/* 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. * * Additional copyright for this file: * Copyright (C) 1994-1998 Revolution Software Ltd. * * 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. */ #include "common/memstream.h" #include "common/textconsole.h" #include "sword2/sword2.h" #include "sword2/defs.h" #include "sword2/header.h" #include "sword2/logic.h" #include "sword2/resman.h" #include "sword2/router.h" #include "sword2/screen.h" namespace Sword2 { // --------------------------------------------------------------------------- // ROUTER.CPP by James // // A rehash of Jeremy's original jrouter.c, containing low-level system // routines for calculating routes between points inside a walk-grid, and // constructing walk animations from mega-sets. // // jrouter.c underwent 2 major reworks from the original: // (1) Restructured to allow more flexibility in the mega-sets, ie. more info // taken from the walk-data // - the new George & Nico mega-sets & walk-data were then tested & // tweaked in the Sword1 system // (2) Updated for the new Sword2 system, ie. new object structures // - now compatible with Sword2, the essential code already having been // tested // // --------------------------------------------------------------------------- /**************************************************************************** * JROUTER.C polygon router with modular walks * using a tree of modules * 21 july 94 * 3 november 94 * System currently works by scanning grid data and coming up with a ROUTE * as a series of way points(nodes), the smoothest eight directional PATH * through these nodes is then found, and a WALK created to fit the PATH. * * Two funtions are called by the user, RouteFinder creates a route as a * module list, HardWalk creates an animation list from the module list. * The split is only provided to allow the possibility of turning the * autorouter over two game cycles. **************************************************************************** * * Routine timings on osborne 486 * * Read floor resource (file already loaded) 112 pixels * * Read mega resource (file already loaded) 112 pixels * * * **************************************************************************** * * Modified 12 Oct 95 * * Target Points within 1 pixel of a line are ignored ??? * * Modules split into Points within 1 pixel of a line are ignored ??? * **************************************************************************** * * TOTALLY REHASHED BY JAMES FOR NEW MEGAS USING OLD SYSTEM * THEN REINCARNATED BY JAMES FOR NEW MEGAS USING NEW SYSTEM * ****************************************************************************/ //---------------------------------------------------------- // (4) WALK-GRID FILES //---------------------------------------------------------- // a walk-grid file consists of: // // standard file header // walk-grid file header // walk-grid data // Walk-Grid Header - taken directly from old "header.h" in STD_INC struct WalkGridHeader { int32 numBars; // number of bars on the floor int32 numNodes; // number of nodes }; uint8 Router::returnSlotNo(uint32 megaId) { if (_vm->_logic->readVar(ID) == CUR_PLAYER_ID) { // George (8) return 0; } else { // One of Nico's mega id's return 1; } } void Router::allocateRouteMem() { uint8 slotNo; // Player character always always slot 0, while the other mega // (normally Nico) always uses slot 1 // Better this way, so that if mega object removed from memory while // in middle of route, the old route will be safely cleared from // memory just before they create a new one slotNo = returnSlotNo(_vm->_logic->readVar(ID)); // if this slot is already used, then it can't be needed any more // because this id is creating a new route! if (_routeSlots[slotNo]) freeRouteMem(); _routeSlots[slotNo] = (WalkData *)malloc(sizeof(WalkData) * O_WALKANIM_SIZE); // 12000 bytes were used for this in Sword1 mega compacts, based on // 20 bytes per 'WalkData' frame // ie. allowing for 600 frames including end-marker // Now 'WalkData' is 8 bytes, so 8*600 = 4800 bytes. // Note that a 600 frame walk lasts about 48 seconds! // (600fps / 12.5s = 48s) // mega keeps note of which slot contains the pointer to it's walk // animation mem block // +1 so that '0' can mean "not walking" // megaObject->route_slot_id = slotNo + 1; } WalkData *Router::getRouteMem() { uint8 slotNo = returnSlotNo(_vm->_logic->readVar(ID)); return (WalkData *)_routeSlots[slotNo]; } void Router::freeRouteMem() { uint8 slotNo = returnSlotNo(_vm->_logic->readVar(ID)); free(_routeSlots[slotNo]); _routeSlots[slotNo] = NULL; } void Router::freeAllRouteMem() { for (int i = 0; i < TOTAL_ROUTE_SLOTS; i++) { free(_routeSlots[i]); _routeSlots[i] = NULL; } } int32 Router::routeFinder(byte *ob_mega, byte *ob_walkdata, int32 x, int32 y, int32 dir) { /********************************************************************* * RouteFinder.C polygon router with modular walks * 21 august 94 * 3 november 94 * routeFinder creates a list of modules that enables HardWalk to * create an animation list. * * routeFinder currently works by scanning grid data and coming up * with a ROUTE as a series of way points(nodes), the smoothest eight * directional PATH through these nodes is then found, this * information is made available to HardWalk for a WALK to be created * to fit the PATH. * * 30 november 94 return values modified * * return 0 = failed to find a route * * 1 = found a route * * 2 = mega already at target * *********************************************************************/ int32 routeFlag = 0; int32 solidFlag = 0; WalkData *walkAnim; // megaId = id; setUpWalkGrid(ob_mega, x, y, dir); loadWalkData(ob_walkdata); walkAnim = getRouteMem(); // All route data now loaded start finding a route // Check if we can get a route through the floor. changed 12 Oct95 JPS routeFlag = getRoute(); switch (routeFlag) { case 2: // special case for zero length route // if target direction specified as any if (_targetDir > 7) _targetDir = _startDir; // just a turn on the spot is required set an end module for // the route let the animator deal with it // modularPath is normally set by extractRoute _modularPath[0].dir = _startDir; _modularPath[0].num = 0; _modularPath[0].x = _startX; _modularPath[0].y = _startY; _modularPath[1].dir = _targetDir; _modularPath[1].num = 0; _modularPath[1].x = _startX; _modularPath[1].y = _startY; _modularPath[2].dir = 9; _modularPath[2].num = ROUTE_END_FLAG; slidyWalkAnimator(walkAnim); routeFlag = 2; break; case 1: // A normal route. Convert the route to an exact path smoothestPath(); // The Route had waypoints and direction options // The Path is an exact set of lines in 8 directions that // reach the target. // The path is in module format, but steps taken in each // direction are not accurate // if target dir = 8 then the walk isn't linked to an anim so // we can create a route without sliding and miss the exact // target #ifndef FORCE_SLIDY if (_targetDir == 8) { // can end facing ANY direction (ie. exact end // position not vital) - so use SOLID walk to // avoid sliding to exact position solidPath(); solidFlag = solidWalkAnimator(walkAnim); } #endif if (!solidFlag) { // if we failed to create a SOLID route, do a SLIDY // one instead slidyPath(); slidyWalkAnimator(walkAnim); } break; default: // Route didn't reach target so