frostfs-sdk-go/netmap/policy.go
Evgenii Stratonikov a02c0bfac8
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[#186] netmap: Marshal policy with brackets
Brackets can be semantically important and must not be omitted,
otherwise the output is plain wrong.
We do not take the responsibility to preserve every bracket, though,
because parser does some optimizations related to grouping long chains
of filters combined with the same operation.

Signed-off-by: Evgenii Stratonikov <e.stratonikov@yadro.com>
2023-10-27 10:54:45 +03:00

945 lines
24 KiB
Go

package netmap
import (
"errors"
"fmt"
"io"
"strconv"
"strings"
"git.frostfs.info/TrueCloudLab/frostfs-api-go/v2/netmap"
"git.frostfs.info/TrueCloudLab/frostfs-sdk-go/netmap/parser"
"github.com/antlr4-go/antlr/v4"
)
// PlacementPolicy declares policy to store objects in the FrostFS container.
// Within itself, PlacementPolicy represents a set of rules to select a subset
// of nodes from FrostFS network map - node-candidates for object storage.
//
// PlacementPolicy is mutually compatible with git.frostfs.info/TrueCloudLab/frostfs-api-go/v2/netmap.PlacementPolicy
// message. See ReadFromV2 / WriteToV2 methods.
//
// Instances can be created using built-in var declaration.
type PlacementPolicy struct {
backupFactor uint32
filters []netmap.Filter
selectors []netmap.Selector
replicas []netmap.Replica
unique bool
}
func (p *PlacementPolicy) readFromV2(m netmap.PlacementPolicy, checkFieldPresence bool) error {
p.replicas = m.GetReplicas()
if checkFieldPresence && len(p.replicas) == 0 {
return errors.New("missing replicas")
}
p.backupFactor = m.GetContainerBackupFactor()
p.selectors = m.GetSelectors()
p.filters = m.GetFilters()
p.unique = m.GetUnique()
return nil
}
// Marshal encodes PlacementPolicy into a binary format of the FrostFS API
// protocol (Protocol Buffers with direct field order).
//
// See also Unmarshal.
func (p PlacementPolicy) Marshal() []byte {
var m netmap.PlacementPolicy
p.WriteToV2(&m)
return m.StableMarshal(nil)
}
// Unmarshal decodes FrostFS API protocol binary format into the PlacementPolicy
// (Protocol Buffers with direct field order). Returns an error describing
// a format violation.
//
// See also Marshal.
func (p *PlacementPolicy) Unmarshal(data []byte) error {
var m netmap.PlacementPolicy
err := m.Unmarshal(data)
if err != nil {
return err
}
return p.readFromV2(m, false)
}
// MarshalJSON encodes PlacementPolicy into a JSON format of the FrostFS API
// protocol (Protocol Buffers JSON).
//
// See also UnmarshalJSON.
func (p PlacementPolicy) MarshalJSON() ([]byte, error) {
var m netmap.PlacementPolicy
p.WriteToV2(&m)
return m.MarshalJSON()
}
// UnmarshalJSON decodes FrostFS API protocol JSON format into the PlacementPolicy
// (Protocol Buffers JSON). Returns an error describing a format violation.
//
// See also MarshalJSON.
func (p *PlacementPolicy) UnmarshalJSON(data []byte) error {
var m netmap.PlacementPolicy
err := m.UnmarshalJSON(data)
if err != nil {
return err
}
return p.readFromV2(m, false)
}
// ReadFromV2 reads PlacementPolicy from the netmap.PlacementPolicy message.
// Checks if the message conforms to FrostFS API V2 protocol.
//
// See also WriteToV2.
func (p *PlacementPolicy) ReadFromV2(m netmap.PlacementPolicy) error {
return p.readFromV2(m, true)
}
// WriteToV2 writes PlacementPolicy to the session.Token message.
// The message must not be nil.
