scummvm/engines/hugo/route.cpp
2011-02-18 22:43:38 +01:00

533 lines
17 KiB
C++

/* ScummVM - Graphic Adventure Engine
*
* ScummVM is the legal property of its developers, whose names
* are too numerous to list here. Please refer to the COPYRIGHT
* file distributed with this source distribution.
*
* This program 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; either version 2
* of the License, or (at your option) any later version.
* This program 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 this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*
* $URL$
* $Id$
*
*/
/*
* This code is based on original Hugo Trilogy source code
*
* Copyright (c) 1989-1995 David P. Gray
*
*/
// Find shortest route from hero to destination
#include "common/system.h"
#include "hugo/hugo.h"
#include "hugo/game.h"
#include "hugo/route.h"
#include "hugo/object.h"
#include "hugo/inventory.h"
#include "hugo/mouse.h"
namespace Hugo {
Route::Route(HugoEngine *vm) : _vm(vm) {
_oldWalkDirection = 0;
_routeIndex = -1; // Hero not following a route
_routeType = kRouteSpace; // Hero walking to space
_routeObjId = -1; // Hero not walking to anything
}
void Route::resetRoute() {
_routeIndex = -1;
}
int16 Route::getRouteIndex() const {
return _routeIndex;
}
/**
* Face hero in new direction, based on cursor key input by user.
*/
void Route::setDirection(const uint16 keyCode) {
debugC(1, kDebugRoute, "setDirection(%d)", keyCode);
object_t *obj = _vm->_hero; // Pointer to hero object
// Set first image in sequence
switch (keyCode) {
case Common::KEYCODE_UP:
case Common::KEYCODE_KP8:
obj->currImagePtr = obj->seqList[_UP].seqPtr;
break;
case Common::KEYCODE_DOWN:
case Common::KEYCODE_KP2:
obj->currImagePtr = obj->seqList[DOWN].seqPtr;
break;
case Common::KEYCODE_LEFT:
case Common::KEYCODE_KP4:
obj->currImagePtr = obj->seqList[LEFT].seqPtr;
break;
case Common::KEYCODE_RIGHT:
case Common::KEYCODE_KP6:
obj->currImagePtr = obj->seqList[RIGHT].seqPtr;
break;
case Common::KEYCODE_HOME:
case Common::KEYCODE_KP7:
obj->currImagePtr = obj->seqList[LEFT].seqPtr;
break;
case Common::KEYCODE_END:
case Common::KEYCODE_KP1:
obj->currImagePtr = obj->seqList[LEFT].seqPtr;
break;
case Common::KEYCODE_PAGEUP:
case Common::KEYCODE_KP9:
obj->currImagePtr = obj->seqList[RIGHT].seqPtr;
break;
case Common::KEYCODE_PAGEDOWN:
case Common::KEYCODE_KP3:
obj->currImagePtr = obj->seqList[RIGHT].seqPtr;
break;
}
}
/**
* Set hero walking, based on cursor key input by user.
* Hitting same key twice will stop hero.
*/
void Route::setWalk(const uint16 direction) {
debugC(1, kDebugRoute, "setWalk(%d)", direction);
object_t *obj = _vm->_hero; // Pointer to hero object
if (_vm->getGameStatus().storyModeFl || obj->pathType != kPathUser) // Make sure user has control
return;
if (!obj->vx && !obj->vy)
_oldWalkDirection = 0; // Fix for consistant restarts
if (direction != _oldWalkDirection) {
// Direction has changed
setDirection(direction); // Face new direction
obj->vx = obj->vy = 0;
switch (direction) { // And set correct velocity
case Common::KEYCODE_UP:
case Common::KEYCODE_KP8:
obj->vy = -kStepDy;
break;
case Common::KEYCODE_DOWN:
case Common::KEYCODE_KP2:
obj->vy = kStepDy;
break;
case Common::KEYCODE_LEFT:
case Common::KEYCODE_KP4:
obj->vx = -kStepDx;
break;
case Common::KEYCODE_RIGHT:
case Common::KEYCODE_KP6:
obj->vx = kStepDx;
break;
case Common::KEYCODE_HOME:
case Common::KEYCODE_KP7:
obj->vx = -kStepDx;
// Note: in v1 Dos and v2 Dos, obj->vy is set to DY
obj->vy = -kStepDy / 2;
break;
case Common::KEYCODE_END:
case Common::KEYCODE_KP1:
obj->vx = -kStepDx;
// Note: in v1 Dos and v2 Dos, obj->vy is set to -DY
obj->vy = kStepDy / 2;
break;
case Common::KEYCODE_PAGEUP:
case Common::KEYCODE_KP9:
obj->vx = kStepDx;
// Note: in v1 Dos and v2 Dos, obj->vy is set to -DY
obj->vy = -kStepDy / 2;
break;
case Common::KEYCODE_PAGEDOWN:
case Common::KEYCODE_KP3:
obj->vx = kStepDx;
// Note: in v1 Dos and v2 Dos, obj->vy is set to DY
obj->vy = kStepDy / 2;
break;
}
_oldWalkDirection = direction;
obj->cycling = kCycleForward;
} else {
// Same key twice - halt hero
obj->vy = 0;
obj->vx = 0;
_oldWalkDirection = 0;
obj->cycling = kCycleNotCycling;
}
}
/**
* Recursive algorithm! Searches from hero to dest_x, dest_y
* Find horizontal line segment about supplied point and recursively
* find line segments for each point above and below that segment.