assume point was off the floor // routeFlag = 0; break; } return routeFlag; // send back null route } int32 Router::getRoute() { /********************************************************************* * GetRoute.C extract a path from walk grid * 12 october 94 * * GetRoute currently works by scanning grid data and coming up with * a ROUTE as a series of way points(nodes). * * static routeData _route[O_ROUTE_SIZE]; * * return 0 = failed to find a route * * 1 = found a route * * 2 = mega already at target * * 3 = failed to find a route because target was on a line * *********************************************************************/ int32 routeGot = 0; if (_startX == _targetX && _startY == _targetY) routeGot = 2; else { // 'else' added by JEL (23jan96) otherwise 'routeGot' affected // even when already set to '2' above - causing some 'turns' // to walk downwards on the spot // returns 3 if target on a line ( +- 1 pixel ) routeGot = checkTarget(_targetX, _targetY); } if (routeGot == 0) { // still looking for a route check if target is within a pixel // of a line // scan through the nodes linking each node to its nearest // neighbor until no more nodes change // This is the routine that finds a route using scan() int32 level = 1; while (scan(level)) level++; // Check to see if the route reached the target if (_node[_nNodes].dist < 9999) { // it did so extract the route as nodes and the // directions to go between each node routeGot = 1; extractRoute(); // route.X,route.Y and route.Dir now hold all the // route infomation with the target dir or route // continuation } } return routeGot; } // THE SLIDY PATH ROUTINES int32 Router::smoothestPath() { // This is the second big part of the route finder and the the only // bit that tries to be clever (the other bits are clever). // // This part of the autorouter creates a list of modules from a set of // lines running across the screen. The task is complicated by two // things: // // Firstly in choosing a route through the maze of nodes the routine // tries to minimise the amount of each individual turn avoiding 90 // degree and greater turns (where possible) and reduces the total // number of turns (subject to two 45 degree turns being better than // one 90 degree turn). // // Secondly when walking in a given direction the number of steps // required to reach the end of that run is not calculated accurately. // This is because I was unable to derive a function to relate number // of steps taken between two points to the shrunken step size int i; int32 steps = 0; int32 lastDir; int32 tempturns[4]; int32 turns[4]; const int32 turntable[NO_DIRECTIONS] = { 0, 1, 3, 5, 7, 5, 3, 1 }; // route.X route.Y and route.Dir start at far end _smoothPath[0].x = _startX; _smoothPath[0].y = _startY; _smoothPath[0].dir = _startDir; _smoothPath[0].num = 0; lastDir = _startDir; // for each section of the route for (int p = 0; p < _routeLength; p++) { int32 dirS = _route[p].dirS; int32 dirD = _route[p].dirD; int32 nextDirS = _route[p + 1].dirS; int32 nextDirD = _route[p + 1].dirD; // Check directions into and out of a pair of nodes going in int32 dS = dirS - lastDir; if (dS < 0) dS = dS + NO_DIRECTIONS; int32 dD = dirD - lastDir; if (dD < 0) dD = dD + NO_DIRECTIONS; // coming out int32 dSS = dirS - nextDirS; if (dSS < 0) dSS = dSS + NO_DIRECTIONS; int32 dDD = dirD - nextDirD; if (dDD < 0) dDD = dDD + NO_DIRECTIONS; int32 dSD = dirS - nextDirD; if (dSD < 0) dSD = dSD + NO_DIRECTIONS; int32 dDS = dirD - nextDirS; if (dDS < 0) dDS = dDS + NO_DIRECTIONS; // Determine the amount of turning involved in each possible path dS = turntable[dS]; dD = turntable[dD]; dSS = turntable[dSS]; dDD = turntable[dDD]; dSD = turntable[dSD]; dDS = turntable[dDS]; // get the best path out ie assume next section uses best direction if (dSD < dSS) dSS = dSD; if (dDS < dDD) dDD = dDS; // Rate each option. Split routes look crap so weight against them tempturns[0] = dS + dSS + 3; turns[0] = 0; tempturns[1] = dS + dDD; turns[1] = 1; tempturns[2] = dD + dSS; turns[2] = 2; tempturns[3] = dD + dDD + 3; turns[3] = 3; // set up turns as a sorted array of the turn values for (i = 0; i < 3; i++) { for (int j = 0; j < 3; j++) { if (tempturns[j] > tempturns[j + 1]) { SWAP(turns[j], turns[j + 1]); SWAP(tempturns[j], tempturns[j + 1]); } } } // best option matched in order of the priority we would like // to see on the screen but each option must be checked to see // if it can be walked int32 options = newCheck(1, _route[p].x, _route[p].y, _route[p + 1].x, _route[p + 1].y); assert(options); for (i = 0; i < 4; ++i) { int32 opt = 1 << turns[i]; if (options & opt) { smoothCheck(steps, turns[i], p, dirS, dirD); break; } } assert(i < 4); // route.X route.Y route.dir and bestTurns start at far end } // best turns will end heading as near as possible to target dir rest // is down to anim for now _smoothPath[steps].dir = 9; _smoothPath[steps].num = ROUTE_END_FLAG; return 1; } void Router::smoothCheck(int32 &k, int32 best, int32 p, int32 dirS, int32 dirD) { /********************************************************************* * Slip sliding away * This path checker checks to see if a walk that exactly follows the * path would be valid. This should be inherently true for atleast one * of the turn options. * No longer checks the data it only creates the smoothPath array JPS *********************************************************************/ int32 dsx, dsy; int32 ddx, ddy; int32 ss0, ss1, ss2; int32 sd0, sd1, sd2; if (p == 0) k = 1; int32 x = _route[p].x; int32 y = _route[p].y; int32 x2 = _route[p + 1].x; int32 y2 = _route[p + 1].y; int32 ldx = x2 - x; int32 ldy = y2 - y; int32 dirX = 1; int32 dirY = 1; if (ldx < 0) { ldx = -ldx; dirX = -1; } if (ldy < 0) { ldy = -ldy; dirY = -1; } // set up sd0-ss2 to reflect possible movement in each direction if (dirS == 0 || dirS == 4) { // vert and diag ddx = ldx; ddy = (ldx * _diagonaly) / _diagonalx; dsy = ldy - ddy; ddx = ddx * dirX; ddy = ddy * dirY; dsy = dsy * dirY; dsx = 0; sd0 = (ddx + _modX[dirD] / 2) / _modX[dirD]; ss0 = (dsy + _modY[dirS] / 2) / _modY[dirS]; sd1 = sd0 / 2; ss1 = ss0 / 2; sd2 = sd0 - sd1; ss2 = ss0 - ss1; } else { ddy = ldy; ddx = (ldy * _diagonalx) / _diagonaly; dsx = ldx - ddx; ddy = ddy * dirY; ddx = ddx * dirX; dsx = dsx * dirX; dsy = 0; sd0 = (ddy + _modY[dirD] / 2) / _modY[dirD]; ss0 = (dsx + _modX[dirS] / 2) / _modX[dirS]; sd1 = sd0 / 2; ss1 = ss0 / 2; sd2 = sd0 - sd1; ss2 = ss0 - ss1; } switch (best) { case 0: // halfsquare, diagonal, halfsquare _smoothPath[k].x = x + dsx / 2; _smoothPath[k].y = y + dsy / 2; _smoothPath[k].dir = dirS; _smoothPath[k].num = ss1; k++; _smoothPath[k].x = x + dsx / 2 + ddx; _smoothPath[k].y = y + dsy / 2 + ddy; _smoothPath[k].dir = dirD; _smoothPath[k].num = sd0; k++; _smoothPath[k].x = x + dsx + ddx; _smoothPath[k].y = y + dsy + ddy; _smoothPath[k].dir = dirS; _smoothPath[k].num = ss2; k++; break; case 1: // square, diagonal _smoothPath[k].x = x + dsx; _smoothPath[k].y = y + dsy; _smoothPath[k].dir = dirS; _smoothPath[k].num = ss0; k++; _smoothPath[k].x = x2; _smoothPath[k].y = y2; _smoothPath[k].dir = dirD; _smoothPath[k].num = sd0; k++; break; case 2: // diagonal square _smoothPath[k].x = x + ddx; _smoothPath[k].y = y + ddy; _smoothPath[k].dir = dirD; _smoothPath[k].num = sd0; k++; _smoothPath[k].x = x2; _smoothPath[k].y = y2; _smoothPath[k].dir = dirS; _smoothPath[k].num = ss0; k++; break; default: // halfdiagonal, square, halfdiagonal _smoothPath[k].x = x + ddx / 2; _smoothPath[k].y = y + ddy / 2; _smoothPath[k].dir = dirD; _smoothPath[k].num = sd1; k++; _smoothPath[k].x = x + dsx + ddx / 2; _smoothPath[k].y = y + dsy + ddy / 2; _smoothPath[k].dir = dirS; _smoothPath[k].num = ss0; k++; _smoothPath[k].x = x2; _smoothPath[k].y = y2; _smoothPath[k].dir = dirD; _smoothPath[k].num = sd2; k++; break; } } void Router::slidyPath() { /********************************************************************* * slidyPath creates a path based on part steps with no sliding to get * as near as possible to the target without any sliding this routine * is intended for use when just clicking about. * * produce a module list from the line data *********************************************************************/ int32 smooth = 1; int32 slidy = 1; // strip out the short sections _modularPath[0].x = _smoothPath[0].x; _modularPath[0].y = _smoothPath[0].y; _modularPath[0].dir = _smoothPath[0].dir; _modularPath[0].num = 0; while (_smoothPath[smooth].num < ROUTE_END_FLAG) { int32 scale = _scaleA * _smoothPath[smooth].y + _scaleB; int32 deltaX = _smoothPath[smooth].x - _modularPath[slidy - 1].x; int32 deltaY = _smoothPath[smooth].y - _modularPath[slidy - 1].y; // quarter a step minimum int32 stepX = (scale * _modX[_smoothPath[smooth].dir]) >> 19; int32 stepY = (scale * _modY[_smoothPath[smooth].dir]) >> 19; if (ABS(deltaX) >= ABS(stepX) && ABS(deltaY) >= ABS(stepY)) { _modularPath[slidy].x = _smoothPath[smooth].x; _modularPath[slidy].y = _smoothPath[smooth].y; _modularPath[slidy].dir = _smoothPath[smooth].dir; _modularPath[slidy].num = 1; slidy++; } smooth++; } // in case the last bit had no steps if (slidy > 1) { _modularPath[slidy - 1].x = _smoothPath[smooth - 1].x; _modularPath[slidy - 1].y = _smoothPath[smooth - 1].y; } // set up the end of the walk _modularPath[slidy].x = _smoothPath[smooth - 1].x; _modularPath[slidy].y = _smoothPath[smooth - 1].y; _modularPath[slidy].dir = _targetDir; _modularPath[slidy].num = 0; slidy++; _modularPath[slidy].x = _smoothPath[smooth - 1].x; _modularPath[slidy].y = _smoothPath[smooth - 1].y; _modularPath[slidy].dir = 9; _modularPath[slidy].num = ROUTE_END_FLAG; } // SLOW IN bool Router::addSlowInFrames(WalkData *walkAnim) { if (_walkData.usingSlowInFrames && _modularPath[1].num > 0) { for (int slowInFrameNo = 0; slowInFrameNo < _walkData.nSlowInFrames[_currentDir]; slowInFrameNo++) { walkAnim[_stepCount].frame = _firstSlowInFrame[_currentDir] + slowInFrameNo; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = _currentDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; } return true; } return false; } void Router::earlySlowOut(byte *ob_mega, byte *ob_walkdata) { int32 slowOutFrameNo; int32 walk_pc; WalkData *walkAnim; ObjectMega obMega(ob_mega); debug(5, "EARLY SLOW-OUT"); loadWalkData(ob_walkdata); debug(5, "********************************"); debug(5, "_framesPerStep = %d", _framesPerStep); debug(5, "_numberOfSlowOutFrames = %d", _numberOfSlowOutFrames); debug(5, "_firstWalkingTurnLeftFrame = %d", _firstWalkingTurnLeftFrame); debug(5, "_firstWalkingTurnRightFrame = %d", _firstWalkingTurnRightFrame); debug(5, "_firstSlowOutFrame = %d", _firstSlowOutFrame); debug(5, "********************************"); walk_pc = obMega.getWalkPc(); walkAnim = getRouteMem(); // if this mega does actually have slow-out frames if (_walkData.usingSlowOutFrames) { // overwrite the next step (half a cycle) of the walk // (ie .step - 0..5) do { debug(5, "STEP NUMBER: walkAnim[%d].step = %d", walk_pc, walkAnim[walk_pc].step); debug(5, "ORIGINAL FRAME: walkAnim[%d].frame = %d", walk_pc, walkAnim[walk_pc].frame); // map from existing walk frame across to correct // frame number of slow-out - remember, there may be // more slow-out frames than walk-frames! if (walkAnim[walk_pc].frame >= _firstWalkingTurnRightFrame) { // if it's a walking turn-right, rather than a // normal step, then map it to a normal step // frame first walkAnim[walk_pc].frame -= _firstWalkingTurnRightFrame; debug(5, "MAPPED TO WALK: walkAnim[%d].frame = %d (walking turn-right frame --> walk frame)", walk_pc, walkAnim[walk_pc].frame); } else if (walkAnim[walk_pc].frame >= _firstWalkingTurnLeftFrame) { // if it's a walking turn-left, rather than a // normal step, then map it to a normal step // frame first walkAnim[walk_pc].frame -= _firstWalkingTurnLeftFrame; debug(5, "MAPPED TO WALK: walkAnim[%d].frame = %d (walking turn-left frame --> walk frame)", walk_pc, walkAnim[walk_pc].frame); } walkAnim[walk_pc].frame += _firstSlowOutFrame + ((walkAnim[walk_pc].frame / _framesPerStep) * (_numberOfSlowOutFrames - _framesPerStep)); walkAnim[walk_pc].step = 0; debug(5, "SLOW-OUT FRAME: walkAnim[%d].frame = %d",walk_pc, walkAnim[walk_pc].frame); walk_pc++; } while (walkAnim[walk_pc].step > 0); // add stationary frame(s) (OPTIONAL) for (slowOutFrameNo = _framesPerStep; slowOutFrameNo < _numberOfSlowOutFrames; slowOutFrameNo++) { walkAnim[walk_pc].frame = walkAnim[walk_pc - 1].frame + 1; debug(5, "EXTRA FRAME: walkAnim[%d].frame = %d", walk_pc, walkAnim[walk_pc].frame); walkAnim[walk_pc].step = 0; walkAnim[walk_pc].dir = walkAnim[walk_pc - 1].dir; walkAnim[walk_pc].x = walkAnim[walk_pc - 1].x; walkAnim[walk_pc].y = walkAnim[walk_pc - 1].y; walk_pc++; } } else { // this mega doesn't have slow-out frames // stand in current direction walkAnim[walk_pc].frame = _firstStandFrame + walkAnim[walk_pc - 1].dir; walkAnim[walk_pc].step = 0; walkAnim[walk_pc].dir = walkAnim[walk_pc - 1].dir; walkAnim[walk_pc].x = walkAnim[walk_pc - 1].x; walkAnim[walk_pc].y = walkAnim[walk_pc - 1].y; walk_pc++; } // end of sequence walkAnim[walk_pc].frame = 512; // so that this doesn't happen again while 'george_walking' is still // '2' walkAnim[walk_pc].step = 99; } // SLOW OUT void Router::addSlowOutFrames(WalkData *walkAnim) { int32 slowOutFrameNo; // if the mega did actually walk, we overwrite the last step (half a // cycle) with slow-out frames + add any necessary stationary frames if (_walkData.usingSlowOutFrames && _lastCount >= _framesPerStep) { // place stop frames here // slowdown at the end of the last walk slowOutFrameNo = _lastCount - _framesPerStep; debug(5, "SLOW OUT: slowOutFrameNo(%d) = _lastCount(%d) - _framesPerStep(%d)", slowOutFrameNo, _lastCount, _framesPerStep); // overwrite the last step (half a cycle) of the walk do { // map from existing walk frame across to correct // frame number of slow-out - remember, there may be // more slow-out frames than walk-frames! walkAnim[slowOutFrameNo].frame += _firstSlowOutFrame + ((walkAnim[slowOutFrameNo].frame / _framesPerStep) * (_numberOfSlowOutFrames - _framesPerStep)); // because no longer a normal walk-step walkAnim[slowOutFrameNo].step = 0; debug(5, "walkAnim[%d].frame = %d",slowOutFrameNo,walkAnim[slowOutFrameNo].frame); slowOutFrameNo++; } while (slowOutFrameNo < _lastCount); // add stationary frame(s) (OPTIONAL) for (slowOutFrameNo = _framesPerStep; slowOutFrameNo < _numberOfSlowOutFrames; slowOutFrameNo++) { walkAnim[_stepCount].frame = walkAnim[_stepCount - 1].frame + 1; debug(5, "EXTRA FRAMES: walkAnim[%d].frame = %d", _stepCount, walkAnim[_stepCount].frame); walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = walkAnim[_stepCount - 