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/*
Copyright 2015 Google LLC
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*/
package bigtable
import (
"fmt"
"strings"
"time"
btpb "google.golang.org/genproto/googleapis/bigtable/v2"
)
// A Filter represents a row filter.
type Filter interface {
String() string
proto() *btpb.RowFilter
}
// ChainFilters returns a filter that applies a sequence of filters.
func ChainFilters(sub ...Filter) Filter { return chainFilter{sub} }
type chainFilter struct {
sub []Filter
}
func (cf chainFilter) String() string {
var ss []string
for _, sf := range cf.sub {
ss = append(ss, sf.String())
}
return "(" + strings.Join(ss, " | ") + ")"
}
func (cf chainFilter) proto() *btpb.RowFilter {
chain := &btpb.RowFilter_Chain{}
for _, sf := range cf.sub {
chain.Filters = append(chain.Filters, sf.proto())
}
return &btpb.RowFilter{
Filter: &btpb.RowFilter_Chain_{Chain: chain},
}
}
// InterleaveFilters returns a filter that applies a set of filters in parallel
// and interleaves the results.
func InterleaveFilters(sub ...Filter) Filter { return interleaveFilter{sub} }
type interleaveFilter struct {
sub []Filter
}
func (ilf interleaveFilter) String() string {
var ss []string
for _, sf := range ilf.sub {
ss = append(ss, sf.String())
}
return "(" + strings.Join(ss, " + ") + ")"
}
func (ilf interleaveFilter) proto() *btpb.RowFilter {
inter := &btpb.RowFilter_Interleave{}
for _, sf := range ilf.sub {
inter.Filters = append(inter.Filters, sf.proto())
}
return &btpb.RowFilter{
Filter: &btpb.RowFilter_Interleave_{Interleave: inter},
}
}
// RowKeyFilter returns a filter that matches cells from rows whose
// key matches the provided RE2 pattern.
// See https://github.com/google/re2/wiki/Syntax for the accepted syntax.
func RowKeyFilter(pattern string) Filter { return rowKeyFilter(pattern) }
type rowKeyFilter string
func (rkf rowKeyFilter) String() string { return fmt.Sprintf("row(%s)", string(rkf)) }
func (rkf rowKeyFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{Filter: &btpb.RowFilter_RowKeyRegexFilter{RowKeyRegexFilter: []byte(rkf)}}
}
// FamilyFilter returns a filter that matches cells whose family name
// matches the provided RE2 pattern.
// See https://github.com/google/re2/wiki/Syntax for the accepted syntax.
func FamilyFilter(pattern string) Filter { return familyFilter(pattern) }
type familyFilter string
func (ff familyFilter) String() string { return fmt.Sprintf("col(%s:)", string(ff)) }
func (ff familyFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{Filter: &btpb.RowFilter_FamilyNameRegexFilter{FamilyNameRegexFilter: string(ff)}}
}
// ColumnFilter returns a filter that matches cells whose column name
// matches the provided RE2 pattern.
// See https://github.com/google/re2/wiki/Syntax for the accepted syntax.
func ColumnFilter(pattern string) Filter { return columnFilter(pattern) }
type columnFilter string
func (cf columnFilter) String() string { return fmt.Sprintf("col(.*:%s)", string(cf)) }
func (cf columnFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{Filter: &btpb.RowFilter_ColumnQualifierRegexFilter{ColumnQualifierRegexFilter: []byte(cf)}}
}
// ValueFilter returns a filter that matches cells whose value
// matches the provided RE2 pattern.
// See https://github.com/google/re2/wiki/Syntax for the accepted syntax.
func ValueFilter(pattern string) Filter { return valueFilter(pattern) }
type valueFilter string
func (vf valueFilter) String() string { return fmt.Sprintf("value_match(%s)", string(vf)) }
func (vf valueFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{Filter: &btpb.RowFilter_ValueRegexFilter{ValueRegexFilter: []byte(vf)}}
}
// LatestNFilter returns a filter that matches the most recent N cells in each column.