* When destination point found in segment, start surfacing and leave
* a trail in segment[] from destination back to hero.
*
* Note: there is a bug which allows a route through a 1-pixel high
* narrow gap if between 2 segments wide enough for hero. To work
* around this, make sure any narrow gaps are 2 or more pixels high.
* An example of this was the blocking guard in Hugo1/Dead-End.
*/
void Route::segment(int16 x, int16 y) {
debugC(1, kDebugRoute, "segment(%d, %d)", x, y);
// Note: use of static - can't waste stack
static image_pt p; // Ptr to _boundaryMap[y]
static segment_t *seg_p; // Ptr to segment
// Bomb out if stack exhausted
// Vinterstum: Is this just a safeguard, or actually used?
//_fullStackFl = _stackavail () < 256;
_fullStackFl = false;
// Find and fill on either side of point
p = _boundaryMap[y];
int16 x1, x2; // Range of segment
for (x1 = x; x1 > 0; x1--) {
if (p[x1] == 0) {
p[x1] = kMapFill;
} else {
break;
}
}
for (x2 = x + 1; x2 < kXPix; x2++) {
if (p[x2] == 0) {
p[x2] = kMapFill;
} else {
break;
}
}
x1++;
x2--;
// Discard path if not wide enough for hero - dead end
if (_heroWidth > x2 - x1 + 1)
return;
// Have we found the destination yet?
if (y == _destY && x1 <= _destX && x2 >= _destX)
_routeFoundFl = true;
// Bounds check y in case no boundary around screen
if (y <= 0 || y >= kYPix - 1)
return;
if (_vm->_hero->x < x1) {
// Hero x not in segment, search x1..x2
// Find all segments above current
for (x = x1; !(_routeFoundFl | _fullStackFl | _fullSegmentFl) && x <= x2; x++) {
if (_boundaryMap[y - 1][x] == 0)
segment(x, y - 1);
}
// Find all segments below current
for (x = x1; !(_routeFoundFl | _fullStackFl | _fullSegmentFl) && x <= x2; x++) {
if (_boundaryMap[y + 1][x] == 0)
segment(x, y + 1);
}
} else if (_vm->_hero->x + kHeroMaxWidth > x2) {
// Hero x not in segment, search x1..x2
// Find all segments above current
for (x = x2; !(_routeFoundFl | _fullStackFl | _fullSegmentFl) && x >= x1; x--) {
if (_boundaryMap[y - 1][x] == 0)
segment(x, y - 1);
}
// Find all segments below current
for (x = x2; !(_routeFoundFl | _fullStackFl | _fullSegmentFl) && x >= x1; x--) {
if (_boundaryMap[y + 1][x] == 0)
segment(x, y + 1);
}
} else {
// Organize search around hero x position - this gives
// better chance for more direct route.
for (x = _vm->_hero->x; !(_routeFoundFl | _fullStackFl | _fullSegmentFl) && x <= x2; x++) {
if (_boundaryMap[y - 1][x] == 0)
segment(x, y - 1);
}
for (x = x1; !(_routeFoundFl | _fullStackFl | _fullSegmentFl) && x < _vm->_hero->x; x++) {
if (_boundaryMap[y - 1][x] == 0)
segment(x, y - 1);
}
for (x = _vm->_hero->x; !(_routeFoundFl | _fullStackFl | _fullSegmentFl) && x <= x2; x++) {
if (_boundaryMap[y + 1][x] == 0)
segment(x, y + 1);
}
for (x = x1; !(_routeFoundFl | _fullStackFl | _fullSegmentFl) && x < _vm->_hero->x; x++) {
if (_boundaryMap[y + 1][x] == 0)
segment(x, y + 1);
}
}
// If found, surface, leaving trail back to hero
if (_routeFoundFl) {
// Bomb out if too many segments (leave one spare)
if (_segmentNumb >= kMaxSeg - 1) {
_fullSegmentFl = true;
} else {
// Create segment
seg_p = &_segment[_segmentNumb];
seg_p->y = y;
seg_p->x1 = x1;
seg_p->x2 = x2;
_segmentNumb++;
}
}
}
/**
* Create and return ptr to new node. Initialize with previous node.
