/// <summary>
/// Internal helper method used by check that iterates over
/// <paramref name="valMismatchKeys"/> and generates a <see cref="ICollection{T}"/> of <see cref="Insanity"/>
/// instances accordingly. The <see cref="MapOfSets{TKey, TValue}"/> are used to populate
/// the <see cref="Insanity"/> objects. </summary>
/// <seealso cref="InsanityType.VALUEMISMATCH"/>
private ICollection <Insanity> CheckValueMismatch(MapOfSets <int, FieldCache.CacheEntry> valIdToItems, MapOfSets <ReaderField, int> readerFieldToValIds, ISet <ReaderField> valMismatchKeys)
{
List <Insanity> insanity = new List <Insanity>(valMismatchKeys.Count * 3);
if (valMismatchKeys.Count != 0)
{
// we have multiple values for some ReaderFields
IDictionary <ReaderField, ISet <int> > rfMap = readerFieldToValIds.Map;
IDictionary <int, ISet <FieldCache.CacheEntry> > valMap = valIdToItems.Map;
foreach (ReaderField rf in valMismatchKeys)
{
IList <FieldCache.CacheEntry> badEntries = new List <FieldCache.CacheEntry>(valMismatchKeys.Count * 2);
foreach (int value in rfMap[rf])
{
foreach (FieldCache.CacheEntry cacheEntry in valMap[value])
{
badEntries.Add(cacheEntry);
}
}
FieldCache.CacheEntry[] badness = new FieldCache.CacheEntry[badEntries.Count];
badEntries.CopyTo(badness, 0);
insanity.Add(new Insanity(InsanityType.VALUEMISMATCH, "Multiple distinct value objects for " + rf.ToString(), badness));
}
}
return(insanity);
}
/// <summary>
/// Internal helper method used by check that iterates over
/// the keys of <paramref name="readerFieldToValIds"/> and generates a <see cref="ICollection{T}"/>
/// of <see cref="Insanity"/> instances whenever two (or more) <see cref="ReaderField"/> instances are
/// found that have an ancestry relationships.
/// </summary>
/// <seealso cref="InsanityType.SUBREADER"/>
private ICollection <Insanity> CheckSubreaders(MapOfSets <int, FieldCache.CacheEntry> valIdToItems, MapOfSets <ReaderField, int> readerFieldToValIds)
{
List <Insanity> insanity = new List <Insanity>(23);
Dictionary <ReaderField, ISet <ReaderField> > badChildren = new Dictionary <ReaderField, ISet <ReaderField> >(17);
MapOfSets <ReaderField, ReaderField> badKids = new MapOfSets <ReaderField, ReaderField>(badChildren); // wrapper
IDictionary <int, ISet <FieldCache.CacheEntry> > viToItemSets = valIdToItems.Map;
IDictionary <ReaderField, ISet <int> > rfToValIdSets = readerFieldToValIds.Map;
HashSet <ReaderField> seen = new HashSet <ReaderField>();
//IDictionary<ReaderField, ISet<int>>.KeyCollection readerFields = rfToValIdSets.Keys;
foreach (ReaderField rf in rfToValIdSets.Keys)
{
if (seen.Contains(rf))
{
continue;
}
IList <object> kids = GetAllDescendantReaderKeys(rf.ReaderKey);
foreach (object kidKey in kids)
{
ReaderField kid = new ReaderField(kidKey, rf.FieldName);
// LUCENENET: Eliminated extra lookup by using TryGetValue instead of ContainsKey
if (badChildren.TryGetValue(kid, out ISet <ReaderField> badKid))
{
// we've already process this kid as RF and found other problems
// track those problems as our own
badKids.Put(rf, kid);
badKids.PutAll(rf, badKid);
badChildren.Remove(kid);
}
else if (rfToValIdSets.ContainsKey(kid))
{
// we have cache entries for the kid
badKids.Put(rf, kid);
}
seen.Add(kid);
}
seen.Add(rf);
}
// every mapping in badKids represents an Insanity
foreach (ReaderField parent in badChildren.Keys)
{
ISet <ReaderField> kids = badChildren[parent];
List <FieldCache.CacheEntry> badEntries = new List <FieldCache.CacheEntry>(kids.Count * 2);
// put parent entr(ies) in first
{
foreach (int value in rfToValIdSets[parent])
{
badEntries.AddRange(viToItemSets[value]);
}
}
// now the entries for the descendants
foreach (ReaderField kid in kids)
{
foreach (int value in rfToValIdSets[kid])
{
badEntries.AddRange(viToItemSets[value]);
}
}
FieldCache.CacheEntry[] badness = badEntries.ToArray();
insanity.Add(new Insanity(InsanityType.SUBREADER, "Found caches for descendants of " + parent.ToString(), badness));
}
return(insanity);
}
/// <summary>
/// Tests a CacheEntry[] for indication of "insane" cache usage.
/// <para>
/// <b>NOTE:</b>FieldCache CreationPlaceholder objects are ignored.
/// (:TODO: is this a bad idea? are we masking a real problem?)
/// </para>
/// </summary>
public Insanity[] Check(params FieldCache.CacheEntry[] cacheEntries)
{
if (null == cacheEntries || 0 == cacheEntries.Length)
{
return(new Insanity[0]);
}
if (estimateRam)
{
for (int i = 0; i < cacheEntries.Length; i++)
{
cacheEntries[i].EstimateSize();
}
}
// the indirect mapping lets MapOfSet dedup identical valIds for us
// maps the (valId) identityhashCode of cache values to
// sets of CacheEntry instances
MapOfSets <int, FieldCache.CacheEntry> valIdToItems = new MapOfSets <int, FieldCache.CacheEntry>(new Dictionary <int, ISet <FieldCache.CacheEntry> >(17));
// maps ReaderField keys to Sets of ValueIds
MapOfSets <ReaderField, int> readerFieldToValIds = new MapOfSets <ReaderField, int>(new Dictionary <ReaderField, ISet <int> >(17));
// any keys that we know result in more then one valId
ISet <ReaderField> valMismatchKeys = new HashSet <ReaderField>();
// iterate over all the cacheEntries to get the mappings we'll need
for (int i = 0; i < cacheEntries.Length; i++)
{
FieldCache.CacheEntry item = cacheEntries[i];
object val = item.Value;
// It's OK to have dup entries, where one is eg
// float[] and the other is the Bits (from
// getDocWithField())
if (val is IBits)
{
continue;
}
if (val is Lucene.Net.Search.FieldCache.CreationPlaceholder)
{
continue;
}
ReaderField rf = new ReaderField(item.ReaderKey, item.FieldName);
int valId = RuntimeHelpers.GetHashCode(val);
// indirect mapping, so the MapOfSet will dedup identical valIds for us
valIdToItems.Put(valId, item);
if (1 < readerFieldToValIds.Put(rf, valId))
{
valMismatchKeys.Add(rf);
}
}
List <Insanity> insanity = new List <Insanity>(valMismatchKeys.Count * 3);
insanity.AddRange(CheckValueMismatch(valIdToItems, readerFieldToValIds, valMismatchKeys));
insanity.AddRange(CheckSubreaders(valIdToItems, readerFieldToValIds));
return(insanity.ToArray());
}