//
// See also ReadFromV2.
func (p PlacementPolicy) WriteToV2(m *netmap.PlacementPolicy) {
m.SetContainerBackupFactor(p.backupFactor)
m.SetFilters(p.filters)
m.SetSelectors(p.selectors)
m.SetReplicas(p.replicas)
m.SetUnique(p.unique)
}
// ReplicaDescriptor replica descriptor characterizes replicas of objects from
// the subset selected by a particular Selector.
type ReplicaDescriptor struct {
m netmap.Replica
}
// SetNumberOfObjects sets number of object replicas.
func (r *ReplicaDescriptor) SetNumberOfObjects(c uint32) {
r.m.SetCount(c)
}
// NumberOfObjects returns number set using SetNumberOfObjects.
//
// Zero ReplicaDescriptor has zero number of objects.
func (r ReplicaDescriptor) NumberOfObjects() uint32 {
return r.m.GetCount()
}
// SetSelectorName sets name of the related Selector.
//
// Zero ReplicaDescriptor references to the root bucket's selector: it contains
// all possible nodes to store the object.
func (r *ReplicaDescriptor) SetSelectorName(s string) {
r.m.SetSelector(s)
}
// AddReplicas adds a bunch object replica's characteristics.
//
// See also IterateReplicas.
func (p *PlacementPolicy) AddReplicas(rs ...ReplicaDescriptor) {
off := len(p.replicas)
p.replicas = append(p.replicas, make([]netmap.Replica, len(rs))...)
for i := range rs {
p.replicas[off+i] = rs[i].m
}
}
// NumberOfReplicas returns number of replica descriptors set using AddReplicas.
//
// Zero PlacementPolicy has no replicas which is incorrect according to the
// FrostFS API protocol.
func (p PlacementPolicy) NumberOfReplicas() int {
return len(p.replicas)
}
// ReplicaNumberByIndex returns number of object replicas from the i-th replica
// descriptor. Index MUST be in range [0; NumberOfReplicas()).
//
// Zero PlacementPolicy has no replicas.
func (p PlacementPolicy) ReplicaNumberByIndex(i int) uint32 {
return p.replicas[i].GetCount()
}
// SetContainerBackupFactor sets container backup factor: it controls how deep
// FrostFS will search for nodes alternatives to include into container's nodes subset.
//
// Zero PlacementPolicy has zero container backup factor.
func (p *PlacementPolicy) SetContainerBackupFactor(f uint32) {
p.backupFactor = f
}
// SetUnique sets the unique flag: it controls whether the selected replica buckets
// are disjoint or not.
//
// Zero PlacementPolicy has false unique flag.
func (p *PlacementPolicy) SetUnique(b bool) {
p.unique = b
}
// Selector describes the bucket selection operator: choose a number of nodes
// from the bucket taking the nearest nodes to the related container by hash distance.
type Selector struct {
m netmap.Selector
}
// SetName sets name with which the Selector can be referenced.
//
// Zero Selector is unnamed.
func (s *Selector) SetName(name string) {
s.m.SetName(name)
}
// SetNumberOfNodes sets number of nodes to select from the bucket.
//
// Zero Selector selects nothing.
func (s *Selector) SetNumberOfNodes(num uint32) {
s.m.SetCount(num)
}
// SelectByBucketAttribute sets attribute of the bucket to select nodes from.
//
// Zero Selector has empty attribute.
func (s *Selector) SelectByBucketAttribute(bucket string) {
s.m.SetAttribute(bucket)
}
// SelectSame makes selection algorithm to select only nodes having the same values
// of the bucket attribute.
//
// Zero Selector doesn't specify selection modifier so nodes are selected randomly.
//
// See also SelectByBucketAttribute.
func (s *Selector) SelectSame() {
s.m.SetClause(netmap.Same)
}
// SelectDistinct makes selection algorithm to select only nodes having the different values
// of the bucket attribute.
//
// Zero Selector doesn't specify selection modifier so nodes are selected randomly.
//
// See also SelectByBucketAttribute.
func (s *Selector) SelectDistinct() {
s.m.SetClause(netmap.Distinct)
}
// SetFilterName sets reference to pre-filtering nodes for selection.
//
// Zero Selector has no filtering reference.
