static void test_ksToArray ()
{
KeySet * ks = ksNew (5, keyNew ("user/test1", KEY_END), keyNew ("user/test2", KEY_END), keyNew ("user/test3", KEY_END), KS_END);
Key ** keyArray = calloc (ksGetSize (ks), sizeof (Key *));
elektraKsToMemArray (ks, keyArray);
succeed_if_same_string ("user/test1", keyName (keyArray[0]));
succeed_if_same_string ("user/test2", keyName (keyArray[1]));
succeed_if_same_string ("user/test3", keyName (keyArray[2]));
/* test if cursor is restored */
ksNext (ks);
cursor_t cursor = ksGetCursor (ks);
elektraKsToMemArray (ks, keyArray);
succeed_if (ksGetCursor (ks) == cursor, "cursor was not restored");
succeed_if (elektraKsToMemArray (0, keyArray) < 0, "wrong result on null pointer");
succeed_if (elektraKsToMemArray (ks, 0) < 0, "wrong result on null buffer");
KeySet * empty = ksNew (0, KS_END);
succeed_if (elektraKsToMemArray (empty, keyArray) == 0, "wrong result on empty keyset");
ksDel (empty);
elektraFree (keyArray);
ksDel (ks);
}
static int saveTree (augeas * augeasHandle, KeySet * ks, const char * lensPath, Key * parentKey)
{
int ret = 0;
size_t prefixSize = keyGetNameSize (parentKey) - 1;
size_t arraySize = ksGetSize (ks);
Key ** keyArray = calloc (ksGetSize (ks), sizeof (Key *));
ret = elektraKsToMemArray (ks, keyArray);
if (ret < 0) goto memoryerror;
qsort (keyArray, arraySize, sizeof (Key *), keyCmpOrderWrapper);
/* convert the Elektra KeySet to an Augeas tree */
for (size_t i = 0; i < arraySize; i++)
{
Key * key = keyArray[i];
char * nodeName;
ret = asprintf (&nodeName, AUGEAS_TREE_ROOT "%s", (keyName (key) + prefixSize));
if (ret < 0) goto memoryerror;
aug_set (augeasHandle, nodeName, keyString (key));
elektraFree (nodeName);
}
elektraFree (keyArray);
/* remove keys not present in the KeySet */
struct OrphanSearch * data = elektraMalloc (sizeof (struct OrphanSearch));
if (!data) return -1;
data->ks = ks;
data->parentKey = parentKey;
ret = foreachAugeasNode (augeasHandle, AUGEAS_TREE_ROOT, &removeOrphan, data);
elektraFree (data);
/* build the tree */
ret = aug_text_retrieve (augeasHandle, lensPath, AUGEAS_CONTENT_ROOT, AUGEAS_TREE_ROOT, AUGEAS_OUTPUT_ROOT);
if (ret < 0)
{
/* report the augeas specific error */
ELEKTRA_SET_ERROR (85, parentKey, getAugeasError (augeasHandle));
}
return ret;
memoryerror:
elektraFree (keyArray);
ELEKTRA_SET_ERROR (87, parentKey, "Unable to allocate memory while saving the augeas tree");
return -1;
}
static int saveTree(augeas* augeasHandle, KeySet* ks, const char* lensPath,
Key *parentKey)
{
int ret = 0;
size_t prefixSize = keyGetNameSize (parentKey) - 1;
size_t arraySize = ksGetSize (ks);
Key **keyArray = calloc (ksGetSize(ks), sizeof (Key *));
ret = elektraKsToMemArray (ks, keyArray);
if (ret < 0)
{
free (keyArray);
return -1;
}
qsort (keyArray, arraySize, sizeof(Key *), keyCmpOrderWrapper);
/* convert the Elektra KeySet to an Augeas tree */
for (size_t i = 0; i < arraySize; i++)
{
Key *key = keyArray[i];
char *nodeName;
asprintf (&nodeName, AUGEAS_TREE_ROOT "%s",
(keyName (key) + prefixSize));
aug_set (augeasHandle, nodeName, keyString (key));
free (nodeName);
}
free (keyArray);
/* remove keys not present in the KeySet */
struct OrphanSearch *data = malloc (sizeof(struct OrphanSearch));
if (!data) return -1;
data->ks = ks;
data->parentKey = parentKey;
foreachAugeasNode (augeasHandle, AUGEAS_TREE_ROOT, &removeOrphan, data);
free (data);
/* build the tree */
ret = aug_text_retrieve (augeasHandle, lensPath, AUGEAS_CONTENT_ROOT,
AUGEAS_TREE_ROOT, AUGEAS_OUTPUT_ROOT);
return ret;
}
int elektraSortTopology (KeySet * ks, Key ** array)
{
if (ks == NULL || array == NULL) return -1;
KeySet * done = ksNew (0, KS_END);
ksRewind (ks);
Key * cur;
ssize_t size = ksGetSize (ks);
Key * orderCounter = keyNew ("/#", KEY_CASCADING_NAME, KEY_END);
