zolfa
/
tendermint


								// Package query implements the custom query format used to filter event

								// subscriptions in Tendermint.

								//

								// Query expressions describe properties of events and their attributes, using

								// strings like:

								//

								//    abci.invoice.number = 22 AND abci.invoice.owner = 'Ivan'

								//

								// Query expressions can handle attribute values encoding numbers, strings,

								// dates, and timestamps.  The complete query grammar is described in the

								// query/syntax package.

								//

								package query


								import (

									"fmt"

									"regexp"

									"strconv"

									"strings"

									"time"


									"github.com/tendermint/tendermint/abci/types"

									"github.com/tendermint/tendermint/libs/pubsub/query/syntax"

								)


								// All is a query that matches all events.

								var All *Query


								// A Query is the compiled form of a query.

								type Query struct {

									ast   syntax.Query

									conds []condition

								}


								// New parses and compiles the query expression into an executable query.

								func New(query string) (*Query, error) {

									ast, err := syntax.Parse(query)

									if err != nil {

										return nil, err

									}

									return Compile(ast)

								}


								// MustCompile compiles the query expression into an executable query.

								// In case of error, MustCompile will panic.

								//

								// This is intended for use in program initialization; use query.New if you

								// need to check errors.

								func MustCompile(query string) *Query {

									q, err := New(query)

									if err != nil {

										panic(err)

									}

									return q

								}


								// Compile compiles the given query AST so it can be used to match events.

								func Compile(ast syntax.Query) (*Query, error) {

									conds := make([]condition, len(ast))

									for i, q := range ast {

										cond, err := compileCondition(q)

										if err != nil {

											return nil, fmt.Errorf("compile %s: %w", q, err)

										}

										conds[i] = cond

									}

									return &Query{ast: ast, conds: conds}, nil

								}


								// Matches satisfies part of the pubsub.Query interface.  This implementation

								// never reports an error. A nil *Query matches all events.

								func (q *Query) Matches(events []types.Event) (bool, error) {

									if q == nil {

										return true, nil

									}

									return q.matchesEvents(events), nil

								}


								// String matches part of the pubsub.Query interface.

								func (q *Query) String() string {

									if q == nil {

										return "<empty>"

									}

									return q.ast.String()

								}


								// Syntax returns the syntax tree representation of q.

								func (q *Query) Syntax() syntax.Query {

									if q == nil {

										return nil

									}

									return q.ast

								}


								// matchesEvents reports whether all the conditions match the given events.

								func (q *Query) matchesEvents(events []types.Event) bool {

									for _, cond := range q.conds {

										if !cond.matchesAny(events) {

											return false

										}

									}

									return len(events) != 0

								}


								// A condition is a compiled match condition.  A condition matches an event if

								// the event has the designated type, contains an attribute with the given

								// name, and the match function returns true for the attribute value.

								type condition struct {

									tag   string // e.g., "tx.hash"

									match func(s string) bool

								}


								// findAttr returns a slice of attribute values from event matching the

								// condition tag, and reports whether the event type strictly equals the

								// condition tag.

								func (c condition) findAttr(event types.Event) ([]string, bool) {

									if !strings.HasPrefix(c.tag, event.Type) {

										return nil, false // type does not match tag

									} else if len(c.tag) == len(event.Type) {

										return nil, true // type == tag

									}

									var vals []string

									for _, attr := range event.Attributes {

										fullName := event.Type + "." + attr.Key

										if fullName == c.tag {

											vals = append(vals, attr.Value)

										}

									}

									return vals, false

								}


								// matchesAny reports whether c matches at least one of the given events.

								func (c condition) matchesAny(events []types.Event) bool {

									for _, event := range events {

										if c.matchesEvent(event) {

											return true

										}

									}

									return false

								}


								// matchesEvent reports whether c matches the given event.

								func (c condition) matchesEvent(event types.Event) bool {

									vs, tagEqualsType := c.findAttr(event)

									if len(vs) == 0 {

										// As a special case, a condition tag that exactly matches the event type

										// is matched against an empty string. This allows existence checks to

										// work for type-only queries.

										if tagEqualsType {

											return c.match("")

										}

										return false

									}


									// At this point, we have candidate values.

									for _, v := range vs {

										if c.match(v) {

											return true

										}

									}

									return false

								}


								func compileCondition(cond syntax.Condition) (condition, error) {

									out := condition{tag: cond.Tag}


									// Handle existence checks separately to simplify the logic below for

									// comparisons that take arguments.

									if cond.Op == syntax.TExists {

										out.match = func(string) bool { return true }

										return out, nil

									}


									// All the other operators require an argument.

									if cond.Arg == nil {

										return condition{}, fmt.Errorf("missing argument for %v", cond.Op)

									}


									// Precompile the argument value matcher.