//
// See also Filter.SetName.
func (s *Selector) SetFilterName(f string) {
s.m.SetFilter(f)
}
// AddSelectors adds a Selector bunch to form the subset of the nodes
// to store container objects.
//
// Zero PlacementPolicy does not declare selectors.
func (p *PlacementPolicy) AddSelectors(ss ...Selector) {
off := len(p.selectors)
p.selectors = append(p.selectors, make([]netmap.Selector, len(ss))...)
for i := range ss {
p.selectors[off+i] = ss[i].m
}
}
// Filter contains rules for filtering the node sets.
type Filter struct {
m netmap.Filter
}
// SetName sets name with which the Filter can be referenced or, for inner filters,
// to which the Filter references. Top-level filters MUST be named. The name
// MUST NOT be '*'.
//
// Zero Filter is unnamed.
func (x *Filter) SetName(name string) {
x.m.SetName(name)
}
func (x *Filter) setAttribute(key string, op netmap.Operation, val string) {
x.m.SetKey(key)
x.m.SetOp(op)
x.m.SetValue(val)
}
// Equal applies the rule to accept only nodes with the same attribute value.
//
// Method SHOULD NOT be called along with other similar methods.
func (x *Filter) Equal(key, value string) {
x.setAttribute(key, netmap.EQ, value)
}
// NotEqual applies the rule to accept only nodes with the distinct attribute value.
//
// Method SHOULD NOT be called along with other similar methods.
func (x *Filter) NotEqual(key, value string) {
x.setAttribute(key, netmap.NE, value)
}
// NumericGT applies the rule to accept only nodes with the numeric attribute
// greater than given number.
//
// Method SHOULD NOT be called along with other similar methods.
func (x *Filter) NumericGT(key string, num int64) {
x.setAttribute(key, netmap.GT, strconv.FormatInt(num, 10))
}
// NumericGE applies the rule to accept only nodes with the numeric attribute
// greater than or equal to given number.
//
// Method SHOULD NOT be called along with other similar methods.
func (x *Filter) NumericGE(key string, num int64) {
x.setAttribute(key, netmap.GE, strconv.FormatInt(num, 10))
}
// NumericLT applies the rule to accept only nodes with the numeric attribute
// less than given number.
//
// Method SHOULD NOT be called along with other similar methods.
func (x *Filter) NumericLT(key string, num int64) {
x.setAttribute(key, netmap.LT, strconv.FormatInt(num, 10))
}
// NumericLE applies the rule to accept only nodes with the numeric attribute
// less than or equal to given number.
//
// Method SHOULD NOT be called along with other similar methods.
func (x *Filter) NumericLE(key string, num int64) {
x.setAttribute(key, netmap.LE, strconv.FormatInt(num, 10))
}
func (x *Filter) setInnerFilters(op netmap.Operation, filters []Filter) {
x.setAttribute("", op, "")
inner := x.m.GetFilters()
if rem := len(filters) - len(inner); rem > 0 {
inner = append(inner, make([]netmap.Filter, rem)...)
}
for i := range filters {
inner[i] = filters[i].m
}
x.m.SetFilters(inner)
}
// LogicalOR applies the rule to accept only nodes which satisfy at least one
// of the given filters.
//
// Method SHOULD NOT be called along with other similar methods.
func (x *Filter) LogicalOR(filters ...Filter) {
x.setInnerFilters(netmap.OR, filters)
}
// LogicalAND applies the rule to accept only nodes which satisfy all the given
// filters.
//
// Method SHOULD NOT be called along with other similar methods.
func (x *Filter) LogicalAND(filters ...Filter) {
x.setInnerFilters(netmap.AND, filters)
}
// AddFilters adds a Filter bunch that will be applied when selecting nodes.
//
// Zero PlacementPolicy has no filters.
func (p *PlacementPolicy) AddFilters(fs ...Filter) {
off := len(p.filters)
p.filters = append(p.filters, make([]netmap.Filter, len(fs))...)
for i := range fs {
p.filters[off+i] = fs[i].m
}
}
// WriteStringTo encodes PlacementPolicy into human-readably query and writes
// the result into w. Returns w's errors directly.
