inT32 C_OUTLINE::area() const {
int stepindex; //current step
inT32 total_steps; //steps to do
inT32 total; //total area
ICOORD pos; //position of point
ICOORD next_step; //step to next pix
// We aren't going to modify the list, or its contents, but there is
// no const iterator.
C_OUTLINE_IT it(const_cast<C_OUTLINE_LIST*>(&children));
pos = start_pos ();
total_steps = pathlength ();
total = 0;
for (stepindex = 0; stepindex < total_steps; stepindex++) {
//all intersected
next_step = step (stepindex);
if (next_step.x () < 0)
total += pos.y ();
else if (next_step.x () > 0)
total -= pos.y ();
pos += next_step;
}
for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ())
total += it.data ()->area ();//add areas of children
return total;
}
inT32 C_OUTLINE::area() { //winding number
int stepindex; //current step
inT32 total_steps; //steps to do
inT32 total; //total area
ICOORD pos; //position of point
ICOORD next_step; //step to next pix
C_OUTLINE_IT it = child ();
pos = start_pos ();
total_steps = pathlength ();
total = 0;
for (stepindex = 0; stepindex < total_steps; stepindex++) {
//all intersected
next_step = step (stepindex);
if (next_step.x () < 0)
total += pos.y ();
else if (next_step.x () > 0)
total -= pos.y ();
pos += next_step;
}
for (it.mark_cycle_pt (); !it.cycled_list (); it.forward ())
total += it.data ()->area ();//add areas of children
return total;
}
inT32 C_OUTLINE::perimeter() {
inT32 total_steps; // Return value.
C_OUTLINE_IT it = child();
total_steps = pathlength();
for (it.mark_cycle_pt(); !it.cycled_list(); it.forward())
total_steps += it.data()->pathlength(); // Add perimeters of children.
return total_steps;
}
inT32 C_OUTLINE::perimeter() const {
inT32 total_steps; // Return value.
// We aren't going to modify the list, or its contents, but there is
// no const iterator.
C_OUTLINE_IT it(const_cast<C_OUTLINE_LIST*>(&children));
total_steps = pathlength();
for (it.mark_cycle_pt(); !it.cycled_list(); it.forward())
total_steps += it.data()->pathlength(); // Add perimeters of children.
return total_steps;
}
// find the shortest path length
int pathlength(const int origin,const int destination, int list[])
{
int shortestlength = 0;
int l[NUM_V];
int c=0;
int le;
int i;
list[origin-1]=1; /*marking current vertices as listed*/
list[destination-1]=1;
if(graph[origin-1][destination-1]==1 && graph[destination-1][origin-1]==1) /*if destination directly connecting to current vertex*/
return 1;
for(i=0;i<NUM_V;i++)
{
if(list[i]==0) /*checking if untraversed*/
{
c++;
break;
}
}
if(c==0)
return 0;
for(i=0;i<NUM_V;i++)
{
if(graph[origin-1][i]==1 && list[i]==0) /*checking for directly connected unvisited vertices*/
{
le=pathlength(i+1,destination,list); /*recursion*/
if(shortestlength==0)
shortestlength=le;
else if(le<shortestlength)
shortestlength=le;
}
}
if(shortestlength==0)
return shortestlength;
shortestlength++;
return shortestlength;
}
// main function: display the right messages. Please refer to MP5 requirement
int main(int argc, const char **argv)
{
int gc;
int list[NUM_V];
int origin;
int destination;
int sl;
int i;
if(argv[1]==NULL)
{
printf("enter the input file name\n");
return -1;
}
gc = graph_reading(argv[1]);
if(gc==1)
{
printf("input file cannot be opened\n");
return -1;
}
else
printf("The adjacency matrix has been loaded\n");
graph_print();
printf("Enter the origin vertex:\n");
scanf("%d",&origin);
printf("Enter the destination vertex:\n");
scanf("%d",&destination);
for(i=0;i<NUM_V;i++) /*list[NUM_V] has recored of traversed vertices*/