1].dir; walkAnim[_stepCount].x = walkAnim[_stepCount - 1].x; walkAnim[_stepCount].y = walkAnim[_stepCount - 1].y; _stepCount++; } } } void Router::slidyWalkAnimator(WalkData *walkAnim) { /********************************************************************* * Skidding every where HardWalk creates an animation that exactly * fits the smoothPath and uses foot slipping to fit whole steps into * the route * * Parameters: georgeg, mouseg * Returns: rout * * produce a module list from the line data *********************************************************************/ int32 left; int32 p; int32 lastDir; int32 lastRealDir; int32 turnDir; int32 scale; int32 step; int32 module; int32 moduleEnd; int32 module16X; int32 module16Y; int32 stepX; int32 stepY; int32 errorX; int32 errorY; int32 lastErrorX; int32 lastErrorY; int32 frameCount; int32 frames; p = 0; lastDir = _modularPath[0].dir; _currentDir = _modularPath[1].dir; if (_currentDir == NO_DIRECTIONS) _currentDir = lastDir; _moduleX = _startX; _moduleY = _startY; module16X = _moduleX << 16; module16Y = _moduleY << 16; _stepCount = 0; // START THE WALK WITH THE FIRST STANDFRAME THIS MAY CAUSE A DELAY // BUT IT STOPS THE PLAYER MOVING FOR COLLISIONS ARE DETECTED debug(5, "SLIDY: STARTING THE WALK"); module = _framesPerChar + lastDir; walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = lastDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; // TURN TO START THE WALK debug(5, "SLIDY: TURNING TO START THE WALK"); // rotate if we need to if (lastDir != _currentDir) { // get the direction to turn turnDir = _currentDir - lastDir; if (turnDir < 0) turnDir += NO_DIRECTIONS; if (turnDir > 4) turnDir = -1; else if (turnDir > 0) turnDir = 1; // rotate to new walk direction // for george and nico put in a head turn at the start if (_walkData.usingStandingTurnFrames) { // new frames for turn frames 29oct95jps if (turnDir < 0) module = _firstStandingTurnLeftFrame + lastDir; else module = _firstStandingTurnRightFrame + lastDir; walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = lastDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; } // rotate till were facing new dir then go back 45 degrees while (lastDir != _currentDir) { lastDir += turnDir; // new frames for turn frames 29oct95jps if (turnDir < 0) { if (lastDir < 0) lastDir += NO_DIRECTIONS; module = _firstStandingTurnLeftFrame + lastDir; } else { if (lastDir > 7) lastDir -= NO_DIRECTIONS; module = _firstStandingTurnRightFrame + lastDir; } walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = lastDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; } // the back 45 degrees bit // step back one because new head turn for george takes us // past the new dir _stepCount--; } // his head is in the right direction lastRealDir = _currentDir; // SLIDY: THE SLOW IN addSlowInFrames(walkAnim); // THE WALK debug(5, "SLIDY: THE WALK"); // start the walk on the left or right leg, depending on how the // slow-in frames were drawn // (0 = left; 1 = right) if (_walkData.leadingLeg[_currentDir] == 0) { // start the walk on the left leg (ie. at beginning of the // first step of the walk cycle) left = 0; } else { // start the walk on the right leg (ie. at beginning of the // second step of the walk cycle) left = 1; } _lastCount = _stepCount; // this ensures that we don't put in turn frames for the start lastDir = 99; // this ensures that we don't put in turn frames for the start _currentDir = 99; do { assert(_stepCount < O_WALKANIM_SIZE); while (_modularPath[p].num == 0) { p++; if (_currentDir != 99) lastRealDir = _currentDir; lastDir = _currentDir; _lastCount = _stepCount; } // calculate average amount to lose in each step on the way // to the next node _currentDir = _modularPath[p].dir; if (_currentDir < NO_DIRECTIONS) { module = _currentDir * _framesPerStep * 2 + left * _framesPerStep; left = !left; moduleEnd = module + _framesPerStep; step = 0; scale = (_scaleA * _moduleY + _scaleB); do { module16X += _walkData.dx[module] * scale; module16Y += _walkData.dy[module] * scale; _moduleX = module16X >> 16; _moduleY = module16Y >> 16; walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = step; // normally 0,1,2,3,4,5,0,1,2,etc walkAnim[_stepCount].dir = _currentDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; step++; module++; } while (module < moduleEnd); stepX = _modX[_modularPath[p].dir]; stepY = _modY[_modularPath[p].dir]; errorX = _modularPath[p].x - _moduleX; errorX = errorX * stepX; errorY = _modularPath[p].y - _moduleY; errorY = errorY * stepY; if (errorX < 0 || errorY < 0) { _modularPath[p].num = 0; // the end of the path // okay those last steps took us past our // target but do we want to scoot or moonwalk frames = _stepCount - _lastCount; errorX = _modularPath[p].x - walkAnim[_stepCount - 1].x; errorY = _modularPath[p].y - walkAnim[_stepCount - 1].y; if (frames > _framesPerStep) { lastErrorX = _modularPath[p].x - walkAnim[_stepCount - 7].x; lastErrorY = _modularPath[p].y - walkAnim[_stepCount - 7].y; if (stepX == 0) { if (3 * ABS(lastErrorY) < ABS(errorY)) { // the last stop was // closest _stepCount -= _framesPerStep; left = !left; } } else { if (3 * ABS(lastErrorX) < ABS(errorX)) { //the last stop was // closest _stepCount -= _framesPerStep; left = !left; } } } errorX = _modularPath[p].x - walkAnim[_stepCount-1].x; errorY = _modularPath[p].y - walkAnim[_stepCount-1].y; // okay we've reached the end but we still // have an error if (errorX != 0) { frameCount = 0; frames = _stepCount - _lastCount; do { frameCount++; walkAnim[_lastCount + frameCount - 1].x += errorX * frameCount / frames; } while (frameCount < frames); } if (errorY != 0) { frameCount = 0; frames = _stepCount - _lastCount; do { frameCount++; walkAnim[_lastCount + frameCount - 1].y += errorY * frameCount / frames; } while (frameCount < frames); } // Now is the time to put in the turn frames // for the last turn if (frames < _framesPerStep) { // this ensures that we don't put in // turn frames for this walk or the // next _currentDir = 99; } if (_currentDir != 99) lastRealDir = _currentDir; // check each turn condition in turn // only for george if (lastDir != 99 && _currentDir != 99 && _walkData.usingWalkingTurnFrames) { // 1 and -7 going right -1 and 7 going // left lastDir = _currentDir - lastDir; if (lastDir == -1 || lastDir == 7 || lastDir == -2 || lastDir == 6) { // turn at the end of the last // walk _frame = _lastCount - _framesPerStep; do { // turning left walkAnim[_frame].frame += _firstWalkingTurnLeftFrame; _frame++; } while (_frame < _lastCount); } else if (lastDir == 1 || lastDir == -7 || lastDir == 2 || lastDir == -6) { // turn at the end of the // current walk _frame = _lastCount - _framesPerStep; do { // turning right walkAnim[_frame].frame += _firstWalkingTurnRightFrame; _frame++; } while (_frame < _lastCount); } lastDir = _currentDir; } // all turns checked _lastCount = _stepCount; _moduleX = walkAnim[_stepCount - 1].x; _moduleY = walkAnim[_stepCount - 1].y; module16X = _moduleX << 16; module16Y = _moduleY << 16; } } } while (_modularPath[p].dir < NO_DIRECTIONS); #ifdef SWORD2_DEBUG if (lastRealDir == 99) error("slidyWalkAnimatorlast direction error"); #endif // THE SLOW OUT addSlowOutFrames(walkAnim); // TURNS TO END THE WALK ? // We've done the walk now put in any turns at the end if (_targetDir == 8) { // ANY direction -> stand in the