Mercurial > ~darius > hgwebdir.cgi > paradise_server
view src/findslot.c @ 18:1424868939a8
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author | darius |
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date | Wed, 24 Dec 1997 12:38:35 +0000 |
parents | aa38447a4b21 |
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/*-------------------------------------------------------------------------- NETREK II -- Paradise Permission to use, copy, modify, and distribute this software and its documentation, or any derivative works thereof, for any NON-COMMERCIAL purpose and without fee is hereby granted, provided that this copyright notice appear in all copies. No representations are made about the suitability of this software for any purpose. This software is provided "as is" without express or implied warranty. Xtrek Copyright 1986 Chris Guthrie Netrek (Xtrek II) Copyright 1989 Kevin P. Smith Scott Silvey Paradise II (Netrek II) Copyright 1993 Larry Denys Kurt Olsen Brandon Gillespie --------------------------------------------------------------------------*/ #include "config.h" #include <stdio.h> #include <sys/types.h> #include <sys/ipc.h> #include <sys/shm.h> #include <errno.h> #include <pwd.h> #include <string.h> #include <ctype.h> #include "defs.h" #include "struct.h" #include "data.h" #include "packets.h" #include "shmem.h" int grabslot( /* int */ ); void mapWaitCount( /* int */ ); extern int isClientDead(); extern unsigned int sleep(); extern int sendQueuePacket(); extern int flushSockBuf(); int findslot(overload, homeaway) int overload; enum HomeAway homeaway; { int i; i = grabslot(overload, homeaway); players[i].p_pos = -1; memset(&players[i].p_stats, 0, sizeof(struct stats)); players[i].p_stats.st_tticks = 1; #if 0 for (j = 0; j < 95; j++) { players[i].p_stats.st_keymap[j] = j + 32; } players[i].p_stats.st_keymap[95] = 0; #endif players[i].p_stats.st_flags = ST_INITIAL; return (i); } static int allocate_slot(homeaway, overload, allocate) enum HomeAway homeaway; int overload; int allocate; { int i; if (overload) { for (i = MAXPLAYER - 1; i >= 0; i--) { if (players[i].p_status == PFREE) { if (allocate) { players[i].p_status = POUTFIT; players[i].p_team = NOBODY; } return i; } } } else { #ifdef LEAGUE_SUPPORT if (status2->league) { /* * for league play, make sure one team doesn't crowd out the other. */ int count = 0; for (i = 0; i < MAXPLAYER; i++) { if (players[i].p_status == PFREE) continue; if (players[i].p_homeaway == homeaway) count++; } if (count * 2 >= MAXPLAYER - configvals->ntesters) return -1; /* our team is full */ } #endif for (i = 0; i < MAXPLAYER - configvals->ntesters; i++) { if (players[i].p_status == PFREE) { if (allocate) { players[i].p_status = POUTFIT; players[i].p_team = NOBODY; } return i; } } } return -1; } #if 0 static int ImAllowed(slotnum, homeaway) int slotnum; enum HomeAway homeaway; { #ifdef LEAGUE_SUPPORT int half; if (!status2->league) return 1; half = (MAXPLAYER - configvals->ntesters) / 2; return (homeaway == AWAY) ? (slotnum < half) : (slotnum >= half); #else return 1; #endif } #endif /* * The following code for grabslot() is really bizarre, and needs an * explaination. * * Basically, the queue works like this: Each process that needs to wait takes * a number, and when that number comes up, the process enters the game. * status->count is the next number to take for a new process, and * status->wait is the current process being served. * * However, this is not enough to determine exactly how many people are waiting, * because people may drop out. So, 3 more variables are added, * status->request posts a request of some sort to all of the other * processes, and status->number is the process posting the request. Also, * status->answer is available for any kind of response needed from the other * processes. (Needless to say, only one process can make a request at any * one time). * * Every process will wait for a second (sleep(1)), and then check the queue * status, do what is appropriate, and repeat. * * Above and beyond this, processes may die, and not