list[NUM_V]=0;
sl = pathlength(origin,destination,list); /*shortest path length*/
if(sl==0)
printf("%d and %d are seperated forever!",origin,destination);
else
printf("%d needs %d step(s) to get %d",origin,sl,destination);
return 0;
}
inT32 C_OUTLINE::outer_area() const {
int stepindex; //current step
inT32 total_steps; //steps to do
inT32 total; //total area
ICOORD pos; //position of point
ICOORD next_step; //step to next pix
pos = start_pos ();
total_steps = pathlength ();
if (total_steps == 0)
return box.area();
total = 0;
for (stepindex = 0; stepindex < total_steps; stepindex++) {
//all intersected
next_step = step (stepindex);
if (next_step.x () < 0)
total += pos.y ();
else if (next_step.x () > 0)
total -= pos.y ();
pos += next_step;
}
return total;
}
inT32 C_OUTLINE::count_transitions( //winding number
inT32 threshold //on size
) {
BOOL8 first_was_max_x; //what was first
BOOL8 first_was_max_y;
BOOL8 looking_for_max_x; //what is next
BOOL8 looking_for_min_x;
BOOL8 looking_for_max_y; //what is next
BOOL8 looking_for_min_y;
int stepindex; //current step
inT32 total_steps; //steps to do
//current limits
inT32 max_x, min_x, max_y, min_y;
inT32 initial_x, initial_y; //initial limits
inT32 total; //total changes
ICOORD pos; //position of point
ICOORD next_step; //step to next pix
pos = start_pos ();
total_steps = pathlength ();
total = 0;
max_x = min_x = pos.x ();
max_y = min_y = pos.y ();
looking_for_max_x = TRUE;
looking_for_min_x = TRUE;
looking_for_max_y = TRUE;
looking_for_min_y = TRUE;
first_was_max_x = FALSE;
first_was_max_y = FALSE;
initial_x = pos.x ();
initial_y = pos.y (); //stop uninit warning
for (stepindex = 0; stepindex < total_steps; stepindex++) {
//all intersected
next_step = step (stepindex);
pos += next_step;
if (next_step.x () < 0) {
if (looking_for_max_x && pos.x () < min_x)
min_x = pos.x ();
if (looking_for_min_x && max_x - pos.x () > threshold) {
if (looking_for_max_x) {
initial_x = max_x;
first_was_max_x = FALSE;
}
total++;
looking_for_max_x = TRUE;
looking_for_min_x = FALSE;
min_x = pos.x (); //reset min
}
}
else if (next_step.x () > 0) {
if (looking_for_min_x && pos.x () > max_x)
max_x = pos.x ();
if (looking_for_max_x && pos.x () - min_x > threshold) {
if (looking_for_min_x) {
initial_x = min_x; //remember first min
first_was_max_x = TRUE;
}
total++;
looking_for_max_x = FALSE;
looking_for_min_x = TRUE;
max_x = pos.x ();
}
}
else if (next_step.y () < 0) {
if (looking_for_max_y && pos.y () < min_y)
min_y = pos.y ();
if (looking_for_min_y && max_y - pos.y () > threshold) {
if (looking_for_max_y) {
initial_y = max_y; //remember first max
first_was_max_y = FALSE;
}
total++;
looking_for_max_y = TRUE;
looking_for_min_y = FALSE;
min_y = pos.y (); //reset min
}
}
else {
if (looking_for_min_y && pos.y () > max_y)
max_y = pos.y ();
if (looking_for_max_y && pos.y () - min_y > threshold) {
if (looking_for_min_y) {
initial_y = min_y; //remember first min
first_was_max_y = TRUE;
}
total++;
looking_for_max_y = FALSE;
looking_for_min_y = TRUE;
max_y = pos.y ();
}
}
}
if (first_was_max_x && looking_for_min_x) {
if (max_x - initial_x > threshold)
total++;
else
total--;
}
else if (!first_was_max_x && looking_for_max_x) {
if (initial_x - min_x > threshold)
total++;
else
total--;
}
if (first_was_max_y && looking_for_min_y) {
if (max_y - initial_y > threshold)
total++;
else
total--;
}
else if (!first_was_max_y && looking_for_max_y) {
if (initial_y - min_y > threshold)
total++;
else
total--;
}
return total;
}