last direction module = _firstStandFrame + lastRealDir; _targetDir = lastRealDir; walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = lastRealDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; } if (_targetDir == 9) { // 'stance' was non-zero if (_stepCount == 0) { module = _framesPerChar + lastRealDir; walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = lastRealDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; } } else if (_targetDir != lastRealDir) { // rotate to target direction turnDir = _targetDir - lastRealDir; if (turnDir < 0) turnDir += NO_DIRECTIONS; if (turnDir > 4) turnDir = -1; else if (turnDir > 0) turnDir = 1; // rotate to target direction // for george and nico put in a head turn at the start if (_walkData.usingStandingTurnFrames) { // new frames for turn frames 29oct95jps if (turnDir < 0) module = _firstStandingTurnLeftFrame + lastDir; else module = _firstStandingTurnRightFrame + lastDir; walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = lastRealDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; } // rotate if we need to while (lastRealDir != _targetDir) { lastRealDir += turnDir; // new frames for turn frames 29oct95jps if (turnDir < 0) { if (lastRealDir < 0) lastRealDir += NO_DIRECTIONS; module = _firstStandingTurnLeftFrame + lastRealDir; } else { if (lastRealDir > 7) lastRealDir -= NO_DIRECTIONS; module = _firstStandingTurnRightFrame + lastRealDir; } walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = lastRealDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; } module = _firstStandFrame + lastRealDir; walkAnim[_stepCount - 1].frame = module; } else { // just stand at the end module = _firstStandFrame + lastRealDir; walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = lastRealDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; } walkAnim[_stepCount].frame = 512; walkAnim[_stepCount].step = 99; _stepCount++; walkAnim[_stepCount].frame = 512; walkAnim[_stepCount].step = 99; _stepCount++; walkAnim[_stepCount].frame = 512; walkAnim[_stepCount].step = 99; // write all the frames to "debug.txt" debug(5, "THE WALKDATA:"); for (_frame = 0; _frame <= _stepCount; _frame++) debug(5, "walkAnim[%d].frame=%d", _frame, walkAnim[_frame].frame); debug(5, "routeFinder RouteSize is %d", _stepCount); return; } #ifndef FORCE_SLIDY // THE SOLID PATH ROUTINES void Router::solidPath() { /********************************************************************* * SolidPath creates a path based on whole steps with no sliding to * get as near as possible to the target without any sliding this * routine is currently unused, but is intended for use when just * clicking about. * * produce a module list from the line data *********************************************************************/ int32 smooth; int32 solid; int32 scale; int32 stepX; int32 stepY; int32 deltaX; int32 deltaY; // strip out the short sections solid = 1; smooth = 1; _modularPath[0].x = _smoothPath[0].x; _modularPath[0].y = _smoothPath[0].y; _modularPath[0].dir = _smoothPath[0].dir; _modularPath[0].num = 0; do { scale = _scaleA * _smoothPath[smooth].y + _scaleB; deltaX = _smoothPath[smooth].x - _modularPath[solid - 1].x; deltaY = _smoothPath[smooth].y - _modularPath[solid - 1].y; stepX = _modX[_smoothPath[smooth].dir]; stepY = _modY[_smoothPath[smooth].dir]; stepX = stepX * scale; stepY = stepY * scale; stepX = stepX >> 16; stepY = stepY >> 16; if (ABS(deltaX) >= ABS(stepX) && ABS(deltaY) >= ABS(stepY)) { _modularPath[solid].x = _smoothPath[smooth].x; _modularPath[solid].y = _smoothPath[smooth].y; _modularPath[solid].dir = _smoothPath[smooth].dir; _modularPath[solid].num = 1; solid++; } smooth++; } while (_smoothPath[smooth].num < ROUTE_END_FLAG); // in case the last bit had no steps if (solid == 1) { // there were no paths so put in a dummy end solid = 2; _modularPath[1].dir = _smoothPath[0].dir; _modularPath[1].num = 0; } _modularPath[solid - 1].x = _smoothPath[smooth - 1].x; _modularPath[solid - 1].y = _smoothPath[smooth - 1].y; // set up the end of the walk _modularPath[solid].x = _smoothPath[smooth - 1].x; _modularPath[solid].y = _smoothPath[smooth - 1].y; _modularPath[solid].dir = 9; _modularPath[solid].num = ROUTE_END_FLAG; } int32 Router::solidWalkAnimator(WalkData *walkAnim) { /********************************************************************* * SolidWalk creates an animation based on whole steps with no sliding * to get as near as possible to the target without any sliding. This * routine is is intended for use when just clicking about. * * produce a module list from the line data * * returns 0 if solid route not found *********************************************************************/ int32 left; int32 turnDir; int32 scale; int32 step; int32 errorX; int32 errorY; int32 moduleEnd; bool slowStart = false; // start at the beginning for a change int32 lastDir = _modularPath[0].dir; int32 module = _framesPerChar + lastDir; _currentDir = _modularPath[1].dir; _moduleX = _startX; _moduleY = _startY; _stepCount = 0; int32 module16X = _moduleX << 16; int32 module16Y = _moduleY << 16; // START THE WALK WITH THE FIRST STANDFRAME THIS MAY CAUSE A DELAY // BUT IT STOPS THE PLAYER MOVING FOR COLLISIONS ARE DETECTED debug(5, "SOLID: STARTING THE WALK"); walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = lastDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; // TURN TO START THE WALK debug(5, "SOLID: TURNING TO START THE WALK"); // rotate if we need to if (lastDir != _currentDir) { // get the direction to turn turnDir = _currentDir - lastDir; if (turnDir < 0) turnDir += NO_DIRECTIONS; if (turnDir > 4) turnDir = -1; else if (turnDir > 0) turnDir = 1; // rotate to new walk direction // for george and nico put in a head turn at the start if (_walkData.usingStandingTurnFrames) { // new frames for turn frames 29oct95jps if (turnDir < 0) module = _firstStandingTurnLeftFrame + lastDir; else module = _firstStandingTurnRightFrame + lastDir; walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = lastDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; } // rotate till were facing new dir then go back 45 degrees while (lastDir != _currentDir) { lastDir += turnDir; // new frames for turn frames if (turnDir < 0) { if (lastDir < 0) lastDir += NO_DIRECTIONS; module = _firstStandingTurnLeftFrame + lastDir; } else { if (lastDir > 7) lastDir -= NO_DIRECTIONS; module = _firstStandingTurnRightFrame + lastDir; } walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = lastDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; } // the back 45 degrees bit // step back one because new head turn for george takes us // past the new dir _stepCount--; } // THE SLOW IN slowStart = addSlowInFrames(walkAnim); // THE WALK debug(5, "SOLID: THE WALK"); // start the walk on the left or right leg, depending on how the // slow-in frames were drawn // (0 = left; 1 = right) if (_walkData.leadingLeg[_currentDir] == 0) { // start the walk on the left leg (ie. at beginning of the // first step of the walk cycle) left = 0; } else { // start the walk on the right leg (ie. at beginning of the // second step of the walk cycle) left = 1; } _lastCount = _stepCount; // this ensures that we don't put in turn frames for the start lastDir = 99; // this ensures that we don't put in turn frames for the start _currentDir = 99; int32 