* Returns 0 if MAX_NODES exceeded
*/
Point *Route::newNode() {
debugC(1, kDebugRoute, "newNode");
_routeListIndex++;
if (_routeListIndex >= kMaxNodes) // Too many nodes
return 0; // Incomplete route - failure
_route[_routeListIndex] = _route[_routeListIndex - 1]; // Initialize with previous node
return &_route[_routeListIndex];
}
/**
* Construct route to cx, cy. Return TRUE if successful.
* 1. Copy boundary bitmap to local byte map (include object bases)
* 2. Construct list of segments segment[] from hero to destination
* 3. Compress to shortest route in route[]
*/
bool Route::findRoute(const int16 cx, const int16 cy) {
debugC(1, kDebugRoute, "findRoute(%d, %d)", cx, cy);
// Initialize for search
_routeFoundFl = false; // Path not found yet
_fullStackFl = false; // Stack not exhausted
_fullSegmentFl = false; // Segments not exhausted
_segmentNumb = 0; // Segment index
_heroWidth = kHeroMinWidth; // Minimum width of hero
_destY = cy; // Destination coords
_destX = cx; // Destination coords
int16 herox1 = _vm->_hero->x + _vm->_hero->currImagePtr->x1; // Hero baseline
int16 herox2 = _vm->_hero->x + _vm->_hero->currImagePtr->x2; // Hero baseline
int16 heroy = _vm->_hero->y + _vm->_hero->currImagePtr->y2; // Hero baseline
// Store all object baselines into objbound (except hero's = [0])
object_t *obj; // Ptr to object
int i;
for (i = 1, obj = &_vm->_object->_objects[i]; i < _vm->_object->_numObj; i++, obj++) {
if ((obj->screenIndex == *_vm->_screen_p) && (obj->cycling != kCycleInvisible) && (obj->priority == kPriorityFloating))
_vm->_object->storeBoundary(obj->oldx + obj->currImagePtr->x1, obj->oldx + obj->currImagePtr->x2, obj->oldy + obj->currImagePtr->y2);
}
// Combine objbound and boundary bitmaps to local byte map
for (uint16 y = 0; y < kYPix; y++) {
for (uint16 x = 0; x < kCompLineSize; x++) {
uint16 boundIdx = y * kCompLineSize + x;
for (i = 0; i < 8; i++)
_boundaryMap[y][x * 8 + i] = ((_vm->_object->getObjectBoundary(boundIdx) | _vm->_object->getBoundaryOverlay(boundIdx)) & (0x80 >> i)) ? kMapBound : 0;
}
}
// Clear all object baselines from objbound
for (i = 0, obj = _vm->_object->_objects; i < _vm->_object->_numObj; i++, obj++) {
if ((obj->screenIndex == *_vm->_screen_p) && (obj->cycling != kCycleInvisible) && (obj->priority == kPriorityFloating))
_vm->_object->clearBoundary(obj->oldx + obj->currImagePtr->x1, obj->oldx + obj->currImagePtr->x2, obj->oldy + obj->currImagePtr->y2);
}
// Search from hero to destination
segment(herox1, heroy);
// Not found or not enough stack or MAX_SEG exceeded
if (!_routeFoundFl || _fullStackFl || _fullSegmentFl) {
return false;
}
// Now find the route of nodes from destination back to hero
// Assign first node as destination
_route[0].x = _destX;
_route[0].y = _destY;
// Make a final segment for hero's base (we left a spare)
_segment[_segmentNumb].y = heroy;
_segment[_segmentNumb].x1 = herox1;
_segment[_segmentNumb].x2 = herox2;
_segmentNumb++;
Point *routeNode; // Ptr to route node
// Look in segments[] for straight lines from destination to hero
for (i = 0, _routeListIndex = 0; i < _segmentNumb - 1; i++) {
if ((routeNode = newNode()) == 0) // New node for new segment
return false; // Too many nodes
routeNode->y = _segment[i].y;
// Look ahead for furthest straight line
for (int16 j = i + 1; j < _segmentNumb; j++) {
segment_t *seg_p = &_segment[j];
// Can we get to this segment from previous node?
