void free_cell(vtab_p table, int row, int col) {
cell_p c_ptr = GET_CELL_PTR(row, col);
if ((c_ptr->type == CELL_TYPE_STRING)
&& (c_ptr->flags & CELL_FLAG_FREEABLE)
&& (c_ptr->s != NULL)) {
free(c_ptr->s);
}
memset(c_ptr, 0, sizeof(cell_t));
}
void zero_table_data(vtab_p table, int type) {
// Sets data area of table to zeros of specified type
for (int row = table->header_rows; (row < ALL_TABLE_ROWS); row++) {
for (int col = table->header_cols; (col < ALL_TABLE_COLS); col++) {
cell_p c_ptr = GET_CELL_PTR(row, col);
memset(c_ptr, 0, sizeof(cell_t));
c_ptr->type = type;
}
}
}
void sort_rows_descending_by_col(vtab_p table, int start_row, int stop_row, int col) {
// Rearrange row_ix_map[] indices so the rows will be in
// descending order by the value in the specified column
for (int ix = start_row; (ix <= stop_row); ix++) {
int biggest_ix = ix;
cell_p biggest_ix_c_ptr = GET_CELL_PTR(table->row_ix_map[ix], col);
for (int iy = ix + 1; (iy <= stop_row); iy++) {
cell_p iy_c_ptr = GET_CELL_PTR(table->row_ix_map[iy], col);
if (biggest_ix_c_ptr->d < iy_c_ptr->d) {
biggest_ix_c_ptr = iy_c_ptr;
biggest_ix = iy;
}
}
if (biggest_ix != ix) {
int tmp = table->row_ix_map[ix];
table->row_ix_map[ix] = table->row_ix_map[biggest_ix];
table->row_ix_map[biggest_ix] = tmp;
}
}
}
/**
* Fills the world with specified number of people and zombies.
* The people are of different age; zombies are "brand new".
*/
void randomDistribution(WorldPtr world, int people, int zombies, simClock clock) {
world->stats.clock = clock;
world->stats.infectedFemales = 0;
world->stats.infectedMales = 0;
for (int i = 0; i < people;) {
int x = randomInt(world->xStart, world->xEnd);
int y = randomInt(world->yStart, world->yEnd);
CellPtr cellPtr = GET_CELL_PTR(world, x, y);
if (cellPtr->type != NONE) {
continue;
}
newHuman(cellPtr, clock);
if (cellPtr->gender == FEMALE) {
world->stats.humanFemales++;
} else {
world->stats.humanMales++;
}
i++;
}
for (int i = 0; i < zombies;) {
int x = randomInt(world->xStart, world->xEnd);
int y = randomInt(world->yStart, world->yEnd);
CellPtr cellPtr = GET_CELL_PTR(world, x, y);
if (cellPtr->type != NONE) {
continue;
}
newZombie(cellPtr, clock);
world->stats.zombies++;
i++;
}
}
void auto_set_col_width(vtab_p table, int col, int min_width, int max_width) {
int width = min_width;
for (int row = 0; (row < ALL_TABLE_ROWS); row++) {
cell_p c_ptr = GET_CELL_PTR(row, col);
if (c_ptr->type == CELL_TYPE_REPCHAR) {
continue;
}
char *p = fmt_cell_data(c_ptr, max_width, (int)(table->col_decimal_places[col]));
int l = strlen(p);
if (width < l) {
width = l;
}
}
width += USUAL_GUTTER_WIDTH;
if (width > max_width) {
width = max_width;
}
table->col_width[col] = (uint8_t)width;
}
void display_table(vtab_p table,
int screen_width,
int show_unseen_rows,
int show_unseen_cols,
int show_zero_rows,
int show_zero_cols)
{
// Set row and column flags according to whether data in rows and cols
// has been assigned, and is currently non-zero.
int some_seen_data = 0;
int some_non_zero_data = 0;
for (int row = table->header_rows; (row < ALL_TABLE_ROWS); row++) {
for (int col = table->header_cols; (col < ALL_TABLE_COLS); col++) {
cell_p c_ptr = GET_CELL_PTR(row, col);
// Currently, "seen data" includes not only numeric data, but also
// any strings, etc -- anything non-NULL (other than rephcars).
if ((c_ptr->type != CELL_TYPE_NULL) && (c_ptr->type != CELL_TYPE_REPCHAR)) {
some_seen_data = 1;
set_row_flag(table, row, ROW_FLAG_SEEN_DATA);
set_col_flag(table, col, COL_FLAG_SEEN_DATA);
// Currently, "non-zero data" includes not only numeric data,
// but also any strings, etc -- anything non-zero (other than
// repchars, which are already excluded above). So, note a
// valid non-NULL pointer to an empty string would still be
// counted as non-zero data.
