/* This software is being provided to you, the LICENSEE, by the Massachusetts Institute of Technology (M.I.T.) under the following license. By obtaining, using and/or copying this software, you agree that you have read, understood, and will comply with these terms and conditions: Permission to use, copy, modify and distribute, including the right to grant others the right to distribute at any tier, this software and its documentation for any purpose and without fee or royalty is hereby granted, provided that you agree to comply with the following copyright notice and statements, including the disclaimer, and that the same appear on ALL copies of the software and documentation, including modifications that you make for internal use or for distribution: Copyright 1992,1993 by the Massachusetts Institute of Technology. All rights reserved. THIS SOFTWARE IS PROVIDED "AS IS", AND M.I.T. MAKES NO REPRESENTATIONS OR WARRANTIES, EXPRESS OR IMPLIED. By way of example, but not limitation, M.I.T. MAKES NO REPRESENTATIONS OR WARRANTIES OF MERCHANTABILITY OR FITNESS FOR ANY PARTICULAR PURPOSE OR THAT THE USE OF THE LICENSED SOFTWARE OR DOCUMENTATION WILL NOT INFRINGE ANY THIRD PARTY PATENTS, COPYRIGHTS, TRADEMARKS OR OTHER RIGHTS. The name of the Massachusetts Institute of Technology or M.I.T. may NOT be used in advertising or publicity pertaining to distribution of the software. Title to copyright in this software and any associated documentation shall at all times remain with M.I.T., and USER agrees to preserve same. */ #include "xplot.h" #include #include inline static void timeval_fix(coord *r) { while (r->t.tv_usec < 0) { r->t.tv_usec += 1000000; r->t.tv_sec -= 1; } while (r->t.tv_usec >= 1000000) { r->t.tv_usec -= 1000000; r->t.tv_sec += 1; } } char *timeval_unparse(coord c) { char *cp; char *r; char buf[50]; struct tm *tmp; tmp = localtime((time_t *) &(c.t.tv_sec)); (void) sprintf(buf,"%s",asctime(tmp)); if (c.t.tv_usec == 0 && tmp->tm_sec == 0 && tmp->tm_min == 0 && tmp->tm_hour == 0) { cp = buf+4; sprintf(cp+7,"midn"); } else if (c.t.tv_usec == 0 && tmp->tm_sec == 0 && tmp->tm_min == 0 && tmp->tm_hour == 12) { cp = buf+4; sprintf(cp+7,"noon"); } else { cp = buf+10; cp[10] = '\0'; if (c.t.tv_usec != 0) { if (c.t.tv_usec % 100 == 0) { (void) sprintf(cp+9,".%04u",(unsigned) c.t.tv_usec/100); cp += 7; } else { (void) sprintf(cp+9,".%06u",(unsigned) c.t.tv_usec); cp += 9; } } } r = malloc((unsigned) strlen(cp)+1); if (r == 0) fatalerror("malloc returned 0"); (void) strcpy(r, cp); return r; } coord timeval_parse(char *s) { coord r; extern int atoi(); r.t.tv_usec = 0; /* quick, dirty, and unsafe */ r.t.tv_sec = atoi(s); while (isdigit(*s)) s++; if (*s == '.') { s++; r.t.tv_usec = atoi(s); { int len = 0; while (isdigit(*s++)) len++; while (len < 6) (len++, r.t.tv_usec *= 10); while (len > 6) (len--, r.t.tv_usec /= 10); } } timeval_fix(&r); return r; } coord timeval_zero(void) { coord r; r.t.tv_sec = 0; r.t.tv_usec = 0; return r; } int timeval_cmp(coord c1, coord c2) { int r; if (c1.t.tv_sec > c2.t.tv_sec) r = 1; else if (c1.t.tv_sec < c2.t.tv_sec) r = -1; else if (c1.t.tv_usec > c2.t.tv_usec) r = 1; else if (c1.t.tv_usec < c2.t.tv_usec) r = -1; else r = 0; return r; } coord timeval_add(coord c1, coord c2) { coord r; r.t.tv_sec = c1.t.tv_sec + c2.t.tv_sec; r.t.tv_usec = c1.t.tv_usec + c2.t.tv_usec; timeval_fix(&r); return r; } coord timeval_subtract(coord c1,coord c2) { coord r; timeval_fix(&r); if (c2.t.tv_usec > c1.t.tv_usec) { c1.t.tv_sec -= 1; c1.t.tv_usec += 1000000; } r.t.tv_sec = c1.t.tv_sec - c2.t.tv_sec; r.t.tv_usec = c1.t.tv_usec - c2.t.tv_usec; return r; } coord timeval_round_down(coord c1, coord c2) { coord