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#include "mode_grid.h"
#include "modes.h"
#include "movement.h"
#include "orangutan_shim.h"
int g_w2_order_number;
int g_w2_maze_status = 0;
w2_s_grid_coordinate g_w2_order[16] = {
{0, 0},
{3, 4},
{2, 1},
{4, 2},
};
unsigned int g_w2_order_index = 4;
w2_s_grid_coordinate g_w2_location;
w2_s_grid_coordinate g_w2_destination;
w2_e_orientation g_w2_direction;
int g_w2_detection = 0;
int g_w2_transition;
char g_w2_x_location = 0;
char g_w2_y_location = 0;
void w2_crosswalk_stroll() {
print("hoi");
while (g_w2_sensors[0] < 100 && g_w2_sensors[1] < 100 && g_w2_sensors[2] < 100 &&
g_w2_sensors[3] < 100 && g_w2_sensors[4] < 100) {
set_motors(15, 15);
delay(290);
g_w2_position = read_line(g_w2_sensors, IR_EMITTERS_ON);
if (g_w2_sensors[2] > 100 || g_w2_sensors[3] > 100 || g_w2_sensors[1] > 100) {
set_motors(0, 0);
g_w2_transition++;
if (g_w2_transition == 3) {
set_motors(40, 40);
delay(600);
g_w2_transition = 0;
w2_modes_swap(W2_M_GRID);
return;
}
}
else {
g_w2_transition = 0;
w2_maze_rotation_full();
}
}
}
void w2_grid_crossway_detection() {
set_motors(50, 50);
delay_ms(150);
set_motors(10, 10);
g_w2_position = read_line(g_w2_sensors, IR_EMITTERS_ON);
}
void w2_grid_follow_line() {
unsigned int last_proportional = 0;
long integral = 0;
while (1) {
g_w2_position = read_line(g_w2_sensors, IR_EMITTERS_ON);
int proportional = ((int)g_w2_position) - 2000;
int derivative = proportional - last_proportional;
integral += proportional;
last_proportional = proportional;
int power_difference = proportional / 20 + integral / 10000 + derivative * 3 / 2;
const int max = 60;
if (power_difference > max) power_difference = max;
if (power_difference < -max) power_difference = -max;
if (g_w2_sensors[0] >= 500 && g_w2_sensors[1] >= 250 && g_w2_sensors[2] >= 500 &&
g_w2_sensors[3] >= 250 && g_w2_sensors[4] >= 500) {
break;
} else if (g_w2_sensors[0] >= 500 && g_w2_sensors[1] >= 200 && g_w2_sensors[4] < 100) {
break;
} else if (g_w2_sensors[4] >= 500 && g_w2_sensors[3] >= 200 &&
g_w2_sensors[0] < 100) { // for the south and west borders of the grid
break;
} else if (g_w2_sensors[4] >= 500 && g_w2_sensors[3] >= 200 && g_w2_sensors[2] < 100 &&
g_w2_sensors[0] < 100) { // sharp right corners
break;
}
else {
if (power_difference < 0 &&
(g_w2_sensors[2] > 100 || g_w2_sensors[3] > 100 || g_w2_sensors[1] > 100)) {
set_motors(max + power_difference, max);
} else if (power_difference > 0 &&
(g_w2_sensors[2] > 100 || g_w2_sensors[3] > 100 || g_w2_sensors[1] > 100)) {
set_motors(max, max - power_difference);
}
}
}
}
void w2_begin_location() {
g_w2_location.x = 4;
g_w2_location.y = 0;
g_w2_direction = W2_ORT_WEST;
}
void w2_end_destination() {
g_w2_destination.x = 4;
g_w2_destination.y = 4;
}
void w2_turn_north() {
switch (g_w2_direction) {
case W2_ORT_NORTH:
break;
case W2_ORT_EAST:
w2_grid_rotation_half_left();
break;
case W2_ORT_SOUTH:
w2_grid_rotation_full();
break;
case W2_ORT_WEST:
w2_grid_rotation_half_right();
break;
}
g_w2_direction = W2_ORT_NORTH;
}
void w2_turn_west() {
switch (g_w2_direction) {
case W2_ORT_WEST:
break;
case W2_ORT_NORTH:
w2_grid_rotation_half_left();
break;
case W2_ORT_EAST:
w2_grid_rotation_full();
break;
case W2_ORT_SOUTH:
w2_grid_rotation_half_right();
;
break;
}
g_w2_direction = W2_ORT_WEST;
}
void w2_turn_south() {
switch (g_w2_direction) {
case W2_ORT_SOUTH:
break;
case W2_ORT_WEST:
w2_grid_rotation_half_left();
break;
case W2_ORT_NORTH:
w2_grid_rotation_full();
break;
case W2_ORT_EAST:
w2_grid_rotation_half_right();
;
break;
}
g_w2_direction = W2_ORT_SOUTH;
}
void w2_turn_east() {
switch (g_w2_direction) {
case W2_ORT_EAST:
break;
case W2_ORT_SOUTH:
w2_grid_rotation_half_left();
break;
case W2_ORT_WEST:
w2_grid_rotation_full();
break;
case W2_ORT_NORTH:
w2_grid_rotation_half_right();
;
break;
}
g_w2_direction = W2_ORT_EAST;
}
void w2_arrived_message() {
if (g_w2_location.x == g_w2_destination.x && g_w2_location.y == g_w2_destination.y) {
print_long(g_w2_order_number);
play_frequency(400, 500, 7);
delay(500);
}
}
void w2_go_to_x() {
if (g_w2_location.x != g_w2_destination.x) {
while (g_w2_location.x != g_w2_destination.x) {
if (g_w2_location.x > g_w2_destination.x) {
w2_turn_west();
w2_grid_follow_line();
w2_grid_crossway_detection();
g_w2_location.x--;
}
else if (g_w2_location.x < g_w2_destination.x) {
w2_turn_east();
w2_grid_follow_line();
w2_grid_crossway_detection();
g_w2_location.x++;
}
}
}
}
void w2_go_to_y() {
if (g_w2_location.y != g_w2_destination.y) {
while (g_w2_location.y != g_w2_destination.y) {
if (g_w2_location.y > g_w2_destination.y) {
w2_turn_south();
w2_grid_follow_line();
w2_grid_crossway_detection();
g_w2_location.y--;
}
else if (g_w2_location.y < g_w2_destination.y) {
w2_turn_north();
w2_grid_follow_line();
w2_grid_crossway_detection();
g_w2_location.y++;
}
}
}
}
void w2_mode_grid() {
set_motors(0, 0);
delay(500);
w2_begin_location();
// TODO: orders read here
for (int i = 0; i < g_w2_order_index; i++) {
g_w2_order_number = i + 1;
g_w2_destination.x = g_w2_order[i].x;
g_w2_destination.y = g_w2_order[i].y;
delay(1000);
w2_go_to_x();
w2_go_to_y();
}
w2_end_destination();
delay(1000);
w2_go_to_y();
w2_go_to_x();
w2_turn_east(); // this was uncommented (6.3)
w2_modes_swap(W2_M_CHRG);
}
/*
void w2_mode_maze() {
unsigned int last_proportional = 0;
long integral = 0;
clear();
print("MAZE");
g_w2_transition = 0;
// This is the "main loop" - it will run forever.
while (1) {
// Get the position of the line. Note that we *must* provide
// the "sensors" argument to read_line() here, even though we
// are not interested in the individual sensor readings.
g_w2_position = read_line(g_w2_sensors, IR_EMITTERS_ON);
// The "proportional" term should be 0 when we are on the line.
int proportional = ((int)g_w2_position) - 2000;
// Compute the derivative (change) and integral (sum) of the
// position.
int derivative = proportional - last_proportional;
integral += proportional;
// Remember the last position.
last_proportional = proportional;
// Compute the difference between the two motor power settings,
// m1 - m2. If this is a positive number the robot will turn
// to the right. If it is a negative number, the robot will
// turn to the left, and the magnitude of the number determines
// the sharpness of the turn.
int power_difference = proportional / 20 + integral / 10000 + derivative * 3 / 2;
// Compute the actual motor settings. We never set either motor
// to a negative value.
const int max = 60;
if (power_difference > max) power_difference = max;
if (power_difference < -max) power_difference = -max;
if (g_w2_sensors[0] < 100 && g_w2_sensors[1] < 100 && g_w2_sensors[2] < 100 &&
g_w2_sensors[3] < 100 && g_w2_sensors[4] < 100) { } else if (g_w2_sensors[0] >= 500 &&
g_w2_sensors[1] >= 250 && g_w2_sensors[2] >= 500 && g_w2_sensors[3] >= 250 && g_w2_sensors[4] >=
500) { w2_crossway_detection(); } else if (g_w2_sensors[0] >= 500 && g_w2_sensors[1] >= 200 &&
g_w2_sensors[4] < 100) { w2_half_rotation_left(); } else { if (power_difference < 0 &&
(g_w2_sensors[2] > 100 || g_w2_sensors[3] > 100 || g_w2_sensors[1] > 100)) set_motors(max +
power_difference, max); else if (power_difference > 0 && (g_w2_sensors[2] > 100 || g_w2_sensors[3] >
100 || g_w2_sensors[1] > 100)) set_motors(max, max - power_difference);
}
}
}
*/
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