Exemplo n.º 1
0
func (d rdsImpl) fixQuery(fq *ds.FinalizedQuery) (*datastore.Query, error) {
	ret := datastore.NewQuery(fq.Kind())

	start, end := fq.Bounds()
	if start != nil {
		ret = ret.Start(start.(datastore.Cursor))
	}
	if end != nil {
		ret = ret.End(end.(datastore.Cursor))
	}

	for prop, vals := range fq.EqFilters() {
		if prop == "__ancestor__" {
			p, err := dsF2RProp(d.aeCtx, vals[0])
			if err != nil {
				return nil, err
			}
			ret = ret.Ancestor(p.Value.(*datastore.Key))
		} else {
			filt := prop + "="
			for _, v := range vals {
				p, err := dsF2RProp(d.aeCtx, v)
				if err != nil {
					return nil, err
				}

				ret = ret.Filter(filt, p.Value)
			}
		}
	}

	if lnam, lop, lprop := fq.IneqFilterLow(); lnam != "" {
		p, err := dsF2RProp(d.aeCtx, lprop)
		if err != nil {
			return nil, err
		}
		ret = ret.Filter(lnam+" "+lop, p.Value)
	}

	if hnam, hop, hprop := fq.IneqFilterHigh(); hnam != "" {
		p, err := dsF2RProp(d.aeCtx, hprop)
		if err != nil {
			return nil, err
		}
		ret = ret.Filter(hnam+" "+hop, p.Value)
	}

	if fq.EventuallyConsistent() {
		ret = ret.EventualConsistency()
	}

	if fq.KeysOnly() {
		ret = ret.KeysOnly()
	}

	if lim, ok := fq.Limit(); ok {
		ret = ret.Limit(int(lim))
	}

	if off, ok := fq.Offset(); ok {
		ret = ret.Offset(int(off))
	}

	for _, o := range fq.Orders() {
		ret = ret.Order(o.String())
	}

	ret = ret.Project(fq.Project()...)
	if fq.Distinct() {
		ret = ret.Distinct()
	}

	return ret, nil
}
Exemplo n.º 2
0
func reduce(fq *ds.FinalizedQuery, aid, ns string, isTxn bool) (*reducedQuery, error) {
	if err := fq.Valid(aid, ns); err != nil {
		return nil, err
	}
	if isTxn && fq.Ancestor() == nil {
		return nil, fmt.Errorf("queries within a transaction must include an Ancestor filter")
	}
	if num := numComponents(fq); num > MaxQueryComponents {
		return nil, fmt.Errorf(
			"gae/memory: query is too large. may not have more than "+
				"%d filters + sort orders + ancestor total: had %d",
			MaxQueryComponents, num)
	}

	ret := &reducedQuery{
		aid:          aid,
		ns:           ns,
		kind:         fq.Kind(),
		suffixFormat: fq.Orders(),
	}

	eqFilts := fq.EqFilters()
	ret.eqFilters = make(map[string]stringset.Set, len(eqFilts))
	for prop, vals := range eqFilts {
		sVals := stringset.New(len(vals))
		for _, v := range vals {
			sVals.Add(string(serialize.ToBytes(v)))
		}
		ret.eqFilters[prop] = sVals
	}

	startD, endD := GetBinaryBounds(fq)

	// Now we check the start and end cursors.
	//
	// Cursors are composed of a list of IndexColumns at the beginning, followed
	// by the raw bytes to use for the suffix. The cursor is only valid if all of
	// its IndexColumns match our proposed suffixFormat, as calculated above.
	//
	// Cursors are mutually exclusive with the start/end we picked up from the
	// inequality. In a well formed query, they indicate a subset of results
	// bounded by the inequality. Technically if the start cursor is not >= the
	// low bound, or the end cursor is < the high bound, it's an error, but for
	// simplicity we just cap to the narrowest intersection of the inequality and
	// cursors.
	ret.start = startD
	ret.end = endD
	if start, end := fq.Bounds(); start != nil || end != nil {
		if start != nil {
			if c, ok := start.(queryCursor); ok {
				startCols, startD, err := c.decode()
				if err != nil {
					return nil, err
				}

				if !sortOrdersEqual(startCols, ret.suffixFormat) {
					return nil, errors.New("gae/memory: start cursor is invalid for this query")
				}
				if ret.start == nil || bytes.Compare(ret.start, startD) < 0 {
					ret.start = startD
				}
			} else {
				return nil, errors.New("gae/memory: bad cursor type")
			}
		}

		if end != nil {
			if c, ok := end.(queryCursor); ok {
				endCols, endD, err := c.decode()
				if err != nil {
					return nil, err
				}

				if !sortOrdersEqual(endCols, ret.suffixFormat) {
					return nil, errors.New("gae/memory: end cursor is invalid for this query")
				}
				if ret.end == nil || bytes.Compare(endD, ret.end) < 0 {
					ret.end = endD
				}
			} else {
				return nil, errors.New("gae/memory: bad cursor type")
			}
		}
	}

	// Finally, verify that we could even /potentially/ do work. If we have
	// overlapping range ends, then we don't have anything to do.
	if ret.end != nil && bytes.Compare(ret.start, ret.end) >= 0 {
		return nil, ds.ErrNullQuery
	}

	ret.numCols = len(ret.suffixFormat)
	for prop, vals := range ret.eqFilters {
		if len(ret.suffixFormat) == 1 && prop == "__ancestor__" {
			continue
		}
		ret.numCols += vals.Len()
	}

	return ret, nil
}