code: 9ferno

ref: 83246e296ea433b65b9d295b5e08fedd39ff1ab7
dir: /liblogfs/scan.c/

View raw version
#include "logfsos.h"
#include "logfs.h"
#include "local.h"
#include "fcall.h"

typedef struct PathEnt {
	ulong path;	
	long block;
} PathEnt;

typedef struct GenInfo {
	long start;
	long end;
	int gaps;
} GenInfo;

static int
dataorder(ulong p1, ulong p2)
{
	int o;
	o = dataseqof(p1) - dataseqof(p2);
	if(o != 0)
		return o;
	return copygenof(p1) - copygenof(p2);
}

static int
logorder(ulong p1, ulong p2)
{
	int o;
	o = loggenof(p1) - loggenof(p2);
	if(o != 0)
		return o;
	o = logseqof(p1) - logseqof(p2);
	if(o != 0)
		return o;
	return copygenof(p1) - copygenof(p2);
}

static void
insert(PathEnt *pathmap, long entries, ulong path, long block, int (*order)(ulong p1, ulong p2))
{
	long i;
	for(i = 0; i < entries; i++)
		if((*order)(path, pathmap[i].path) < 0)
			break;
	memmove(&pathmap[i + 1], &pathmap[i], (entries - i) * sizeof(PathEnt));
	pathmap[i].path = path;
	pathmap[i].block = block;
}

static void
populate(LogSegment *seg, int gen, long unsweptblockindex, long curblockindex, PathEnt *pathent)
{
	long i;
	seg->gen = gen;
	seg->unsweptblockindex = unsweptblockindex;
	seg->curblockindex = curblockindex;
	for(i = unsweptblockindex; i <= curblockindex; i++) {
//		print("populate %d: %d\n", i, pathent[i - unsweptblockindex].block);
		seg->blockmap[i] = pathent->block;
		pathent++;
	}
}

static int
dataduplicate(PathEnt *p1, PathEnt *p2)
{
	return dataseqof(p2->path) == dataseqof(p1->path)
		&& copygenof(p2->path) == copygensucc(copygenof(p1->path));
}

static char *
eliminateduplicates(LogfsServer *server, char *name, PathEnt *map, long *entriesp)
{
	long i;
	long k = *entriesp;
	for(i = 0; i < k;) {
		PathEnt *prev = &map[i - 1];
		PathEnt *this = &map[i];
		if(i > 0 && dataduplicate(prev, this)) {
			print("%s duplicate detected\n", name);
			if(i + 1 < k && dataduplicate(this, &map[i + 1]))
				return "three or more copies of same block";
			/*
			 * check that the copy generations are in order
			 */
			if(copygensucc(copygenof(this->path)) == copygenof(prev->path)) {
				PathEnt m;
				/*
				 * previous entry is newer, so swap
				 */
				m = *this;
				*this = *prev;
				*prev = m;
			}
			else if(copygensucc(copygenof(prev->path)) != copygenof(this->path))
				return "duplicate blocks but copy generations not sequential";
			/* erase and format previous block */
			logfsbootfettleblock(server->lb, prev->block, LogfsTnone, ~0, nil);
			/*
			 * remove entry from table
			 */
			memmove(prev, this, sizeof(PathEnt) * (k - i));
			k--;
			continue;
		}
		i++;
	}
	*entriesp = k;
	return nil;
}