p; for (p = 1; _modularPath[p].dir < NO_DIRECTIONS; ++p) { while (_modularPath[p].num > 0) { _currentDir = _modularPath[p].dir; if (_currentDir < NO_DIRECTIONS) { module = _currentDir * _framesPerStep * 2 + left * _framesPerStep; left = !left; moduleEnd = module + _framesPerStep; step = 0; scale = (_scaleA * _moduleY + _scaleB); do { module16X += _walkData.dx[module] * scale; module16Y += _walkData.dy[module] * scale; _moduleX = module16X >> 16; _moduleY = module16Y >> 16; walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = step; // normally 0,1,2,3,4,5,0,1,2,etc walkAnim[_stepCount].dir = _currentDir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; module++; step++; } while (module < moduleEnd); errorX = _modularPath[p].x - _moduleX; errorX = errorX * _modX[_modularPath[p].dir]; errorY = _modularPath[p].y - _moduleY; errorY = errorY * _modY[_modularPath[p].dir]; if (errorX < 0 || errorY < 0) { _modularPath[p].num = 0; _stepCount -= _framesPerStep; left = !left; // Okay this is the end of a section _moduleX = walkAnim[_stepCount - 1].x; _moduleY = walkAnim[_stepCount - 1].y; module16X = _moduleX << 16; module16Y = _moduleY << 16; _modularPath[p].x = _moduleX; _modularPath[p].y = _moduleY; // Now is the time to put in the turn // frames for the last turn if (_stepCount - _lastCount < _framesPerStep) { // no step taken // clean up if a slow in but no // walk if (slowStart) { _stepCount -= _walkData.nSlowInFrames[_currentDir]; _lastCount -= _walkData.nSlowInFrames[_currentDir]; slowStart = false; } // this ensures that we don't // put in turn frames for this // walk or the next _currentDir = 99; } // check each turn condition in turn if (lastDir != 99 && _currentDir != 99 && _walkData.usingWalkingTurnFrames) { // only for george // 1 and -7 going right -1 and // 7 going left lastDir = _currentDir - lastDir; if (lastDir == -1 || lastDir == 7 || lastDir == -2 || lastDir == 6) { // turn at the end of // the last walk _frame = _lastCount - _framesPerStep; do { // turning left walkAnim[_frame].frame += _firstWalkingTurnLeftFrame; _frame++; } while (_frame < _lastCount); } else if (lastDir == 1 || lastDir == -7 || lastDir == 2 || lastDir == -6) { // turn at the end of // the current walk _frame = _lastCount - _framesPerStep; do { // turning right walkAnim[_frame].frame += _firstWalkingTurnRightFrame; _frame++; } while (_frame < _lastCount); } } // all turns checked _lastCount = _stepCount; } } } lastDir = _currentDir; // can only be valid first time round slowStart = false; } // THE SLOW OUT addSlowOutFrames(walkAnim); module = _framesPerChar + _modularPath[p - 1].dir; walkAnim[_stepCount].frame = module; walkAnim[_stepCount].step = 0; walkAnim[_stepCount].dir = _modularPath[p - 1].dir; walkAnim[_stepCount].x = _moduleX; walkAnim[_stepCount].y = _moduleY; _stepCount++; walkAnim[_stepCount].frame = 512; walkAnim[_stepCount].step = 99; _stepCount++; walkAnim[_stepCount].frame = 512; walkAnim[_stepCount].step = 99; _stepCount++; walkAnim[_stepCount].frame = 512; walkAnim[_stepCount].step = 99; debug(5, "THE WALKDATA:"); for (_frame = 0; _frame <= _stepCount; _frame++) debug(5, "walkAnim[%d].frame=%d", _frame, walkAnim[_frame].frame); // NO END TURNS debug(5, "routeFinder RouteSize is %d", _stepCount); // now check the route for (int i = 0; i < p - 1; ++i) { if (!check(_modularPath[i].x, _modularPath[i].y, _modularPath[i + 1].x, _modularPath[i + 1].y)) p = 0; } if (p != 0) { _targetDir = _modularPath[p - 1].dir; if (checkTarget(_moduleX, _moduleY) == 3) { // new target on a line p = 0; debug(5, "Solid walk target was on a line %d %d", _moduleX, _moduleY); } } return p; } #endif // THE SCAN ROUTINES bool Router::scan(int32 level) { /********************************************************************* * Called successively from routeFinder until no more changes take * place in the grid array, ie he best path has been found * * Scans through every point in the node array and checks if there is * a route between each point and if this route gives a new route. * * This routine could probably halve its processing time if it doubled * up on the checks after each route check * *********************************************************************/ int32 x1, y1, x2, y2; int32 distance; bool changed = false; // For all the nodes that have new values and a distance less than // enddist, ie dont check for new routes from a point we checked // before or from a point that is already further away than the best // route so far. for (int i = 0; i < _nNodes; i++) { if (_node[i].dist < _node[_nNodes].dist && _node[i].level == level) { x1 = _node[i].x; y1 = _node[i].y; for (int j = _nNodes; j > 0; j--) { if (_node[j].dist > _node[i].dist) { x2 = _node[j].x; y2 = _node[j].y; if (ABS(x2 - x1) > 4.5 * ABS(y2 - y1)) distance = (8 * ABS(x2 - x1) + 18 * ABS(y2 - y1)) / (54 * 8) + 1; else distance = (6 * ABS(x2 - x1) + 36 * ABS(y2 - y1)) / (36 * 14) + 1; if (distance + _node[i].dist < _node[_nNodes].dist && distance + _node[i].dist < _node[j].dist) { if (newCheck(0, x1, y1, x2, y2)) { _node[j].level = level + 1; _node[j].dist = distance + _node[i].dist; _node[j].prev = i; changed = true; } } } } } } return changed; } int32 Router::newCheck(int32 status, int32 x1, int32 y1, int32 x2, int32 y2) { /********************************************************************* * newCheck routine checks if the route between two points can be * achieved without crossing any of the bars in the Bars array. * * newCheck differs from check in that that 4 route options are * considered corresponding to actual walked routes. * * Note distance doesnt take account of shrinking ??? * * Note Bars array must be properly calculated ie min max dx dy co *********************************************************************/ int32 ldx; int32 ldy; int32 dlx; int32 dly; int32 dirX; int32 dirY; int32 step1; int32 step2; int32 step3; int32 steps; int32 options; steps = 0; options = 0; ldx = x2 - x1; ldy = y2 - y1; dirX = 1; dirY = 1; if (ldx < 0) { ldx = -ldx; dirX = -1; } if (ldy < 0) { ldy = -ldy; dirY = -1; } // make the route options if (_diagonaly * ldx > _diagonalx * ldy) { // dir = 1,2 or 2,3 or 5,6 or 6,7 dly = ldy; dlx = (ldy * _diagonalx) / _diagonaly; ldx = ldx - dlx; dlx = dlx * dirX; dly = dly * dirY; ldx = ldx * dirX; ldy = 0; // options are square, diagonal a code 1 route step1 = check(x1, y1, x1 + ldx, y1); if (step1 != 0) { step2 = check(x1 + ldx, y1, x2, y2); if (step2 != 0) { steps = step1 + step2; options |= 2; } } // diagonal, square a code 2 route if (steps == 0 || status == 1) { step1 = check(x1, y1, x1 + dlx, y1 + dly); if (step1 != 0) { step2 = check(x1 + dlx, y2, x2, y2); if (step2 != 0) { steps = step1 + step2; options |= 4; } } } // halfsquare, diagonal, halfsquare a code 0 route if (steps == 0 || status == 1) { step1 = check(x1, y1, x1 + ldx / 2, y1); if (step1 != 0) { step2 = check(x1 + ldx / 2, y1, x1 + ldx / 2 + dlx, y2); if (step2 != 0) { step3 = check(x1 + ldx / 2 + dlx, y2, x2, y2); if (step3 != 0) { steps = step1 + step2 + step3; options |= 1; } } } } // halfdiagonal, square, halfdiagonal a code 3 route if (steps == 0 || status == 1) { step1 = check(x1, y1, x1 + dlx / 2, y1 + dly / 2); if (step1 != 0) { step2 = check(x1 + dlx / 2, y1 + dly / 2, x1 + ldx + dlx / 2, y1 + dly / 2); if (step2 != 0) { step3 = check(x1 + ldx + dlx / 2, y1 + dly / 