//
// See also DecodeString.
// nolint: funlen
func (p PlacementPolicy) WriteStringTo(w io.StringWriter) (err error) {
if p.unique {
if _, err := w.WriteString("UNIQUE\n"); err != nil {
return err
}
}
delim := ""
for i := range p.replicas {
c := p.replicas[i].GetCount()
s := p.replicas[i].GetSelector()
if s != "" {
_, err = w.WriteString(fmt.Sprintf("%sREP %d IN %s", delim, c, s))
} else {
_, err = w.WriteString(fmt.Sprintf("%sREP %d", delim, c))
}
if err != nil {
return err
}
delim = "\n"
}
if p.backupFactor > 0 {
_, err = w.WriteString(fmt.Sprintf("\nCBF %d", p.backupFactor))
if err != nil {
return err
}
}
var s string
for i := range p.selectors {
_, err = w.WriteString(fmt.Sprintf("\nSELECT %d", p.selectors[i].GetCount()))
if err != nil {
return err
}
if s = p.selectors[i].GetAttribute(); s != "" {
var clause string
switch p.selectors[i].GetClause() {
case netmap.Same:
clause = "SAME "
case netmap.Distinct:
clause = "DISTINCT "
default:
clause = ""
}
_, err = w.WriteString(fmt.Sprintf(" IN %s%s", clause, s))
if err != nil {
return err
}
}
if s = p.selectors[i].GetFilter(); s != "" {
_, err = w.WriteString(" FROM " + s)
if err != nil {
return err
}
}
if s = p.selectors[i].GetName(); s != "" {
_, err = w.WriteString(" AS " + s)
if err != nil {
return err
}
}
}
for i := range p.filters {
_, err = w.WriteString("\nFILTER ")
if err != nil {
return err
}
err = writeFilterStringTo(w, p.filters[i], false)
if err != nil {
return err
}
}
return nil
}
func writeFilterStringTo(w io.StringWriter, f netmap.Filter, mayNeedOuterBrackets bool) error {
var err error
var s string
op := f.GetOp()
unspecified := op == 0
if s = f.GetKey(); s != "" {
_, err = w.WriteString(fmt.Sprintf("%s %s %s", escapeString(s), op, escapeString(f.GetValue())))
if err != nil {
return err
}
} else if s = f.GetName(); unspecified && s != "" {
_, err = w.WriteString(fmt.Sprintf("@%s", s))
if err != nil {
return err
}
}
inner := f.GetFilters()
if op == netmap.NOT {
_, err = w.WriteString(op.String() + " (")
if err != nil {
return err
}
err = writeFilterStringTo(w, inner[0], false)
if err != nil {
return err
}
_, err = w.WriteString(")")
if err != nil {
return err
}
} else {
useBrackets := mayNeedOuterBrackets && op == netmap.OR && len(inner) > 1
if useBrackets {
_, err = w.WriteString("(")
if err != nil {
return err
}
}
for i := range inner {
if i != 0 {
_, err = w.WriteString(" " + op.String() + " ")
if err != nil {
return err
}
}
err = writeFilterStringTo(w, inner[i], true)
if err != nil {
return err
}
}
if useBrackets {
_, err = w.WriteString(")")
if err != nil {
return err
}
}
}
if s = f.GetName(); s != "" && !unspecified {
_, err = w.WriteString(" AS " + s)
if err != nil {
return err
}
}
return nil
}
// DecodeString decodes PlacementPolicy from the string composed using
// WriteStringTo. Returns error if s is malformed.
func (p *PlacementPolicy) DecodeString(s string) error {
var v policyVisitor
input := antlr.NewInputStream(s)
lexer := parser.NewQueryLexer(input)
lexer.RemoveErrorListeners()
lexer.AddErrorListener(&v)
stream := antlr.NewCommonTokenStream(lexer, 0)
pp := parser.NewQuery(stream)
pp.BuildParseTrees = true
pp.RemoveErrorListeners()
pp.AddErrorListener(&v)
pl := pp.Policy().Accept(&v)
if len(v.errors) != 0 {
return v.errors[0]
}
parsed, ok := pl.(*PlacementPolicy)
if !ok {
return fmt.Errorf("unexpected parsed instance type %T", pl)
} else if parsed == nil {
return errors.New("parsed nil value")
}
if err := validatePolicy(*parsed); err != nil {
return fmt.Errorf("invalid policy: %w", err)
}
*p = *parsed
return nil
}
// SelectFilterExpr is an expression containing only selectors and filters.