func LatestNFilter(n int) Filter { return latestNFilter(n) }
type latestNFilter int32
func (lnf latestNFilter) String() string { return fmt.Sprintf("col(*,%d)", lnf) }
func (lnf latestNFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{Filter: &btpb.RowFilter_CellsPerColumnLimitFilter{CellsPerColumnLimitFilter: int32(lnf)}}
}
// LabelFilter returns a filter that applies the
// given label to all cells in the output row.
func LabelFilter(label string) Filter { return labelFilter(label) }
type labelFilter string
func (lf labelFilter) String() string { return fmt.Sprintf("apply_label(%s)", string(lf)) }
func (lf labelFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{Filter: &btpb.RowFilter_ApplyLabelTransformer{ApplyLabelTransformer: string(lf)}}
}
// StripValueFilter returns a filter that replaces each value with the empty string.
func StripValueFilter() Filter { return stripValueFilter{} }
type stripValueFilter struct{}
func (stripValueFilter) String() string { return "strip_value()" }
func (stripValueFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{Filter: &btpb.RowFilter_StripValueTransformer{StripValueTransformer: true}}
}
// TimestampRangeFilter returns a filter that matches any cells whose timestamp is within the given time bounds. A zero
// time means no bound.
// The timestamp will be truncated to millisecond granularity.
func TimestampRangeFilter(startTime time.Time, endTime time.Time) Filter {
trf := timestampRangeFilter{}
if !startTime.IsZero() {
trf.startTime = Time(startTime)
}
if !endTime.IsZero() {
trf.endTime = Time(endTime)
}
return trf
}
// TimestampRangeFilterMicros returns a filter that matches any cells whose timestamp is within the given time bounds,
// specified in units of microseconds since 1 January 1970. A zero value for the end time is interpreted as no bound.
// The timestamp will be truncated to millisecond granularity.
func TimestampRangeFilterMicros(startTime Timestamp, endTime Timestamp) Filter {
return timestampRangeFilter{startTime, endTime}
}
type timestampRangeFilter struct {
startTime Timestamp
endTime Timestamp
}
func (trf timestampRangeFilter) String() string {
return fmt.Sprintf("timestamp_range(%v,%v)", trf.startTime, trf.endTime)
}
func (trf timestampRangeFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{
Filter: &btpb.RowFilter_TimestampRangeFilter{TimestampRangeFilter: &btpb.TimestampRange{
StartTimestampMicros: int64(trf.startTime.TruncateToMilliseconds()),
EndTimestampMicros: int64(trf.endTime.TruncateToMilliseconds()),
},
}}
}
// ColumnRangeFilter returns a filter that matches a contiguous range of columns within a single
// family, as specified by an inclusive start qualifier and exclusive end qualifier.
func ColumnRangeFilter(family, start, end string) Filter {
return columnRangeFilter{family, start, end}
}
type columnRangeFilter struct {
family string
start string
end string
}
func (crf columnRangeFilter) String() string {
return fmt.Sprintf("columnRangeFilter(%s,%s,%s)", crf.family, crf.start, crf.end)
}
func (crf columnRangeFilter) proto() *btpb.RowFilter {
r := &btpb.ColumnRange{FamilyName: crf.family}
if crf.start != "" {
r.StartQualifier = &btpb.ColumnRange_StartQualifierClosed{StartQualifierClosed: []byte(crf.start)}
}
if crf.end != "" {
r.EndQualifier = &btpb.ColumnRange_EndQualifierOpen{EndQualifierOpen: []byte(crf.end)}
}
return &btpb.RowFilter{Filter: &btpb.RowFilter_ColumnRangeFilter{ColumnRangeFilter: r}}
}
// ValueRangeFilter returns a filter that matches cells with values that fall within
// the given range, as specified by an inclusive start value and exclusive end value.
func ValueRangeFilter(start, end []byte) Filter {
return valueRangeFilter{start, end}
}
type valueRangeFilter struct {
start []byte
end []byte
}
func (vrf valueRangeFilter) String() string {
return fmt.Sprintf("valueRangeFilter(%s,%s)", vrf.start, vrf.end)
}
func (vrf valueRangeFilter) proto() *btpb.RowFilter {
r := &btpb.ValueRange{}
if vrf.start != nil {
r.StartValue = &btpb.ValueRange_StartValueClosed{StartValueClosed: vrf.start}
}
if vrf.end != nil {
r.EndValue = &btpb.ValueRange_EndValueOpen{EndValueOpen: vrf.end}
}
return &btpb.RowFilter{Filter: &btpb.RowFilter_ValueRangeFilter{ValueRangeFilter: r}}
}
// ConditionFilter returns a filter that evaluates to one of two possible filters depending
// on whether or not the given predicate filter matches at least one cell.