2, x2, y2); if (step3 != 0) { steps = step1 + step2 + step3; options |= 8; } } } } } else { // dir = 7,0 or 0,1 or 3,4 or 4,5 dlx = ldx; dly = (ldx * _diagonaly) / _diagonalx; ldy = ldy - dly; dlx = dlx * dirX; dly = dly * dirY; ldy = ldy * dirY; ldx = 0; // options are square, diagonal a code 1 route step1 = check(x1 ,y1, x1, y1 + ldy); if (step1 != 0) { step2 = check(x1, y1 + ldy, x2, y2); if (step2 != 0) { steps = step1 + step2; options |= 2; } } // diagonal, square a code 2 route if (steps == 0 || status == 1) { step1 = check(x1, y1, x2, y1 + dly); if (step1 != 0) { step2 = check(x2, y1 + dly, x2, y2); if (step2 != 0) { steps = step1 + step2; options |= 4; } } } // halfsquare, diagonal, halfsquare a code 0 route if (steps == 0 || status == 1) { step1 = check(x1, y1, x1, y1 + ldy / 2); if (step1 != 0) { step2 = check(x1, y1 + ldy / 2, x2, y1 + ldy / 2 + dly); if (step2 != 0) { step3 = check(x2, y1 + ldy / 2 + dly, x2, y2); if (step3 != 0) { steps = step1 + step2 + step3; options |= 1; } } } } // halfdiagonal, square, halfdiagonal a code 3 route if (steps == 0 || status == 1) { step1 = check(x1, y1, x1 + dlx / 2, y1 + dly / 2); if (step1 != 0) { step2 = check(x1 + dlx / 2, y1 + dly / 2, x1 + dlx / 2, y1 + ldy + dly / 2); if (step2 != 0) { step3 = check(x1 + dlx / 2, y1 + ldy + dly / 2, x2, y2); if (step3 != 0) { steps = step1 + step2 + step3; options |= 8; } } } } } if (status == 0) status = steps; else status = options; return status; } // CHECK ROUTINES bool Router::check(int32 x1, int32 y1, int32 x2, int32 y2) { // call the fastest line check for the given line // returns true if line didn't cross any bars if (x1 == x2 && y1 == y2) return true; if (x1 == x2) return vertCheck(x1, y1, y2); if (y1 == y2) return horizCheck(x1, y1, x2); return lineCheck(x1, y1, x2, y2); } bool Router::lineCheck(int32 x1, int32 y1, int32 x2, int32 y2) { bool linesCrossed = true; int32 xmin = MIN(x1, x2); int32 xmax = MAX(x1, x2); int32 ymin = MIN(y1, y2); int32 ymax = MAX(y1, y2); // Line set to go one step in chosen direction so ignore if it hits // anything int32 dirx = x2 - x1; int32 diry = y2 - y1; int32 co = (y1 * dirx) - (x1 * diry); // new line equation for (int i = 0; i < _nBars && linesCrossed; i++) { // skip if not on module if (xmax >= _bars[i].xmin && xmin <= _bars[i].xmax && ymax >= _bars[i].ymin && ymin <= _bars[i].ymax) { // Okay, it's a valid line. Calculate an intercept. Wow // but all this arithmetic we must have loads of time // slope it he slope between the two lines int32 slope = (_bars[i].dx * diry) - (_bars[i].dy *dirx); // assuming parallel lines don't cross if (slope != 0) { // calculate x intercept and check its on both // lines int32 xc = ((_bars[i].co * dirx) - (co * _bars[i].dx)) / slope; // skip if not on module if (xc >= xmin - 1 && xc <= xmax + 1) { // skip if not on line if (xc >= _bars[i].xmin - 1 && xc <= _bars[i].xmax + 1) { int32 yc = ((_bars[i].co * diry) - (co * _bars[i].dy)) / slope; // skip if not on module if (yc >= ymin - 1 && yc <= ymax + 1) { // skip if not on line if (yc >= _bars[i].ymin - 1 && yc <= _bars[i].ymax + 1) { linesCrossed = false; } } } } } } } return linesCrossed; } bool Router::horizCheck(int32 x1, int32 y, int32 x2) { bool linesCrossed = true; int32 xmin = MIN(x1, x2); int32 xmax = MAX(x1, x2); // line set to go one step in chosen direction so ignore if it hits // anything for (int i = 0; i < _nBars && linesCrossed; i++) { // skip if not on module if (xmax >= _bars[i].xmin && xmin <= _bars[i].xmax && y >= _bars[i].ymin && y <= _bars[i].ymax) { // Okay, it's a valid line calculate an intercept. Wow // but all this arithmetic we must have loads of time if (_bars[i].dy == 0) linesCrossed = false; else { int32 ldy = y - _bars[i].y1; int32 xc = _bars[i].x1 + (_bars[i].dx * ldy) / _bars[i].dy; // skip if not on module if (xc >= xmin - 1 && xc <= xmax + 1) linesCrossed = false; } } } return linesCrossed; } bool Router::vertCheck(int32 x, int32 y1, int32 y2) { bool linesCrossed = true; int32 ymin = MIN(y1, y2); int32 ymax = MAX(y1, y2); // Line set to go one step in chosen direction so ignore if it hits // anything for (int i = 0; i < _nBars && linesCrossed; i++) { // skip if not on module if (x >= _bars[i].xmin && x <= _bars[i].xmax && ymax >= _bars[i].ymin && ymin <= _bars[i].ymax) { // Okay, it's a valid line calculate an intercept. Wow // but all this arithmetic we must have loads of time // both lines vertical and overlap in x and y so they // cross if (_bars[i].dx == 0) linesCrossed = false; else { int32 ldx = x - _bars[i].x1; int32 yc = _bars[i].y1 + (_bars[i].dy * ldx) / _bars[i].dx; // the intercept overlaps if (yc >= ymin - 1 && yc <= ymax + 1) linesCrossed = false; } } } return linesCrossed; } int32 Router::checkTarget(int32 x, int32 y) { int32 onLine = 0; int32 xmin = x - 1; int32 xmax = x + 1; int32 ymin = y - 1; int32 ymax = y + 1; // check if point +- 1 is on the line // so ignore if it hits anything for (int i = 0; i < _nBars && onLine == 0; i++) { // overlapping line if (xmax >= _bars[i].xmin && xmin <= _bars[i].xmax && ymax >= _bars[i].ymin && ymin <= _bars[i].ymax) { int32 xc, yc; // okay this line overlaps the target calculate an y intercept for x // vertical line so we know it overlaps y if (_bars[i].dx == 0) yc = 0; else { int ldx = x - _bars[i].x1; yc = _bars[i].y1 + (_bars[i].dy * ldx) / _bars[i].dx; } // overlapping point for y if (yc >= ymin && yc <= ymax) { // target on a line so drop out onLine = 3; debug(5, "RouteFail due to target on a line %d %d", x, y); } else { // vertical line so we know it overlaps y if (_bars[i].dy == 0) xc = 0; else { int32 ldy = y - _bars[i].y1; xc = _bars[i].x1 + (_bars[i].dx * ldy) / _bars[i].dy; } // skip if not on module if (xc >= xmin && xc <= xmax) { // target on a line so drop out onLine = 3; debug(5, "RouteFail due to target on a line %d %d", x, y); } } } } return onLine; } // THE SETUP ROUTINES void Router::loadWalkData(byte *ob_walkdata) { uint16 firstFrameOfDirection; uint16 walkFrameNo; uint32 frameCounter = 0; // starts at frame 0 of mega set int i; _walkData.read(ob_walkdata); // 0 = not using slow out frames; non-zero = using that many frames // for each leading leg for each direction _numberOfSlowOutFrames = _walkData.usingSlowOutFrames; for (i = 0; i < NO_DIRECTIONS; i++) { firstFrameOfDirection = i * _walkData.nWalkFrames; _modX[i] = 0; _modY[i] = 0; for (walkFrameNo = firstFrameOfDirection; walkFrameNo < firstFrameOfDirection + _walkData.nWalkFrames / 2; walkFrameNo++) { // eg. _modX[0] is the sum of the x-step sizes for the // first half of the walk cycle for direction 0 _modX[i] += _walkData.dx[walkFrameNo]; _modY[i] += _walkData.dy[walkFrameNo]; } } _diagonalx = _modX[3]; _diagonaly = _modY[3]; // interpret the walk data _framesPerStep = _walkData.nWalkFrames / 2; _framesPerChar = _walkData.nWalkFrames * NO_DIRECTIONS; // offset pointers added Oct 30 95 JPS // mega id references removed 16sep96 by JEL // WALK FRAMES // start on frame 0 frameCounter += _framesPerChar; // STAND FRAMES // stand frames come after the walk frames // one stand frame for each direction _firstStandFrame = frameCounter; frameCounter += NO_DIRECTIONS; // STANDING TURN FRAMES - OPTIONAL! // standing turn-left frames come after the slow-out frames // one for each direction // standing turn-left frames come after the standing