report it (for whatever * reason, and every process waiting on the queue watches the behavior of * every other supposed process to make sure it is still alive). * * When a space opens up, and the person who holds the number currently being * served does not respond, then the processes argue over who deserves to get * in next. The first process to decide that no one is going to take the * free slot says that his number is the next on to be served. He waits for * anyone to disagree with him. Any other processes which notice that their * number is lower than the number being served claim that their number is * the next one to be served. They also wait for anyone to disagree with * them. Eventually, everyone is done waiting, and the process with the * lowest count will be served. * * Variables: status->wait: Number being served. status->count: Next * number to take. * * status->request: Process request. (status->number) (status->answer) * REQFREE: No requests pending. REQWHO: How many people are * before me? In this case, every process in from of this process (whose * position is recorded in status->number) increments status->answer. * REQDEAD: I am leaving the queue (Either to quit, or enter game). Any * process whose position is higher than this process will note that they are * closer to the top of the queue. * * (Local) waitWin: The window. qwin: The quit half of waitWin. * countWin: The count half of waitWin. count: My number (Position * in queue). pseudocount: Number of people in front of me (-1 means I don't * know). myRequest: This keeps track of requests I've made. If it is non * zero, then this is the number of times I will leave it there before I get * my answer (if there is one), and reset status->request. idie: This * is set to one if I need to leave the queue. When I get a chance, I will * submit my request, and leave. wearein: This is the slot we grabbed * to enter the game. If it is -1, then we haven't got a slot yet. If we * can grab a slot, then wearein is set to the slot #, and idie is set to 1. * * Because we need to monitor other processes, the following variables also * exist: * * oldcount: The number that was being served last time I looked. waits: * Number of times I've seen oldcount as the number being served. If a * position opens in the game, and no one takes it for a while, we assume * that someone died. lastRequest: The last request I have seen. * lastNumber: The process making this request. reqCount: Number of * times I've seen this request. If I see this request 9 times, I assume it * is obsolete, and I reset it. */ int grabslot(overload, homeaway) int overload; /* Indicates a request for a tester's slot. */ enum HomeAway homeaway; { int count; /* My number */ int oldcount; /* Number that was being served last check */ int i; int waits; /* # times I have waited for someone else to * act */ int oldwait; /* Number being served last check */ int pseudocount = -1; /* Count on queue for sake of person waiting */ int myRequest = 0; /* To keep track of any request I'm making */ int lastRequest = 0; /* Last request I've seen */ int lastNumber = 0; /* Last person making request */ int reqCount = 0; /* Number of times I've seen this */ int idie = 0; /* Do I want to die? */ int wearein = -1; /* Slot we got in the game */ int rep = 0; /* If other players waiting, we get in line behind them */ if (!overload && status->wait != status->count) { count = status->count++; } else { /* Get in game if posible */ #if 1 i = allocate_slot(homeaway, overload, 1); if (i >= 0) return i; #else if (overload) for (i = MAXPLAYER - 1; i >= 0; i--) { if (players[i].p_status == PFREE) { /* We have a free slot */ players[i].p_status = POUTFIT; /* possible race code */ players[i].p_team = NOBODY; return (i); } } else for (i = 0; i < MAXPLAYER - configvals->ntesters; i++) { if (ImAllowed(i, homeaway) && players[i].p_status == PFREE) { /* We have a free slot */ players[i].p_status = POUTFIT; /* possible race code */ players[i].p_team = NOBODY; return (i); } } #endif /* Game full. We will wait. */ count = status->count++; } waits = 0; oldwait = -1; oldcount = status->wait; /* For count = 0,1,2 I know that it is right */ if (count - status->wait < 1) { pseudocount = count - status->wait; } for (;;) { /* Send packets occasionally to see if he is accepting... */ if (rep++ % 10 == 0) { mapWaitCount(pseudocount); } if (isClientDead()) { if (count == status->count - 1) { status->count--; exit(0); } /* If we are at top, decrease it */ if (count == status->wait) { status->wait++; } idie = 1; /* break; warning, function has return e and return */ exit(0); } if (status->wait != oldcount) { mapWaitCount(pseudocount); oldcount = status->wait; } /* To mimize process overhead and aid synchronization */ sleep(1); /* Message from daemon that it died */ if (status->count == 0) exit(0); /* I have a completed request? */ if (myRequest != 0 && --myRequest == 0) { if (idie && status->request == REQDEAD) { status->request = REQFREE; /* Out of queue, into game */ if (wearein != -1) { return (wearein); } exit(0); } pseudocount = status->answer; status->request = REQFREE; if (pseudocount > 18) idie = 1; mapWaitCount(pseudocount); } /* Tell the world I am going bye bye */ if (idie && status->request == REQFREE) { status->request = REQDEAD; status->number = count; myRequest = 4; } /* Should I request a count for # of people waiting? */ if (pseudocount == -1 && status->request == REQFREE) { status->request = REQWHO; status->number = count; status->answer = 0; myRequest = 4; /* I give people 4 seconds to respond */ } /* Is someone else making a request? */ if (status->request != REQFREE && myRequest == 0) { if (status->request == lastRequest && status->number == lastNumber) { reqCount++; /* 9 occurances of the same request implies that the process */ /* died. I will reset request. */ if (reqCount > 8) { status->request = REQFREE; } } else { lastRequest = status->request; lastNumber = status->number; reqCount = 1; if (lastRequest == REQWHO) { if (count < lastNumber) { status->answer++; } } else if (lastRequest == REQDEAD) { if (count > lastNumber && pseudocount != -1) { pseudocount--; mapWaitCount(pseudocount); } } } } /* If someone raised wait too high, I claim that I * am next in line */ if (status->wait > count && !idie) { status->wait = count; /* Give people a chance to correct me */ sleep(2); } #if 1 if (idie) continue; if (count == status->wait) { i = allocate_slot(homeaway, overload, 1); if (i < 0) continue; status->wait++; wearein = i; idie = 1; } else { i = allocate_slot(homeaway, overload, 0); if (i < 0) continue; if (oldwait == status->wait) { waits++; } else { oldwait = status->wait; waits = 1; } /* If this is our fifth wait (5 sec), then something is */ /* wrong. We assume someone died, and fix this problem */ if (waits == 5 && !idie) { /* I want to be next in line, so I say so. */ status->wait = count; /* And I allow someone to correct me if I'm wrong */ sleep(2); waits = 0; } } #else for (i = 0; i < MAXPLAYER - configvals->ntesters; i++) { /* If we want to die anyway, we have no right looking for */ /* a free slot */ if (idie) break; if (ImAllowed(i, homeaway) && players[i].p_status == PFREE) { /* If I am next in line... */ if (count == status->wait) { players[i].p_status = POUTFIT; players[i].p_team = NOBODY; /* Increase count for next player */ status->wait++; /* I should check idie, but maybe he wants in, eh? */ wearein = i; idie = 1; break; } else { if (oldwait == status->wait) { waits++; } else { oldwait = status->wait; waits = 1; } /* If this is our fifth wait (5 sec), then something is */ /* wrong. We assume someone died, and fix this problem */ if (waits == 5 && !idie) { /* I want to be next in line, so I say so. */ status->wait = count; /* And I allow someone to correct me if I'm wrong */ sleep(2); waits = 0; } break; } } } #endif /* this location is skipped if we didn't find a slot */ } } void mapWaitCount(count) unsigned int count; { if (count == -1) return; sendQueuePacket((short) count); blk_flag = 1; updateMOTD(); blk_flag = 0; undeferDeferred(); /* send the MOTD through the TCP buffers */ flushSockBuf(); }