// It's useful to evaluate their effect before being used in a policy.
type SelectFilterExpr struct {
cbf uint32
selector *netmap.Selector
filters []netmap.Filter
}
// DecodeString decodes a string into a SelectFilterExpr.
// Returns an error if s is malformed.
func DecodeSelectFilterString(s string) (*SelectFilterExpr, error) {
var v policyVisitor
input := antlr.NewInputStream(s)
lexer := parser.NewQueryLexer(input)
lexer.RemoveErrorListeners()
lexer.AddErrorListener(&v)
stream := antlr.NewCommonTokenStream(lexer, 0)
pp := parser.NewQuery(stream)
pp.BuildParseTrees = true
pp.RemoveErrorListeners()
pp.AddErrorListener(&v)
sfExpr := pp.SelectFilterExpr().Accept(&v)
if len(v.errors) != 0 {
return nil, v.errors[0]
}
parsed, ok := sfExpr.(*SelectFilterExpr)
if !ok {
return nil, fmt.Errorf("unexpected parsed instance type %T", sfExpr)
}
return parsed, nil
}
var (
// errUnknownFilter is returned when a value of FROM in a query is unknown.
errUnknownFilter = errors.New("filter not found")
// errUnknownSelector is returned when a value of IN is unknown.
errUnknownSelector = errors.New("policy: selector not found")
// errSyntaxError is returned for errors found by ANTLR parser.
errSyntaxError = errors.New("policy: syntax error")
// errRedundantSelector is returned for errors found by selectors policy validator.
errRedundantSelector = errors.New("policy: found redundant selector")
// errUnnamedSelector is returned for errors found by selectors policy validator.
errUnnamedSelector = errors.New("policy: unnamed selectors are useless, " +
"make sure to pair REP and SELECT clauses: \"REP .. IN X\" + \"SELECT ... AS X\"")
// errRedundantSelector is returned for errors found by filters policy validator.
errRedundantFilter = errors.New("policy: found redundant filter")
)
type policyVisitor struct {
errors []error
parser.BaseQueryVisitor
antlr.DefaultErrorListener
}
func (p *policyVisitor) SyntaxError(_ antlr.Recognizer, _ any, line, column int, msg string, _ antlr.RecognitionException) {
p.reportError(fmt.Errorf("%w: line %d:%d %s", errSyntaxError, line, column, msg))
}
func (p *policyVisitor) reportError(err error) any {
p.errors = append(p.errors, err)
return nil
}
// VisitPolicy implements parser.QueryVisitor interface.