r; struct tm *tmp; tmp = localtime((time_t *) &(c1.t.tv_sec)); #ifdef HAVE_TM_GMTOFF c1.t.tv_sec += tmp->tm_gmtoff; #endif if (c2.t.tv_sec == 0) { r.t.tv_sec = c1.t.tv_sec; r.t.tv_usec = (c1.t.tv_usec - (c1.t.tv_usec % c2.t.tv_usec)); } else { r.t.tv_usec = 0; r.t.tv_sec = c1.t.tv_sec - (c1.t.tv_sec % c2.t.tv_sec); } #ifdef HAVE_TM_GMTOFF r.t.tv_sec -= tmp->tm_gmtoff; #endif timeval_fix(&r); return r; } coord timeval_round_up(coord c1, coord c2) { coord r; struct tm *tmp; tmp = localtime((time_t *) &(c1.t.tv_sec)); #ifdef HAVE_TM_GMTOFF c1.t.tv_sec += tmp->tm_gmtoff; #endif if (c2.t.tv_sec == 0) { r.t.tv_sec = c1.t.tv_sec; if (c1.t.tv_usec % c2.t.tv_usec == 0) r.t.tv_usec = c1.t.tv_usec; else { r.t.tv_usec = c1.t.tv_usec + (c2.t.tv_usec - (c1.t.tv_usec % c2.t.tv_usec)); if (r.t.tv_usec >= 1000000) { r.t.tv_usec -= 1000000; r.t.tv_sec += 1; } } } else { r.t.tv_usec = 0; if (c1.t.tv_sec % c2.t.tv_sec == 0) r.t.tv_sec = c1.t.tv_sec; else r.t.tv_sec = c1.t.tv_sec + (c2.t.tv_sec - (c1.t.tv_sec % c2.t.tv_sec)); } #ifdef HAVE_TM_GMTOFF r.t.tv_sec -= tmp->tm_gmtoff; #endif timeval_fix(&r); return r; #if 0 return timeval_round_down(timeval_add(c1,c2), c2); #endif } static struct tick_table_s { struct timeval step; int subtick_offset; } tick_table[] = { {{ 0, 1 }, 0 }, {{ 0, 2 }, -1 }, {{ 0, 5 }, -2 }, {{ 0, 10 }, -2 }, {{ 0, 20 }, -2 }, {{ 0, 50 }, -2 }, {{ 0, 100 }, -2 }, {{ 0, 200 }, -2 }, {{ 0, 500 }, -2 }, {{ 0, 1000 }, -2 }, {{ 0, 2000 }, -2 }, {{ 0, 5000 }, -2 }, {{ 0, 10000 }, -2 }, {{ 0, 20000 }, -2 }, {{ 0, 50000 }, -2 }, {{ 0, 100000 }, -2 }, {{ 0, 200000 }, -2 }, {{ 0, 500000 }, -2 }, {{ 1, 0 }, -2 }, {{ 2, 0 }, -2 }, {{ 5, 0 }, -2 }, {{ 10, 0 }, -2 }, {{ 20, 0 }, -2 }, {{ 30, 0 }, -2 }, {{ 1*60, 0 }, -2 }, {{ 2*60, 0 }, -2 }, {{ 5*60, 0 }, -2 }, {{ 10*60, 0 }, -2 }, {{ 20*60, 0 }, -2 }, {{ 30*60, 0 }, -2 }, {{ 1*60*60, 0 }, -2 }, {{ 2*60*60, 0 }, -2 }, {{ 6*60*60, 0 }, -2 }, {{ 12*60*60, 0 }, -2 }, {{ 24*60*60, 0 }, -2 }, {{ 2*24*60*60, 0 }, -2 }, {{ 5*24*60*60, 0 }, -2 }, {{ 10*24*60*60, 0 }, -2 }, {{ 20*24*60*60, 0 }, -2 }, {{ 50*24*60*60, 0 }, -2 }, {{ 100*24*60*60, 0 }, -2 }, {{ 200*24*60*60, 0 }, -2 }, {{ 500*24*60*60, 0 }, -2 }, {{ 1000*24*60*60, 0 }, -2 }, {{ 2000*24*60*60, 0 }, -2 }, {{ 5000*24*60*60, 0 }, -2 }, {{ 10000*24*60*60, 0 }, -2 }, }; coord timeval_tick(int level) { coord r; if (level < 0 || level >= sizeof(tick_table) / sizeof(struct tick_table_s)) panic("timeval_tick: level too large"); r.t = tick_table[level].step; timeval_fix(&r); return r; } int timeval_subtick(int level) { int r; if (level < 0 || level >= sizeof(tick_table) / sizeof(struct tick_table_s)) panic("timeval_subtick: level too large"); r = level + tick_table[level].subtick_offset; return r; } double timeval_map(coord c1,coord c2, int n, coord c) { double r; double d; double dc; d = (((double) ((int) (c2.t.tv_sec - c1.t.tv_sec))) * 1000000 + ((double) ((int) (c2.t.tv_usec - c1.t.tv_usec)))); dc = (((double) ((int) (c.t.tv_sec - c1.t.tv_sec))) * 1000000 + ((double) ((int) (c.t.tv_usec - c1.t.tv_usec)))); r = dc/d * ((double) n); return r; } coord timeval_unmap(coord c1,coord c2, int n, double x) { coord r; double d; d = (((double) (c2.t.tv_sec - c1.t.tv_sec)) * 1000000 + ((double) (c2.t.tv_usec - c1.t.tv_usec))); d /= n; d *= x; d += ((double) c1.t.tv_sec * 1000000) + (double) c1.t.tv_usec; r.t.tv_sec = floor(d/1000000.); r.t.tv_usec = rint(d - (((double) floor(d/1000000.)) * 1000000.)); return r; } struct coord_impl timeval_impl = { timeval_unparse, timeval_parse, timeval_zero, timeval_cmp, timeval_add, timeval_subtract, timeval_round_up, timeval_round_down, timeval_tick, timeval_subtick, timeval_map, timeval_unmap };