// If the matched filter is nil then no results will be returned.
// IMPORTANT NOTE: The predicate filter does not execute atomically with the
// true and false filters, which may lead to inconsistent or unexpected
// results. Additionally, condition filters have poor performance, especially
// when filters are set for the false condition.
func ConditionFilter(predicateFilter, trueFilter, falseFilter Filter) Filter {
return conditionFilter{predicateFilter, trueFilter, falseFilter}
}
type conditionFilter struct {
predicateFilter Filter
trueFilter Filter
falseFilter Filter
}
func (cf conditionFilter) String() string {
return fmt.Sprintf("conditionFilter(%s,%s,%s)", cf.predicateFilter, cf.trueFilter, cf.falseFilter)
}
func (cf conditionFilter) proto() *btpb.RowFilter {
var tf *btpb.RowFilter
var ff *btpb.RowFilter
if cf.trueFilter != nil {
tf = cf.trueFilter.proto()
}
if cf.falseFilter != nil {
ff = cf.falseFilter.proto()
}
return &btpb.RowFilter{
Filter: &btpb.RowFilter_Condition_{Condition: &btpb.RowFilter_Condition{
PredicateFilter: cf.predicateFilter.proto(),
TrueFilter: tf,
FalseFilter: ff,
}}}
}
// CellsPerRowOffsetFilter returns a filter that skips the first N cells of each row, matching all subsequent cells.
func CellsPerRowOffsetFilter(n int) Filter {
return cellsPerRowOffsetFilter(n)
}
type cellsPerRowOffsetFilter int32
func (cof cellsPerRowOffsetFilter) String() string {
return fmt.Sprintf("cells_per_row_offset(%d)", cof)
}
func (cof cellsPerRowOffsetFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{Filter: &btpb.RowFilter_CellsPerRowOffsetFilter{CellsPerRowOffsetFilter: int32(cof)}}
}
// CellsPerRowLimitFilter returns a filter that matches only the first N cells of each row.
func CellsPerRowLimitFilter(n int) Filter {
return cellsPerRowLimitFilter(n)
}
type cellsPerRowLimitFilter int32
func (clf cellsPerRowLimitFilter) String() string {
return fmt.Sprintf("cells_per_row_limit(%d)", clf)
}
func (clf cellsPerRowLimitFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{Filter: &btpb.RowFilter_CellsPerRowLimitFilter{CellsPerRowLimitFilter: int32(clf)}}
}
// RowSampleFilter returns a filter that matches a row with a probability of p (must be in the interval (0, 1)).
func RowSampleFilter(p float64) Filter {
return rowSampleFilter(p)
}
type rowSampleFilter float64
func (rsf rowSampleFilter) String() string {
return fmt.Sprintf("filter(%f)", rsf)
}
func (rsf rowSampleFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{Filter: &btpb.RowFilter_RowSampleFilter{RowSampleFilter: float64(rsf)}}
}
// PassAllFilter returns a filter that matches everything.
func PassAllFilter() Filter { return passAllFilter{} }
type passAllFilter struct{}
func (paf passAllFilter) String() string { return "passAllFilter()" }
func (paf passAllFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{Filter: &btpb.RowFilter_PassAllFilter{PassAllFilter: true}}
}
// BlockAllFilter returns a filter that matches nothing.
func BlockAllFilter() Filter { return blockAllFilter{} }
type blockAllFilter struct{}
func (baf blockAllFilter) String() string { return "blockAllFilter()" }
func (baf blockAllFilter) proto() *btpb.RowFilter {
return &btpb.RowFilter{Filter: &btpb.RowFilter_BlockAllFilter{BlockAllFilter: true}}
}