func (p *policyVisitor) VisitPolicy(ctx *parser.PolicyContext) any {
if len(p.errors) != 0 {
return nil
}
pl := new(PlacementPolicy)
pl.unique = ctx.UNIQUE() != nil
repStmts := ctx.AllRepStmt()
pl.replicas = make([]netmap.Replica, 0, len(repStmts))
for _, r := range repStmts {
res, ok := r.Accept(p).(*netmap.Replica)
if !ok {
return nil
}
pl.replicas = append(pl.replicas, *res)
}
if cbfStmt := ctx.CbfStmt(); cbfStmt != nil {
cbf, ok := cbfStmt.(*parser.CbfStmtContext).Accept(p).(uint32)
if !ok {
return nil
}
pl.SetContainerBackupFactor(cbf)
}
selStmts := ctx.AllSelectStmt()
pl.selectors = make([]netmap.Selector, 0, len(selStmts))
for _, s := range selStmts {
res, ok := s.Accept(p).(*netmap.Selector)
if !ok {
return nil
}
pl.selectors = append(pl.selectors, *res)
}
filtStmts := ctx.AllFilterStmt()
pl.filters = make([]netmap.Filter, 0, len(filtStmts))
for _, f := range filtStmts {
pl.filters = append(pl.filters, *f.Accept(p).(*netmap.Filter))
}
return pl
}
func (p *policyVisitor) VisitSelectFilterExpr(ctx *parser.SelectFilterExprContext) any {
if len(p.errors) != 0 {
return nil
}
sfExpr := new(SelectFilterExpr)
if cbfStmt := ctx.CbfStmt(); cbfStmt != nil {
cbf, ok := cbfStmt.(*parser.CbfStmtContext).Accept(p).(uint32)
if !ok {
return nil
}
sfExpr.cbf = cbf
}
if selStmt := ctx.SelectStmt(); selStmt != nil {
sel, ok := selStmt.Accept(p).(*netmap.Selector)
if !ok {
return nil
}
sfExpr.selector = sel
}
filtStmts := ctx.AllFilterStmt()
sfExpr.filters = make([]netmap.Filter, 0, len(filtStmts))
for _, f := range filtStmts {
sfExpr.filters = append(sfExpr.filters, *f.Accept(p).(*netmap.Filter))
}
return sfExpr
}
func (p *policyVisitor) VisitCbfStmt(ctx *parser.CbfStmtContext) any {
cbf, err := strconv.ParseUint(ctx.GetBackupFactor().GetText(), 10, 32)
if err != nil {
return p.reportError(errInvalidNumber)
}
return uint32(cbf)
}
// VisitRepStmt implements parser.QueryVisitor interface.
func (p *policyVisitor) VisitRepStmt(ctx *parser.RepStmtContext) any {
num, err := strconv.ParseUint(ctx.GetCount().GetText(), 10, 32)
if err != nil {
return p.reportError(errInvalidNumber)
}
rs := new(netmap.Replica)
rs.SetCount(uint32(num))
if sel := ctx.GetSelector(); sel != nil {
rs.SetSelector(sel.GetText())
}
return rs
}
// VisitSelectStmt implements parser.QueryVisitor interface.
func (p *policyVisitor) VisitSelectStmt(ctx *parser.SelectStmtContext) any {
res, err := strconv.ParseUint(ctx.GetCount().GetText(), 10, 32)
if err != nil {
return p.reportError(errInvalidNumber)
}
s := new(netmap.Selector)
s.SetCount(uint32(res))
if clStmt := ctx.Clause(); clStmt != nil {
s.SetClause(clauseFromString(clStmt.GetText()))
}
if bStmt := ctx.GetBucket(); bStmt != nil {
s.SetAttribute(ctx.GetBucket().GetText())
}
s.SetFilter(ctx.GetFilter().GetText()) // either ident or wildcard
if ctx.AS() != nil {
s.SetName(ctx.GetName().GetText())
}
return s
}
// VisitFilterStmt implements parser.QueryVisitor interface.
func (p *policyVisitor) VisitFilterStmt(ctx *parser.FilterStmtContext) any {
f := p.VisitFilterExpr(ctx.GetExpr().(*parser.FilterExprContext)).(*netmap.Filter)
f.SetName(ctx.GetName().GetText())
return f
}
func (p *policyVisitor) VisitFilterExpr(ctx *parser.FilterExprContext) any {
if eCtx := ctx.Expr(); eCtx != nil {
return eCtx.Accept(p)
}
if inner := ctx.GetInner(); inner != nil {
return inner.Accept(p)
}
f := new(netmap.Filter)
op := operationFromString(ctx.GetOp().GetText())
f.SetOp(op)
if op == netmap.NOT {
f1 := *ctx.GetF1().Accept(p).(*netmap.Filter)
f.SetFilters([]netmap.Filter{f1})
return f
}
f1 := *ctx.GetF1().Accept(p).(*netmap.Filter)
f2 := *ctx.GetF2().Accept(p).(*netmap.Filter)
// Consider f1=(.. AND ..) AND f2. This can be merged because our AND operation
// is of arbitrary arity. ANTLR generates left-associative parse-tree by default.
