/
static inline bool IsInclinedFoundation(Foundation f)
{
return (f == FOUNDATION_INCLINED_X) || (f == FOUNDATION_INCLINED_Y);
}
/**
* Returns the foundation needed to flatten a slope.
* The returned foundation is either FOUNDATION_NONE if the tile was already flat, or FOUNDATION_LEVELED.
*
* @pre The slope must not be steep.
* @param s The current #Slope.
* @return The needed #Foundation.
*/
static inline Foundation FlatteningFoundation(Slope s)
{
assert(!IsSteepSlope(s));
return (s == SLOPE_FLAT ? FOUNDATION_NONE : FOUNDATION_LEVELED);
}
/**
* Returns the along a specific axis inclined foundation.
*
* @param axis The #Axis.
* @return The needed #Foundation.
*/
static inline Foundation InclinedFoundation(Axis axis)
{
return (axis == AXIS_X ? FOUNDATION_INCLINED_X : FOUNDATION_INCLINED_Y);
}
#endif /* SLOPE_H */
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