turn-right frames // one for each direction if (_walkData.usingStandingTurnFrames) { _firstStandingTurnLeftFrame = frameCounter; frameCounter += NO_DIRECTIONS; _firstStandingTurnRightFrame = frameCounter; frameCounter += NO_DIRECTIONS; } else { // refer instead to the normal stand frames _firstStandingTurnLeftFrame = _firstStandFrame; _firstStandingTurnRightFrame = _firstStandFrame; } // WALKING TURN FRAMES - OPTIONAL! // walking left-turn frames come after the stand frames // walking right-turn frames come after the walking left-turn frames if (_walkData.usingWalkingTurnFrames) { _firstWalkingTurnLeftFrame = frameCounter; frameCounter += _framesPerChar; _firstWalkingTurnRightFrame = frameCounter; frameCounter += _framesPerChar; } else { _firstWalkingTurnLeftFrame = 0; _firstWalkingTurnRightFrame = 0; } // SLOW-IN FRAMES - OPTIONAL! // slow-in frames come after the walking right-turn frames if (_walkData.usingSlowInFrames) { // Make note of frame number of first slow-in frame for each // direction. There may be a different number of slow-in // frames in each direction for (i = 0; i < NO_DIRECTIONS; i++) { _firstSlowInFrame[i] = frameCounter; frameCounter += _walkData.nSlowInFrames[i]; } } // SLOW-OUT FRAMES - OPTIONAL! // slow-out frames come after the slow-in frames if (_walkData.usingSlowOutFrames) _firstSlowOutFrame = frameCounter; } // THE ROUTE EXTRACTOR void Router::extractRoute() { /********************************************************************* * extractRoute gets route from the node data after a full scan, route * is written with just the basic way points and direction options for * heading to the next point. *********************************************************************/ int32 prev; int32 prevx; int32 prevy; int32 last; int32 point; int32 dirx; int32 diry; int32 dir; int32 ldx; int32 ldy; int32 p; // extract the route from the node data prev = _nNodes; last = prev; point = O_ROUTE_SIZE - 1; _route[point].x = _node[last].x; _route[point].y = _node[last].y; do { point--; prev = _node[last].prev; prevx = _node[prev].x; prevy = _node[prev].y; _route[point].x = prevx; _route[point].y = prevy; last = prev; } while (prev > 0); // now shuffle route down in the buffer _routeLength = 0; do { _route[_routeLength].x = _route[point].x; _route[_routeLength].y = _route[point].y; point++; _routeLength++; } while (point < O_ROUTE_SIZE); _routeLength--; // okay the route exists as a series point now put in some directions for (p = 0; p < _routeLength; ++p) { ldx = _route[p + 1].x - _route[p].x; ldy = _route[p + 1].y - _route[p].y; dirx = 1; diry = 1; if (ldx < 0) { ldx = -ldx; dirx = -1; } if (ldy < 0) { ldy = -ldy; diry = -1; } if (_diagonaly * ldx > _diagonalx * ldy) { // dir = 1,2 or 2,3 or 5,6 or 6,7 // 2 or 6 dir = 4 - 2 * dirx; _route[p].dirS = dir; // 1, 3, 5 or 7 dir = dir + diry * dirx; _route[p].dirD = dir; } else { // dir = 7,0 or 0,1 or 3,4 or 4,5 // 0 or 4 dir = 2 + 2 * diry; _route[p].dirS = dir; // 2 or 6 dir = 4 - 2 * dirx; // 1, 3, 5 or 7 dir = dir + diry * dirx; _route[p].dirD = dir; } } // set the last dir to continue previous route unless specified if (_targetDir == NO_DIRECTIONS) { // ANY direction _route[p].dirS = _route[p - 1].dirS; _route[p].dirD = _route[p - 1].dirD; } else { _route[p].dirS = _targetDir; _route[p].dirD = _targetDir; } return; } void Router::setUpWalkGrid(byte *ob_mega, int32 x, int32 y, int32 dir) { ObjectMega obMega(ob_mega); // get walk grid file + extra grid into 'bars' & 'node' arrays loadWalkGrid(); // copy the mega structure into the local variables for use in all // subroutines _startX = obMega.getFeetX(); _startY = obMega.getFeetY(); _startDir = obMega.getCurDir(); _targetX = x; _targetY = y; _targetDir = dir; _scaleA = obMega.getScaleA(); _scaleB = obMega.getScaleB(); // mega's current position goes into first node _node[0].x = _startX; _node[0].y = _startY; _node[0].level = 1; _node[0].prev = 0; _node[0].dist = 0; // reset other nodes for (int i = 1; i < _nNodes; i++) { _node[i].level = 0; _node[i].prev = 0; _node[i].dist = 9999; } // target position goes into final node _node[_nNodes].x = _targetX; _node[_nNodes].y = _targetY; _node[_nNodes].level = 0; _node[_nNodes].prev = 0; _node[_nNodes].dist = 9999; } void Router::plotWalkGrid() { int32 i; // get walk grid file + extra grid into 'bars' & 'node' arrays loadWalkGrid(); // lines for (i = 0; i < _nBars; i++) _vm->_screen->drawLine(_bars[i].x1, _bars[i].y1, _bars[i].x2, _bars[i].y2, 254); // nodes // leave node 0 for start node for (i = 1; i < _nNodes; i++) plotCross(_node[i].x, _node[i].y, 184); } void Router::plotCross(int16 x, int16 y, uint8 color) { _vm->_screen->drawLine(x - 1, y - 1, x + 1, y + 1, color); _vm->_screen->drawLine(x + 1, y - 1, x - 1, y + 1, color); } void Router::loadWalkGrid() { WalkGridHeader floorHeader; byte *fPolygrid; uint16 fPolygridLen; _nBars = 0; // reset counts _nNodes = 1; // leave node 0 for start-node // STATIC GRIDS (added/removed by object logics) // go through walkgrid list for (int i = 0; i < MAX_WALKGRIDS; i++) { if (_walkGridList[i]) { int j; // open walk grid file fPolygrid = _vm->_resman->openResource(_walkGridList[i]); fPolygridLen = _vm->_resman->fetchLen(_walkGridList[i]); Common::MemoryReadStream readS(fPolygrid, fPolygridLen); readS.seek(ResHeader::size()); floorHeader.numBars = readS.readSint32LE(); floorHeader.numNodes = readS.readSint32LE(); // check that we're not going to exceed the max // allowed in the complete walkgrid arrays assert(_nBars + floorHeader.numBars < O_GRID_SIZE); assert(_nNodes + floorHeader.numNodes < O_GRID_SIZE); // lines for (j = 0; j < floorHeader.numBars; j++) { _bars[_nBars + j].x1 = readS.readSint16LE(); _bars[_nBars + j].y1 = readS.readSint16LE(); _bars[_nBars + j].x2 = readS.readSint16LE(); _bars[_nBars + j].y2 = readS.readSint16LE(); _bars[_nBars + j].xmin = readS.readSint16LE(); _bars[_nBars + j].ymin = readS.readSint16LE(); _bars[_nBars + j].xmax = readS.readSint16LE(); _bars[_nBars + j].ymax = readS.readSint16LE(); _bars[_nBars + j].dx = readS.readSint16LE(); _bars[_nBars + j].dy = readS.readSint16LE(); _bars[_nBars + j].co = readS.readSint32LE(); } // nodes // leave node 0 for start node for (j = 0; j < floorHeader.numNodes; j++) { _node[_nNodes + j].x = readS.readSint16LE(); _node[_nNodes + j].y = readS.readSint16LE(); } // close walk grid file _vm->_resman->closeResource(_walkGridList[i]); // increment counts of total bars & nodes in whole // walkgrid _nBars += floorHeader.numBars; _nNodes += floorHeader.numNodes; } } } void Router::clearWalkGridList() { memset(_walkGridList, 0, sizeof(_walkGridList)); } // called from fnAddWalkGrid void Router::addWalkGrid(int32 gridResource) { int i; // First, scan the list to see if this grid is already included for (i = 0; i < MAX_WALKGRIDS; i++) { if (_walkGridList[i] == gridResource) return; } // Scan the list for a free slot for (i = 0; i < MAX_WALKGRIDS; i++) { if (_walkGridList[i] == 0) { _walkGridList[i] = gridResource; return; } } error("_walkGridList[] full"); } // called from fnRemoveWalkGrid void Router::removeWalkGrid(int32 gridResource) { for (int i = 0; i < MAX_WALKGRIDS; i++) { if (_walkGridList[i] == gridResource) { // If we've found it in the list, reset entry to zero. // Otherwise just ignore the request. _walkGridList[i] = 0; break; } } } } // End of namespace Sword2