									argType := cond.Arg.Type

									var argValue interface{}


									switch argType {

									case syntax.TString:

										argValue = cond.Arg.Value()

									case syntax.TNumber:

										argValue = cond.Arg.Number()

									case syntax.TTime, syntax.TDate:

										argValue = cond.Arg.Time()

									default:

										return condition{}, fmt.Errorf("unknown argument type %v", argType)

									}


									mcons := opTypeMap[cond.Op][argType]

									if mcons == nil {

										return condition{}, fmt.Errorf("invalid op/arg combination (%v, %v)", cond.Op, argType)

									}

									out.match = mcons(argValue)

									return out, nil

								}


								// TODO(creachadair): The existing implementation allows anything number shaped

								// to be treated as a number. This preserves the parts of that behavior we had

								// tests for, but we should probably get rid of that.

								var extractNum = regexp.MustCompile(`^\d+(\.\d+)?`)


								func parseNumber(s string) (float64, error) {

									return strconv.ParseFloat(extractNum.FindString(s), 64)

								}


								// A map of operator ⇒ argtype ⇒ match-constructor.

								// An entry does not exist if the combination is not valid.

								//

								// Disable the dupl lint for this map. The result isn't even correct.

								//nolint:dupl

								var opTypeMap = map[syntax.Token]map[syntax.Token]func(interface{}) func(string) bool{

									syntax.TContains: {

										syntax.TString: func(v interface{}) func(string) bool {

											return func(s string) bool {

												return strings.Contains(s, v.(string))

											}

										},

									},

									syntax.TEq: {

										syntax.TString: func(v interface{}) func(string) bool {

											return func(s string) bool { return s == v.(string) }

										},

										syntax.TNumber: func(v interface{}) func(string) bool {

											return func(s string) bool {

												w, err := parseNumber(s)

												return err == nil && w == v.(float64)

											}

										},

										syntax.TDate: func(v interface{}) func(string) bool {

											return func(s string) bool {

												ts, err := syntax.ParseDate(s)

												return err == nil && ts.Equal(v.(time.Time))

											}

										},

										syntax.TTime: func(v interface{}) func(string) bool {

											return func(s string) bool {

												ts, err := syntax.ParseTime(s)

												return err == nil && ts.Equal(v.(time.Time))

											}

										},

									},

									syntax.TLt: {

										syntax.TNumber: func(v interface{}) func(string) bool {

											return func(s string) bool {

												w, err := parseNumber(s)

												return err == nil && w < v.(float64)

											}

										},

										syntax.TDate: func(v interface{}) func(string) bool {

											return func(s string) bool {

												ts, err := syntax.ParseDate(s)

												return err == nil && ts.Before(v.(time.Time))

											}

										},

										syntax.TTime: func(v interface{}) func(string) bool {

											return func(s string) bool {

												ts, err := syntax.ParseTime(s)

												return err == nil && ts.Before(v.(time.Time))

											}

										},

									},

									syntax.TLeq: {

										syntax.TNumber: func(v interface{}) func(string) bool {

											return func(s string) bool {

												w, err := parseNumber(s)

												return err == nil && w <= v.(float64)

											}

										},

										syntax.TDate: func(v interface{}) func(string) bool {

											return func(s string) bool {

												ts, err := syntax.ParseDate(s)

												return err == nil && !ts.After(v.(time.Time))

											}

										},

										syntax.TTime: func(v interface{}) func(string) bool {

											return func(s string) bool {

												ts, err := syntax.ParseTime(s)

												return err == nil && !ts.After(v.(time.Time))

											}

										},

									},

									syntax.TGt: {

										syntax.TNumber: func(v interface{}) func(string) bool {

											return func(s string) bool {

												w, err := parseNumber(s)

												return err == nil && w > v.(float64)

											}

										},

										syntax.TDate: func(v interface{}) func(string) bool {

											return func(s string) bool {

												ts, err := syntax.ParseDate(s)

												return err == nil && ts.After(v.(time.Time))

											}

										},

										syntax.TTime: func(v interface{}) func(string) bool {

											return func(s string) bool {

												ts, err := syntax.ParseTime(s)

												return err == nil && ts.After(v.(time.Time))

											}

										},

									},

									syntax.TGeq: {

										syntax.TNumber: func(v interface{}) func(string) bool {

											return func(s string) bool {

												w, err := parseNumber(s)

												return err == nil && w >= v.(float64)

											}

										},

										syntax.TDate: func(v interface{}) func(string) bool {

											return func(s string) bool {

												ts, err := syntax.ParseDate(s)

												return err == nil && !ts.Before(v.(time.Time))

											}

										},

										syntax.TTime: func(v interface{}) func(string) bool {

											return func(s string) bool {

												ts, err := syntax.ParseTime(s)

												return err == nil && !ts.Before(v.(time.Time))

											}

										},

									},

								}