if (c_ptr->l != (int64_t)0) {
some_non_zero_data = 1;
set_row_flag(table, row, ROW_FLAG_NON_ZERO_DATA);
set_col_flag(table, col, COL_FLAG_NON_ZERO_DATA);
}
}
}
}
if (!some_seen_data) {
printf("Table has no data.\n");
return;
}
if (!some_non_zero_data && !show_zero_rows && !show_zero_cols) {
printf("Table has no non-zero data.\n");
return;
}
// Start with first data column and try to display table,
// folding lines as necessary per screen_width
int col = -1;
int data_col = table->header_cols;
while (data_col < ALL_TABLE_COLS) {
// Skip data columns until we have one to display
if ((!test_col_flag(table, data_col, COL_FLAG_ALWAYS_SHOW)) &&
(((!show_unseen_cols) && (!test_col_flag(table, data_col, COL_FLAG_SEEN_DATA))) ||
((!show_zero_cols) && (!test_col_flag(table, data_col, COL_FLAG_NON_ZERO_DATA))))) {
data_col += 1;
continue;
}
// Display blank line between table sections
if (col > 0) {
printf("\n");
}
// For each row, display as many columns as possible
for (int row_ix = 0; (row_ix < ALL_TABLE_ROWS); row_ix++) {
int row = table->row_ix_map[row_ix];
// If past the header rows, conditionally skip rows
if ((row >= table->header_rows) && (!test_row_flag(table, row, ROW_FLAG_ALWAYS_SHOW))) {
// Optionally skip row if no data seen or if all zeros
if (((!show_unseen_rows) && (!test_row_flag(table, row, ROW_FLAG_SEEN_DATA))) ||
((!show_zero_rows) && (!test_row_flag(table, row, ROW_FLAG_NON_ZERO_DATA)))) {
continue;
}
}
// Begin a new row...
int cur_line_width = 0;
// All lines start with the left header columns
for (col = 0; (col < table->header_cols); col++) {
display_justified_cell(GET_CELL_PTR(row, col),
(int)(table->row_flags[row]),
(int)(table->col_flags[col]),
(int)(table->col_width[col]),
(int)(table->col_decimal_places[col]));
cur_line_width += (int)(table->col_width[col]);
}
// Reset column index to starting data column for each new row
col = data_col;
// Try to display as many data columns as possible in every section
for (;;) {
// See if we should print this column
if (test_col_flag(table, col, COL_FLAG_ALWAYS_SHOW) ||
(((show_unseen_cols) || (test_col_flag(table, col, COL_FLAG_SEEN_DATA))) &&
((show_zero_cols) || (test_col_flag(table, col, COL_FLAG_NON_ZERO_DATA))))) {
display_justified_cell(GET_CELL_PTR(row, col),
(int)(table->row_flags[row]),
(int)(table->col_flags[col]),
(int)(table->col_width[col]),
(int)(table->col_decimal_places[col]));
cur_line_width += (int)(table->col_width[col]);
}
col += 1;
// End the line if no more columns or next column would exceed screen width
if ((col >= ALL_TABLE_COLS) ||
((cur_line_width + (int)(table->col_width[col])) > screen_width)) {
break;
}
}
printf("\n");
}
// Remember next starting data column for next section
data_col = col;
}
}
void clear_assign(vtab_p table, int row, int col) {
cell_p c_ptr = GET_CELL_PTR(row, col);
memset(c_ptr, 0, sizeof(cell_t));
}
void long_addto(vtab_p table, int row, int col, int64_t l) {
cell_p c_ptr = GET_CELL_PTR(row, col);
c_ptr->type = CELL_TYPE_LONG;
c_ptr->l += l;
}
void double_addto(vtab_p table, int row, int col, double d) {
cell_p c_ptr = GET_CELL_PTR(row, col);
c_ptr->type = CELL_TYPE_DOUBLE;
c_ptr->d += d;
}
void repchar_assign(vtab_p table, int row, int col, char c) {
cell_p c_ptr = GET_CELL_PTR(row, col);
c_ptr->type = CELL_TYPE_REPCHAR;
c_ptr->c[0] = c;
}
void string_assign(vtab_p table, int row, int col, char *s) {
cell_p c_ptr = GET_CELL_PTR(row, col);
c_ptr->type = CELL_TYPE_STRING;
c_ptr->s = s;
}
int test_cell_flag(vtab_p table, int row, int col, int flag) {
cell_p c_ptr = GET_CELL_PTR(row, col);
return ((c_ptr->flags & (uint32_t)flag) != 0);
}
void clear_cell_flag(vtab_p table, int row, int col, int flag) {