elektraArrayIncName (orderCounter);
_adjMatrix adjMatrix[size];
int i = 0;
int retVal = 1;
int depCount = 0;
Key ** localArray = elektraMalloc (size * sizeof (Key *));
elektraKsToMemArray (ks, localArray);
qsort (localArray, size, sizeof (Key *), topCmpOrder);
for (long j = 0; j < size; ++j)
{
adjMatrix[j].key = localArray[j];
adjMatrix[j].isResolved = 0;
adjMatrix[j].deps = elektraCalloc (sizeof (unsigned long) * size);
}
kdb_octet_t hasOrder = 0;
if (keyGetMeta (localArray[0], "order")) hasOrder = 1;
unsigned int unresolved = 0;
for (int j = 0; j < size; ++j)
{
cur = localArray[j];
KeySet * deps = elektraMetaArrayToKS (cur, "dep");
keyDel (ksLookupByName (deps, "dep", KDB_O_POP));
Key * tmpDep;
switch (ksGetSize (deps))
{
case -1:
{
// key has no dependencies, give it an order number and add it to list of resolved dependencies
keySetMeta (cur, "order", keyBaseName (orderCounter));
elektraArrayIncName (orderCounter);
ksAppendKey (done, keyDup (cur));
adjMatrix[j].isResolved = 1;
ksDel (deps);
break;
}
case 1:
{
// only 1 dependency:
// test if it's reflexive
tmpDep = ksHead (deps);
if (!strcmp (keyName (cur), keyString (tmpDep)))
{
keySetMeta (cur, "order", keyBaseName (orderCounter));
elektraArrayIncName (orderCounter);
ksAppendKey (done, keyDup (cur));
adjMatrix[j].isResolved = 1;
ksDel (deps);
break;
}
// if not, fallthrough to normal dependency handling
}
default:
{
int gotUnresolved = 0;
while ((tmpDep = ksNext (deps)) != NULL)
{
if (!isValidKeyName (keyString (tmpDep)))
{
// invalid keyname -> ERROR
retVal = -1;
break;
}
i = getArrayIndex (tmpDep, adjMatrix, size);
if (i == -1)
{
// key doesn't exist yet but has valid name, ignore it.
continue;
}
else if (i == j)
{
// reflexiv depencency, do nothing
}
else
{
if (!adjMatrix[i].isResolved)
{
// unresolved dependency
adjMatrix[j].deps[i] = 1;
++gotUnresolved;
// simple cycle detection
if (adjMatrix[i].deps[j])
{
retVal = 0;
break;
}
}
}
}
if (gotUnresolved)
{
adjMatrix[j].isResolved = 0;
++unresolved;
// cound unresolved dependencies
depCount += gotUnresolved;
}
ksDel (deps);
break;
}
}
if (retVal <= 0) break;
}
if (retVal <= 0)
{
// error or cycle: goto cleanup
goto TopSortCleanup;
}
// resolve all dependencies that can be resolved immediately
for (int j = 0; j < size; ++j)
{
if (adjMatrix[j].isResolved) depCount -= resolveDep (j, adjMatrix, size);
}
ssize_t resolved = ksGetSize (done);
if (((depCount + resolved) >= size) && (unresolved))
{
// more dependencies dependencies than keys:
// cycle found !
retVal = 0;
goto TopSortCleanup;
}
if (unresolved)
{
int found = 1;
// we have unresolved dependencies
for (int j = 0; j < size + 1; ++j)
{
// loop until no dependency can be resolved anymore
if (j == size)
{
if (found)
{
found = 0;
j = -1;
unresolved = 0;
continue;
}
else
break;
}
if (adjMatrix[j].isResolved) continue;
++unresolved;
if (hasOrder)
{
// resolve by order
int ret = resolveDeps (j, adjMatrix, size, done, orderCounter);
if (ret == -1) break;
j = -1;
found = 1;
continue;
}
else
{
// resolve next possible dependency in keyset
if (!hasUnresolvedDependencies (j, adjMatrix, size))
{
adjMatrix[j].isResolved = 1;
resolveDep (j, adjMatrix, size);
keySetMeta (localArray[j], "order", keyBaseName (orderCounter));
elektraArrayIncName (orderCounter);
ksAppendKey (done, keyDup (localArray[j]));
found = 1;
}
}
}
}
if (unresolved == 0)
{
// everything resolved
// add dependencies in topological order to array
elektraKsToMemArray (ks, array);
qsort (array, size, sizeof (Key *), topCmpOrder);
retVal = 1;
}
else
{
// still unresolved dependencies left:
// there must be a cycle somewhere
retVal = 0;
}
TopSortCleanup:
ksDel (done);
keyDel (orderCounter);
elektraFree (localArray);
for (ssize_t j = 0; j < size; ++j)
{
elektraFree (adjMatrix[j].deps);
}
return retVal;
}