if (seg_p->x1 <= routeNode->x && seg_p->x2 >= routeNode->x + _heroWidth - 1) {
routeNode->y = seg_p->y; // Yes, keep updating node
} else {
// No, create another node on previous segment to reach it
if ((routeNode = newNode()) == 0) // Add new route node
return false; // Too many nodes
// Find overlap between old and new segments
int16 x1 = MAX(_segment[j - 1].x1, seg_p->x1);
int16 x2 = MIN(_segment[j - 1].x2, seg_p->x2);
// If room, add a little offset to reduce staircase effect
int16 dx = kHeroMaxWidth >> 1;
if (x2 - x1 < _heroWidth + dx)
dx = 0;
// Bear toward final hero position
if (j == _segmentNumb - 1)
routeNode->x = herox1;
else if (herox1 < x1)
routeNode->x = x1 + dx;
else if (herox1 > x2 - _heroWidth + 1)
routeNode->x = x2 - _heroWidth - dx;
else
routeNode->x = herox1;
i = j - 2; // Restart segment (-1 to offset auto increment)
break;
}
}
// Terminate loop if we've reached hero
if (routeNode->x == herox1 && routeNode->y == heroy)
break;
}
return true;
}
/**
* Process hero in route mode - called from Move_objects()
*/
void Route::processRoute() {
debugC(1, kDebugRoute, "processRoute");
static bool turnedFl = false; // Used to get extra cylce for turning
if (_routeIndex < 0)
return;
// Current hero position
int16 herox = _vm->_hero->x + _vm->_hero->currImagePtr->x1;
int16 heroy = _vm->_hero->y + _vm->_hero->currImagePtr->y2;
Point *routeNode = &_route[_routeIndex];
// Arrived at node?
if (abs(herox - routeNode->x) < kStepDx + 1 && abs(heroy - routeNode->y) < kStepDy) {
// kStepDx too low
// Close enough - position hero exactly
_vm->_hero->x = _vm->_hero->oldx = routeNode->x - _vm->_hero->currImagePtr->x1;
_vm->_hero->y = _vm->_hero->oldy = routeNode->y - _vm->_hero->currImagePtr->y2;
_vm->_hero->vx = _vm->_hero->vy = 0;
_vm->_hero->cycling = kCycleNotCycling;
// Arrived at final node?
if (--_routeIndex < 0) {
// See why we walked here
switch (_routeType) {
case kRouteExit: // Walked to an exit, proceed into it
setWalk(_vm->_mouse->getDirection(_routeObjId));
break;
case kRouteLook: // Look at an object
if (turnedFl) {
_vm->_object->lookObject(&_vm->_object->_objects[_routeObjId]);
turnedFl = false;
} else {
setDirection(_vm->_object->_objects[_routeObjId].direction);
_routeIndex++; // Come round again
turnedFl = true;
}
break;
case kRouteGet: // Get (or use) an object
if (turnedFl) {
_vm->_object->useObject(_routeObjId);
turnedFl = false;
} else {
setDirection(_vm->_object->_objects[_routeObjId].direction);
_routeIndex++; // Come round again
turnedFl = true;
}
break;
default:
break;
}
}
} else if (_vm->_hero->vx == 0 && _vm->_hero->vy == 0) {
// Set direction of travel if at a node
// Note realignment when changing to (thinner) up/down sprite,
// otherwise hero could bump into boundaries along route.
if (herox < routeNode->x) {
setWalk(Common::KEYCODE_RIGHT);
} else if (herox > routeNode->x) {
setWalk(Common::KEYCODE_LEFT);
} else if (heroy < routeNode->y) {
setWalk(Common::KEYCODE_DOWN);
_vm->_hero->x = _vm->_hero->oldx = routeNode->x - _vm->_hero->currImagePtr->x1;
} else if (heroy > routeNode->y) {
setWalk(Common::KEYCODE_UP);
_vm->_hero->x = _vm->_hero->oldx = routeNode->x - _vm->_hero->currImagePtr->x1;
}
}
}
/**
* Start a new route from hero to cx, cy
* go_for is the purpose, id indexes the exit or object to walk to
* Returns FALSE if route not found
*/
bool Route::startRoute(const go_t routeType, const int16 objId, int16 cx, int16 cy) {
debugC(1, kDebugRoute, "startRoute(%d, %d, %d, %d)", routeType, objId, cx, cy);
// Don't attempt to walk if user does not have control
if (_vm->_hero->pathType != kPathUser)
return false;
// if inventory showing, make it go away
if (_vm->_inventory->getInventoryState() != kInventoryOff)
_vm->_inventory->setInventoryState(kInventoryUp);
_routeType = routeType; // Purpose of trip
_routeObjId = objId; // Index of exit/object
// Adjust destination to center hero if walking to cursor
if (_routeType == kRouteSpace)
cx -= kHeroMinWidth / 2;
bool foundFl = false; // TRUE if route found ok
if ((foundFl = findRoute(cx, cy))) { // Found a route?
_routeIndex = _routeListIndex; // Node index
_vm->_hero->vx = _vm->_hero->vy = 0; // Stop manual motion
}
return foundFl;
}
} // End of namespace Hugo