cell_p c_ptr = GET_CELL_PTR(row, col);
c_ptr->flags &= (uint32_t)~flag;
}
void set_cell_flag(vtab_p table, int row, int col, int flag) {
cell_p c_ptr = GET_CELL_PTR(row, col);
c_ptr->flags |= (uint32_t)flag;
}
/**
* Order of actions:
* a) death of human or infected
* b) decomposition of zombie
* c) transition of infected to zombie
*/
static void simulateStep1(WorldPtr input, WorldPtr output) {
simClock clock = output->clock;
// we want to force static scheduling because we suppose that the load
// is distributed evenly over the map and we need to have predictable locking
#ifdef _OPENMP
// at least three columns per thread
int threads = omp_get_max_threads();
int numThreads = MIN(MAX(input->localWidth / 3, 1), threads);
#pragma omp parallel for num_threads(numThreads) schedule(static)
#endif
for (int x = input->xStart; x < input->xEnd; x++) {
Stats stats = NO_STATS;
for (int y = input->yStart; y <= input->yEnd; y++) {
EntityPtr entity = GET_CELL_PTR(input, x, y);
if (entity->type == NONE) {
continue;
}
// Death of living entity
if (entity->type == HUMAN || entity->type == INFECTED) {
if (randomDouble() < getDeathRate(entity, clock)) {
if (entity->type == HUMAN) {
if (entity->gender == FEMALE) {
stats.humanFemalesDied++;
} else {
stats.humanMalesDied++;
}
} else {
if (entity->gender == FEMALE) {
stats.infectedFemalesDied++;
} else {
stats.infectedMalesDied++;
}
}
LOG_EVENT("A %s died\n",
entity->type == HUMAN ? "Human" : "Infected");
// just forget this entity
entity->type = NONE;
}
}
// Decompose Zombie
if (entity->type == ZOMBIE) {
if (randomDouble() < getDecompositionRate(entity, clock)) {
stats.zombiesDecomposed++;
LOG_EVENT("A Zombie decomposed\n");
// just forgot this entity
entity->type = NONE;
}
}
// Convert Infected to Zombie
if (entity->type == INFECTED) {
if (randomDouble() < PROBABILITY_BECOME_ZOMBIE) {
if (entity->gender == FEMALE) {
stats.infectedFemalesBecameZombies++;
} else {
stats.infectedMalesBecameZombies++;
}
toZombie(entity, clock);
LOG_EVENT("An Infected became Zombie\n");
}
}
}
#ifdef _OPENMP
#pragma omp critical (StatsCriticalRegion2)
#endif
{
mergeStats(&output->stats, stats, true);
}
}
}
/**
* Order of actions:
* a) transition of human into infected
* b) giving birth to children - changes input
* c) making love - changes input
* d) movement
*/
static void simulateStep2(WorldPtr input, WorldPtr output) {
simClock clock = output->clock;
// notice that we iterate over xx and yy
// and the real x and y are randomly switched between two directions
double xxDir = randomDouble();
double yyDir = randomDouble();
// we want to force static scheduling because we suppose that the load
// is distributed evenly over the map and we need to have predictable locking
#ifdef _OPENMP
// at least three columns per thread
int threads = omp_get_max_threads();
int numThreads = MIN(MAX(input->localWidth / 3, 1), threads);
#pragma omp parallel for num_threads(numThreads) schedule(static)
#endif
for (int xx = input->xStart; xx <= input->xEnd; xx++) {
int x = (xxDir < 0.5) ? xx : (input->xEnd + input->xStart - xx);
// stats are counted per column and summed at the end
Stats stats = NO_STATS;
lockColumn(output, x);
for (int yy = input->yStart; yy <= input->yEnd; yy++) {
int y = (yyDir < 0.5) ? yy : (input->yEnd + input->yStart - yy);
Entity entity = GET_CELL(input, x, y);
if (entity.type == NONE) {
continue;
}
// Convert Human to Infected
if (entity.type == HUMAN) {
int zombieCount = countNeighbouringZombies(input, x, y);
double infectionChance = zombieCount * PROBABILITY_INFECTION;
if (randomDouble() <= infectionChance) {
if (entity.gender == FEMALE) {