char *
logfsscan(LogfsServer *server)
{
	LogfsLowLevel *ll = server->ll;
	long b;
	long i;
	long logfound = 0;
	long datafound = 0;
	PathEnt *logpathmap, *datapathmap;
	GenInfo geninfo[1 << L2LogSweeps];
	int gensfound, lastgenfound;
	int g0, g1;
	char *errmsg;
//print("logfsscan %ld blocks\n", server->ll->blocks);
	logpathmap = logfsrealloc(nil, sizeof(PathEnt) * server->ll->blocks);
	datapathmap = logfsrealloc(nil, sizeof(PathEnt) * server->ll->blocks);
	if(logpathmap == nil || datapathmap == nil)
		return Enomem;
	for(b = 0; b < ll->blocks; b++) {
		short tag = (*ll->getblocktag)(ll, b);
		ulong path = (*ll->getblockpath)(ll, b);
//print("scan: %ld: %d %ld\n", b, tag, path);
		switch(tag) {
		case LogfsTlog:
			insert(logpathmap, logfound++, path, b, logorder);
			break;
		case LogfsTdata:
			insert(datapathmap, datafound++, path, b, dataorder);
			break;
		}
	}
	if(server->trace > 1) {
		for(i = 0; i < logfound; i++)
			print("log gen %lud seq %lud copygen %lud block %ld\n",
				loggenof(logpathmap[i].path), logseqof(logpathmap[i].path), copygenof(datapathmap[i].path), logpathmap[i].block);
		for(i = 0; i < datafound; i++)
			print("data seq %lud copygen %lud block %ld\n",
				dataseqof(datapathmap[i].path), copygenof(datapathmap[i].path), datapathmap[i].block);
	}
	/*
	 * sort out data first
	 */
	errmsg = eliminateduplicates(server, "data", datapathmap, &datafound);
	if(errmsg)
		goto fail;
	/*
	 * data blocks guaranteed to be ordered
	 */
	if(datafound)
		server->ndatablocks = dataseqof(datapathmap[datafound - 1].path) + 1;
	else
		server->ndatablocks = 0;
	for(i = 0; i < server->ndatablocks; i++)
		server->datablock[i].block = -1;
	for(i = 0; i < datafound; i++) {
		long j;
		j = dataseqof(datapathmap[i].path);
		server->datablock[j].path = datapathmap[i].path;
		server->datablock[j].block = datapathmap[i].block;
		/*
		 * mark pages as free and dirty, which indicates they cannot be used
	 	*/
		server->datablock[j].dirty = server->datablock[j].free = logfsdatapagemask(1 << ll->l2pagesperblock, 0);
	}
	/*
	 * find how many generations are present, and whether there are any gaps
	 */
	errmsg = eliminateduplicates(server, "log", logpathmap, &logfound);
	if(errmsg)
		goto fail;
	gensfound = 0;
	lastgenfound = -1;
	for(i = 0; i < nelem(geninfo); i++)
		geninfo[i].start = -1;
	for(i = 0; i < logfound; i++) {
		int gen;
		gen = loggenof(logpathmap[i].path);
		if(geninfo[gen].start < 0) {
			if(lastgenfound >= 0)
				geninfo[lastgenfound].end = i;
			geninfo[gen].start = i;
			lastgenfound = gen;
			geninfo[gen].gaps = 0;
			gensfound++;
		}
		else if(!geninfo[lastgenfound].gaps && logseqof(logpathmap[i - 1].path) + 1 != logseqof(logpathmap[i].path)) {
			geninfo[lastgenfound].gaps = 1;
			print("generation %d has gaps (%lud, %lud)\n", lastgenfound,
				logseqof(logpathmap[i - 1].path), logseqof(logpathmap[i].path));
		}
	}
	if(lastgenfound >= 0)
		geninfo[lastgenfound].end = i;
	if(server->trace > 1) {
		for(i = 0; i < nelem(geninfo); i++)
			print("geninfo: %ld: start %ld end %ld gaps %d\n", i, geninfo[i].start, geninfo[i].end, geninfo[i].gaps);
	}
	switch(gensfound) {
	case 0:
		/* active log - empty */
		break;
	case 1:
		/*
		 * one log, active
		 */
		for(g0 = 0; g0 < nelem(geninfo); g0++)
			if(geninfo[g0].start >= 0)
				break;
		if(geninfo[g0].gaps || geninfo[g0].start != 0) {
			errmsg = "missing log blocks";
			goto fail;
		}
		populate(server->activelog, g0, 0, geninfo[g0].end - geninfo[g0].start - 1, logpathmap + geninfo[g0].start);
		break;
	case 2:
		/*
		 * two logs, active, swept
		 */
		g0 = -1;
		for(g1 = 0; g1 < nelem(geninfo); g1++)
			if(geninfo[g1].start >= 0) {
				if(g0 < 0)
					g0 = g1;
				else 
					break;
			}
		if(geninfo[g0].gaps || geninfo[g1].gaps) {
			errmsg = "missing log blocks";
			goto fail;
		}
		if(g0 == loggensucc(g1)) {
			int tmp = g0;
			g0 = g1;
			g1 = tmp;
		}
		else if(g1 != loggensucc(g0)) {
			errmsg = "nonsequential generations in log";
			goto fail;
		}
		if(logseqof(logpathmap[geninfo[g1].start].path) != 0) {
			errmsg = "swept log does not start at 0";
			goto fail;
		}
		if(logseqof(logpathmap[geninfo[g0].start].path) == logseqof(logpathmap[geninfo[g1].end - 1].path)) {
			/*
			 * duplicate block
			 * as the log never gets bigger, information from active[n] is either entirely in swept[n],
			 * or split between swept[n-1] and swept[n]. we can safely remove swept[n]. this might
			 * leave some duplication between swept[n - 1] and active[n], but this is always true
			 * for a partially swept log
			 */
			logfsbootfettleblock(server->lb, logpathmap[geninfo[g1].end - 1].block, LogfsTnone, ~0, nil);
			geninfo[g1].end--;
		}
		if(logseqof(logpathmap[geninfo[g0].start].path) < logseqof(logpathmap[geninfo[g1].end - 1].path)) {
			errmsg = "active log overlaps end of swept log";
			goto fail;
		}
		populate(server->activelog, g0, logseqof(logpathmap[geninfo[g0].start].path),
			logseqof(logpathmap[geninfo[g0].end - 1].path), logpathmap + geninfo[g0].start);
		if(server->sweptlog == nil) {
			errmsg = logfslogsegmentnew(server, g1, &server->sweptlog);
			if(errmsg)
				goto fail;
		}
		populate(server->sweptlog, g1, logseqof(logpathmap[geninfo[g1].start].path),
			logseqof(logpathmap[geninfo[g1].end - 1].path), logpathmap + geninfo[g1].start);
		break;
	default:	
		errmsg = "more than two generations in log";
		goto fail;
	}
	goto ok;
fail:
	logfslogsegmentfree(&server->sweptlog);
ok:
	logfsfreemem(logpathmap);
	logfsfreemem(datapathmap);
	return errmsg;
}