pacman/lib/Ghost.cpp
Patricia Aas 522362152d Refactor
2021-07-13 14:26:57 +02:00

214 lines
5.9 KiB
C++

#include "Ghost.hpp"
#include <array>
#include <cmath>
namespace pacman {
Ghost::Ghost(Atlas::Ghost spritesSet, Position startingPosition, Position scatterTarget)
: spritesSet(spritesSet),
pos(startingPosition),
startingPosition(startingPosition),
scatterTarget(scatterTarget) {
}
void Ghost::frighten() {
if (state > State::Scatter)
return;
direction = oppositeDirection(direction);
state = State::Frightened;
timeFrighten = 0;
}
bool Ghost::isFrightened() const {
return state == State::Frightened;
}
bool Ghost::isEyes() const {
return state == State::Eyes;
}
void Ghost::die() {
if (state == State::Eyes)
return;
direction = oppositeDirection(direction);
state = State::Eyes;
timeFrighten = 0;
timeChase = 0;
}
void Ghost::reset() {
pos = startingPosition;
}
[[nodiscard]] GridPosition Ghost::currentSprite() const {
switch (state) {
default:
return Atlas::ghostSprite(spritesSet, direction, (animationIndex % 2) == 0);
case State::Eyes:
return Atlas::eyeSprite(direction);
case State::Frightened:
if (timeFrighten < 3500)
return Atlas::initialFrightened(animationIndex);
else
return Atlas::endingFrightened(animationIndex);
}
}
Position Ghost::position() const {
return pos;
}
GridPosition Ghost::positionInGrid() const {
return positionToGridPosition(pos);
}
void Ghost::update(std::chrono::milliseconds time_delta) {
if (state == State::Eyes && isInPen())
state = State::Scatter;
if (state == State::Frightened) {
timeFrighten += time_delta.count();
if (timeFrighten > 6000)
state = State::Scatter;
}
updateAnimation(time_delta);
updatePosition(time_delta);
}
bool Ghost::isInPen() const {
return pacman::isInPen(positionInGrid());
}
void Ghost::updatePosition(std::chrono::milliseconds time_delta) {
updateDirection();
double position_delta = (0.004 * time_delta.count()) * speed();
switch (direction) {
case Direction::NONE:
break;
case Direction::LEFT:
pos.x -= position_delta;
pos.y = round(pos.y);
break;
case Direction::RIGHT:
pos.x += position_delta;
pos.y = round(pos.y);
break;
case Direction::UP:
pos.x = round(pos.x);
pos.y -= position_delta;
break;
case Direction::DOWN:
pos.x = round(pos.x);
pos.y += position_delta;
break;
}
}
double Ghost::speed() const {
if (state == State::Eyes)
return 2;
if (state == State::Frightened)
return 0.5;
return 0.75;
}
/*
* Each time a ghost finds itself at an intersection,
* it picks a target position - the specific target depends on the state
* of the ghost and the specific ghost.
*
* For each 4 cells around the current ghost position the straight-line distance
* to the target is calculated (this ignores all obstacles, including walls)
*
* The ghost then selects among these 4 cells the one with the shortest euclidean distance to the target.
* If a cell is a wall or would cause a ghost to move in the opposite direction, the distance to the target
* from that cell is considered infinite (due to the shape of the maze, there is always one direction
* a ghost can take).
*
* In the scatter state, each ghost tries to reach an unreachable position outside of the map.
* This makes ghosts run in circle around the island at each of the 4 map corner.
*/
void Ghost::updateDirection() {
const auto current_grid_position = positionInGrid();
if (current_grid_position == last_grid_position)
return;
struct Move {
Direction direction;
Position position;
double distance = std::numeric_limits<double>::infinity();
};
const Position current_position = { double(current_grid_position.x), double(current_grid_position.y) };
const auto [x, y] = current_position;
std::array<Move, 4> possible_moves = { { Move{ Direction::UP, { x, y - 1 } },
Move{ Direction::LEFT, { x - 1, y } },
Move{ Direction::DOWN, { x, y + 1 } },
Move{ Direction::RIGHT, { x + 1, y } } } };
const Position target_position = target();
for (auto & move : possible_moves) {
const bool invalid_position = (move.position.x < 0 || move.position.y < 0);
if (invalid_position)
continue;
const bool opposite_direction = (move.direction == oppositeDirection(direction));
if (opposite_direction)
continue;
const GridPosition grid_position = { size_t(move.position.x), size_t(move.position.y) };
const bool can_walk = pacman::isWalkableForGhost(grid_position, current_grid_position, isEyes());
if (!can_walk)
continue;
move.distance = std::hypot(move.position.x - target_position.x, move.position.y - target_position.y);
}
const auto optimal_move = std::min_element(possible_moves.begin(), possible_moves.end(), [](const auto & a, const auto & b) {
return a.distance < b.distance;
});
auto move = *optimal_move;
direction = move.direction;
last_grid_position = current_grid_position;
}
Position Ghost::target() const {
if (state == State::Eyes)
return startingPosition;
if (pacman::isInPen(positionInGrid()))
return pacman::penDoorPosition();
return scatterTarget;
}
void Ghost::updateAnimation(std::chrono::milliseconds time_delta) {
timeForAnimation += time_delta.count();
if (timeForAnimation >= 250) {
timeForAnimation = 0;
animationIndex = (animationIndex + 1) % 4;
}
}
Blinky::Blinky()
: Ghost(Atlas::Ghost::blinky, pacman::initialBlinkyPosition(), pacman::blinkyScatterTarget()) {
}
Speedy::Speedy()
: Ghost(Atlas::Ghost::speedy, pacman::initialSpeedyPosition(), pacman::speedyScatterTarget()) {
}
Inky::Inky()
: Ghost(Atlas::Ghost::inky, pacman::initialInkyPosition(), pacman::inkyScatterTarget()) {
}
Clyde::Clyde()
: Ghost(Atlas::Ghost::clyde, pacman::initialClydePosition(), pacman::clydeScatterTarget()) {
}
} // namespace pacman