stats.humanFemalesBecameInfected++;
} else {
stats.humanMalesBecameInfected++;
}
toInfected(&entity, clock);
LOG_EVENT("A Human became infected\n");
}
}
// Here are performed natural processed of humans and infected
if (entity.type == HUMAN || entity.type == INFECTED) {
// giving birth
if (entity.gender == FEMALE && entity.children > 0) {
if (entity.origin + entity.borns <= clock) {
if (entity.type == HUMAN) {
stats.humanFemalesGivingBirth++;
} else {
stats.infectedFemalesGivingBirth++;
}
Entity * freePtr;
while (entity.children > 0 && (freePtr =
getFreeAdjacent(input, output, x, y)) != NULL) {
Entity child = giveBirth(&entity, clock);
if (child.type == HUMAN) {
if (child.gender == FEMALE) {
stats.humanFemalesBorn++;
} else {
stats.humanMalesBorn++;
}
} else {
if (child.gender == FEMALE) {
stats.infectedFemalesBorn++;
} else {
stats.infectedMalesBorn++;
}
}
*freePtr = child;
LOG_EVENT("A %s child was born\n",
child.type == HUMAN ? "Human" : "Infected");
}
} else {
if (entity.type == HUMAN) {
stats.humanFemalesPregnant++;
} else {
stats.infectedFemalesPregnant++;
}
}
}
// making love
if (entity.gender == FEMALE && entity.children == 0
&& clock >= entity.origin + entity.fertilityStart
&& clock < entity.origin + entity.fertilityEnd) { // can have baby
EntityPtr adjacentMale = findAdjacentFertileMale(input, x,
y, clock);
if (adjacentMale != NULL) {
stats.couplesMakingLove++;
makeLove(&entity, adjacentMale, clock, input->stats);
stats.childrenConceived += entity.children;
LOG_EVENT("A couple made love\n");
}
}
}
if (entity.type == HUMAN) {
if (entity.gender == FEMALE) {
stats.humanFemales++;
} else {
stats.humanMales++;
}
} else if (entity.type == INFECTED) {
if (entity.gender == FEMALE) {
stats.infectedFemales++;
} else {
stats.infectedMales++;
}
} else {
stats.zombies++;
}
// MOVEMENT
bearing bearing_ = getBearing(input, x, y); // optimal bearing
bearing_ += getRandomBearing() * BEARING_FLUCTUATION;
Direction dir = bearingToDirection(bearing_);
if (dir != STAY) {
double bearingRandomQuotient = (randomDouble() - 0.5)
* BEARING_ABS_QUOTIENT_VARIANCE
+ BEARING_ABS_QUOTIENT_MEAN;
entity.bearing = bearing_ / cabsf(bearing_)
* bearingRandomQuotient;
} else {
entity.bearing = bearing_;
}
// some randomness in direction
// the entity will never go in the opposite direction
if (dir != STAY) {
if (randomDouble() < getMaxSpeed(&entity, clock)) {
double dirRnd = randomDouble();
if (dirRnd < DIRECTION_MISSED) {
dir = DIRECTION_CCW(dir); // turn counter-clock-wise
} else if (dirRnd < DIRECTION_MISSED * 2) {
dir = DIRECTION_CW(dir); // turn clock-wise
} else if (dirRnd
> DIRECTION_FOLLOW + DIRECTION_MISSED * 2) {
dir = STAY;
}
} else {
dir = STAY;
}
} else {
// if the entity would STAY, we'll try again to make it move
// to make the entity bearing variable in terms of absolute value
double bearingRandomQuotient = (randomDouble() - 0.5)
* BEARING_ABS_QUOTIENT_VARIANCE
+ BEARING_ABS_QUOTIENT_MEAN;
bearing_ += getRandomBearing() * bearingRandomQuotient;
dir = bearingToDirection(bearing_);
}
// we will try to find the cell in the chosen direction
CellPtr destPtr = NULL;
if (dir != STAY) {
destPtr = IF_CAN_MOVE_TO(x, y, dir);
if (randomDouble() < MOVEMENT_TRY_ALTERNATIVE) {
if (destPtr == NULL) {
destPtr = IF_CAN_MOVE_TO(x, y, DIRECTION_CCW(dir));
}
if (destPtr == NULL) {
destPtr = IF_CAN_MOVE_TO(x, y, DIRECTION_CW(dir));
}
}
}
if (destPtr == NULL) {
destPtr = GET_CELL_PTR(output, x, y);
}
// actual assignment of entity to its destination
*destPtr = entity;
}
unlockColumn(output, x);
#ifdef _OPENMP
#pragma omp critical (StatsCriticalRegion2)
#endif
{
mergeStats(&output->stats, stats, true);
}
}
}