if f1.GetOp() == op {
f.SetFilters(append(f1.GetFilters(), f2))
return f
}
f.SetFilters([]netmap.Filter{f1, f2})
return f
}
// VisitFilterKey implements parser.QueryVisitor interface.
func (p *policyVisitor) VisitFilterKey(ctx *parser.FilterKeyContext) any {
if id := ctx.Ident(); id != nil {
return id.GetText()
}
str := ctx.STRING().GetText()
return str[1 : len(str)-1]
}
func (p *policyVisitor) VisitFilterValue(ctx *parser.FilterValueContext) any {
if id := ctx.Ident(); id != nil {
return id.GetText()
}
if num := ctx.Number(); num != nil {
return num.GetText()
}
str := ctx.STRING().GetText()
return str[1 : len(str)-1]
}
// VisitExpr implements parser.QueryVisitor interface.
func (p *policyVisitor) VisitExpr(ctx *parser.ExprContext) any {
f := new(netmap.Filter)
if flt := ctx.GetFilter(); flt != nil {
f.SetName(flt.GetText())
return f
}
key := ctx.GetKey().Accept(p)
opStr := ctx.SIMPLE_OP().GetText()
value := ctx.GetValue().Accept(p)
f.SetKey(key.(string))
f.SetOp(operationFromString(opStr))
f.SetValue(value.(string))
return f
}
// validatePolicy checks high-level constraints such as filter link in SELECT
// being actually defined in FILTER section.
func validatePolicy(p PlacementPolicy) error {
canOmitNames := len(p.selectors) == 1 && len(p.replicas) == 1
seenFilters := map[string]bool{}
expectedFilters := map[string]struct{}{}
for i := range p.filters {
seenFilters[p.filters[i].GetName()] = true
for _, f := range p.filters[i].GetFilters() {
if f.GetName() != "" {
expectedFilters[f.GetName()] = struct{}{}
}
}
}
seenSelectors := map[string]*netmap.Selector{}
for i := range p.selectors {
if p.selectors[i].GetName() == "" && !canOmitNames {
return errUnnamedSelector
}
if flt := p.selectors[i].GetFilter(); flt != mainFilterName {
expectedFilters[flt] = struct{}{}
if !seenFilters[flt] {
return fmt.Errorf("%w: '%s'", errUnknownFilter, flt)
}
}
seenSelectors[p.selectors[i].GetName()] = &p.selectors[i]
}
for _, f := range p.filters {
if _, ok := expectedFilters[f.GetName()]; !ok {
return fmt.Errorf("%w: '%s'", errRedundantFilter, f.GetName())
}
}
expectedSelectors := map[string]struct{}{}
for i := range p.replicas {
selName := p.replicas[i].GetSelector()
if selName != "" || canOmitNames {
expectedSelectors[selName] = struct{}{}
if seenSelectors[selName] == nil {
return fmt.Errorf("%w: '%s'", errUnknownSelector, selName)
}
}
}
for _, s := range p.selectors {
if _, ok := expectedSelectors[s.GetName()]; !ok {
return fmt.Errorf("%w: to use selector '%s' use keyword IN", errRedundantSelector, s.GetName())
}
}
return nil
}
func clauseFromString(s string) (c netmap.Clause) {
if !c.FromString(strings.ToUpper(s)) {
// Such errors should be handled by ANTLR code thus this panic.
panic(fmt.Errorf("BUG: invalid clause: %s", c))
}
return
}
func operationFromString(s string) (op netmap.Operation) {
if !op.FromString(strings.ToUpper(s)) {
// Such errors should be handled by ANTLR code thus this panic.
panic(fmt.Errorf("BUG: invalid operation: %s", op))
}
return
}
// escapeString returns single quote wrapped string if it contains special
// characters '-' and whitespace.
func escapeString(s string) string {
if strings.ContainsAny(s, " -\t") {
return "'" + s + "'"
}
return s
}