/* Event layout engine for Gnomecal
*
* Copyright (C) 1998 The Free Software Foundation
*
* Authors: Miguel de Icaza <miguel@nuclecu.unam.mx>
* Federico Mena <federico@nuclecu.unam.mx>
*/
#include <config.h>
#include <stdlib.h>
#include "layout.h"
/* This structure is used to pass around layout information among the internal layout functions */
struct layout_info {
GList *events; /* List of events from client */
int num_events; /* The number of events (length of the list) */
LayoutQueryTimeFunc func; /* Function to convert a list item to a start/end time pair */
int num_rows; /* Size of the time partition */
time_t *partition; /* The time partition containing start and end time values */
int *array; /* Working array of free and allocated time slots */
int *allocations; /* Returned array of slot allocations */
int *slots; /* Returned array of slots used */
int num_slots; /* Number of slots used */
};
/* This defines the maximum number of events to overlap per row. More than that number of events
* will not be displayed. This is not ideal, so sue me.
*/
#define MAX_EVENTS_PER_ROW 32
/* Compares two time_t values, used for qsort() */
static int
compare_time_t (const void *a, const void *b)
{
time_t ta, tb;
ta = *((time_t *) a);
tb = *((time_t *) b);
if (ta < tb)
return -1;
else if (ta > tb)
return 1;
else
return 0;
}
/* Builds a partition of the time range occupied by the events in the list. It returns an array
* with the times that define the partition and the number of items in the partition.
*/
static void
build_partition (struct layout_info *li)
{
time_t *rows, *p, *q;
GList *list;
int i, unique_vals;
/* This is the maximum number of rows we would need */
li->num_rows = li->num_events * 2;
/* Fill the rows with the times */
rows = g_new (time_t, li->num_rows);
for (list = li->events, p = rows; list; list = list->next) {
(* li->func) (list, &p[0], &p[1]);
p += 2;
}
/* Do a sort | uniq on the array */
qsort (rows, li->num_rows, sizeof (time_t), compare_time_t);
p = rows;
q = rows + 1;
unique_vals = 1;
for (i = 1; i < li->num_rows; i++, q++)
if (*q != *p) {
unique_vals++;
p++;
*p = *q;
}
/* Return the number of unique values in the partition and the partition array itself */
li->num_rows = unique_vals;
li->partition = rows;
}
/* Returns the index of the element in the partition that corresponds to the specified time */
int
find_index (struct layout_info *li, time_t t)
{
int i;
for (i = 0; ; i++)
if (li->partition[i] == t)
return i;
g_assert_not_reached ();
}
#define xy(li, x, y) li->array[(y * MAX_EVENTS_PER_ROW) + (x)]
/* Checks that all the cells in the slot array at the specified slot column are free to use by an
* event that has the specified range.
*/
static int
range_is_empty (struct layout_info *li, int slot, time_t start, time_t end)
{
int i;
for (i = find_index (li, start); li->partition[i] < end; i++)
if (xy (li, slot, i) != -1)
return FALSE;
return TRUE;
}
/* Allocates a time in the slot array for the specified event's index */
static void
range_allocate (struct layout_info *li, int slot, time_t start, time_t end, int ev_num)
{
int i;
for (i = find_index (li, start); li->partition[i] < end; i++)
xy (li, slot, i) = ev_num;
}
/* Performs the initial allocation of slots for events. Each event gets one column; they will be
* expanded in a later stage. Returns the number of columns used.
*/
static void
initial_allocate (struct layout_info *li)
{
GList *events;
int i;
int slot;
int num_slots;
time_t start, end;
num_slots = 0;
for (i = 0, events = li->events; events; events = events->next, i++) {
(* li->func) (events, &start, &end);
/* Start with no allocation, no columns */
li->allocations[i] = -1;
li->slots[i] = 0;
/* Find a free column for the event */
for (slot = 0; slot < MAX_EVENTS_PER_ROW; slot++)
if (range_is_empty (li, slot, start, end)) {
range_allocate (li, slot, start, end, i);
li->allocations[i] = slot;
li->slots[i] = 1;
if ((slot + 1) > num_slots)
num_slots = slot + 1;
break;
}
}
li->num_slots = num_slots;
}
/* Returns the maximum number of columns that an event can expanded by in the slot array */
static int
columns_to_expand (struct layout_info *li, int ev_num, time_t start, time_t end)
{
int cols;
int slot;
int i_start;
int i;
cols = 0;
i_start = find_index (li, start);
for (slot = li->allocations[ev_num] + 1; slot < li->num_slots; slot++) {
for (i = i_start; li->partition[i] < end; i++)
if (xy (li, slot, i) != -1)
return cols;
cols++;
}
return cols;
}
/* Expands an event by the specified number of columns */
static void
do_expansion (struct layout_info *li, int ev_num, time_t start, time_t end, int num_cols)
{
int i, j;
int slot;
for (i = find_index (li, start); li->partition[i] < end; i++) {
slot = li->allocations[ev_num] + 1;
for (j = 0; j < num_cols; j++)
xy (li, slot + j, i) = ev_num;
}
}
/* Expands the events in the slot array to occupy as many columns as possible. This is the second
* pass of the layout algorithm.
*/
static void
expand_events (struct layout_info *li)
{
GList *events;
time_t start, end;
int i;
int cols;
for (i = 0, events = li->events; events; events = events->next, i++) {
(* li->func) (events, &start, &end);
cols = columns_to_expand (li, i, start, end);
if (cols == 0)
continue; /* We can't expand this event */
do_expansion (li, i, start, end, cols);
li->slots[i] += cols;
}
}
void
layout_events (GList *events, LayoutQueryTimeFunc func, int *num_slots, int **allocations, int **slots)
{
struct layout_info li;
int i;
g_return_if_fail (num_slots != NULL);
g_return_if_fail (allocations != NULL);
g_return_if_fail (slots != NULL);
if (!events) {
*num_slots = 0;
*allocations = NULL;
*slots = NULL;
return;
}
li.events = events;
li.num_events = g_list_length (events);
li.func = func;
/* Build the partition of the time range, and then build the array of slots */
build_partition (&li);
li.array = g_new (int, li.num_rows * MAX_EVENTS_PER_ROW);
for (i = 0; i < (li.num_rows * MAX_EVENTS_PER_ROW); i++)
li.array[i] = -1; /* This is our 'empty' value */
/* Build the arrays for allocations and columns used */
li.allocations = g_new (int, li.num_events);
li.slots = g_new (int, li.num_events);
/* Perform initial allocation and then expand the events to as many slots as they can occupy */
initial_allocate (&li);
expand_events (&li);
/* Clean up and return values */
g_free (li.array);
*num_slots = li.num_slots;
*allocations = li.allocations;
*slots = li.slots;
}
