ceph-csi/vendor/github.com/google/cel-go/interpreter/attribute_patterns.go

// Copyright 2020 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 interpreter

import (
	"fmt"

	"github.com/google/cel-go/common/containers"
	"github.com/google/cel-go/common/types"
	"github.com/google/cel-go/common/types/ref"
)

// AttributePattern represents a top-level variable with an optional set of qualifier patterns.
//
// When using a CEL expression within a container, e.g. a package or namespace, the variable name
// in the pattern must match the qualified name produced during the variable namespace resolution.
// For example, if variable `c` appears in an expression whose container is `a.b`, the variable
// name supplied to the pattern must be `a.b.c`
//
// The qualifier patterns for attribute matching must be one of the following:
//
//   - valid map key type: string, int, uint, bool
//   - wildcard (*)
//
// Examples:
//
//   1. ns.myvar["complex-value"]
//   2. ns.myvar["complex-value"][0]
//   3. ns.myvar["complex-value"].*.name
//
// The first example is simple: match an attribute where the variable is 'ns.myvar' with a
// field access on 'complex-value'. The second example expands the match to indicate that only
// a specific index `0` should match. And lastly, the third example matches any indexed access
// that later selects the 'name' field.
type AttributePattern struct {
	variable          string
	qualifierPatterns []*AttributeQualifierPattern
}

// NewAttributePattern produces a new mutable AttributePattern based on a variable name.
func NewAttributePattern(variable string) *AttributePattern {
	return &AttributePattern{
		variable:          variable,
		qualifierPatterns: []*AttributeQualifierPattern{},
	}
}

// QualString adds a string qualifier pattern to the AttributePattern. The string may be a valid
// identifier, or string map key including empty string.
func (apat *AttributePattern) QualString(pattern string) *AttributePattern {
	apat.qualifierPatterns = append(apat.qualifierPatterns,
		&AttributeQualifierPattern{value: pattern})
	return apat
}

// QualInt adds an int qualifier pattern to the AttributePattern. The index may be either a map or
// list index.
func (apat *AttributePattern) QualInt(pattern int64) *AttributePattern {
	apat.qualifierPatterns = append(apat.qualifierPatterns,
		&AttributeQualifierPattern{value: pattern})
	return apat
}

// QualUint adds an uint qualifier pattern for a map index operation to the AttributePattern.
func (apat *AttributePattern) QualUint(pattern uint64) *AttributePattern {
	apat.qualifierPatterns = append(apat.qualifierPatterns,
		&AttributeQualifierPattern{value: pattern})
	return apat
}

// QualBool adds a bool qualifier pattern for a map index operation to the AttributePattern.
func (apat *AttributePattern) QualBool(pattern bool) *AttributePattern {
	apat.qualifierPatterns = append(apat.qualifierPatterns,
		&AttributeQualifierPattern{value: pattern})
	return apat
}

// Wildcard adds a special sentinel qualifier pattern that will match any single qualifier.
func (apat *AttributePattern) Wildcard() *AttributePattern {
	apat.qualifierPatterns = append(apat.qualifierPatterns,
		&AttributeQualifierPattern{wildcard: true})
	return apat
}

// VariableMatches returns true if the fully qualified variable matches the AttributePattern
// fully qualified variable name.
func (apat *AttributePattern) VariableMatches(variable string) bool {
	return apat.variable == variable
}

// QualifierPatterns returns the set of AttributeQualifierPattern values on the AttributePattern.
func (apat *AttributePattern) QualifierPatterns() []*AttributeQualifierPattern {
	return apat.qualifierPatterns
}

// AttributeQualifierPattern holds a wildcard or valued qualifier pattern.
type AttributeQualifierPattern struct {
	wildcard bool
	value    interface{}
}

// Matches returns true if the qualifier pattern is a wildcard, or the Qualifier implements the
// qualifierValueEquator interface and its IsValueEqualTo returns true for the qualifier pattern.
func (qpat *AttributeQualifierPattern) Matches(q Qualifier) bool {
	if qpat.wildcard {
		return true
	}
	qve, ok := q.(qualifierValueEquator)
	return ok && qve.QualifierValueEquals(qpat.value)
}

// qualifierValueEquator defines an interface for determining if an input value, of valid map key
// type, is equal to the value held in the Qualifier. This interface is used by the
// AttributeQualifierPattern to determine pattern matches for non-wildcard qualifier patterns.
//
// Note: Attribute values are also Qualifier values; however, Attributes are resolved before
// qualification happens. This is an implementation detail, but one relevant to why the Attribute
// types do not surface in the list of implementations.
//
// See: partialAttributeFactory.matchesUnknownPatterns for more details on how this interface is
// used.
type qualifierValueEquator interface {
	// QualifierValueEquals returns true if the input value is equal to the value held in the
	// Qualifier.
	QualifierValueEquals(value interface{}) bool
}

// QualifierValueEquals implementation for boolean qualifiers.
func (q *boolQualifier) QualifierValueEquals(value interface{}) bool {
	bval, ok := value.(bool)
	return ok && q.value == bval
}

// QualifierValueEquals implementation for field qualifiers.
func (q *fieldQualifier) QualifierValueEquals(value interface{}) bool {
	sval, ok := value.(string)
	return ok && q.Name == sval
}

// QualifierValueEquals implementation for string qualifiers.
func (q *stringQualifier) QualifierValueEquals(value interface{}) bool {
	sval, ok := value.(string)
	return ok && q.value == sval
}

// QualifierValueEquals implementation for int qualifiers.
func (q *intQualifier) QualifierValueEquals(value interface{}) bool {
	return numericValueEquals(value, q.celValue)
}

// QualifierValueEquals implementation for uint qualifiers.
func (q *uintQualifier) QualifierValueEquals(value interface{}) bool {
	return numericValueEquals(value, q.celValue)
}

// QualifierValueEquals implementation for double qualifiers.
func (q *doubleQualifier) QualifierValueEquals(value interface{}) bool {
	return numericValueEquals(value, q.celValue)
}

// numericValueEquals uses CEL equality to determine whether two number values are
func numericValueEquals(value interface{}, celValue ref.Val) bool {
	val := types.DefaultTypeAdapter.NativeToValue(value)
	return celValue.Equal(val) == types.True
}

// NewPartialAttributeFactory returns an AttributeFactory implementation capable of performing
// AttributePattern matches with PartialActivation inputs.
func NewPartialAttributeFactory(container *containers.Container,
	adapter ref.TypeAdapter,
	provider ref.TypeProvider) AttributeFactory {
	fac := NewAttributeFactory(container, adapter, provider)
	return &partialAttributeFactory{
		AttributeFactory: fac,
		container:        container,
		adapter:          adapter,
		provider:         provider,
	}
}

type partialAttributeFactory struct {
	AttributeFactory
	container *containers.Container
	adapter   ref.TypeAdapter
	provider  ref.TypeProvider
}

// AbsoluteAttribute implementation of the AttributeFactory interface which wraps the
// NamespacedAttribute resolution in an internal attributeMatcher object to dynamically match
// unknown patterns from PartialActivation inputs if given.
func (fac *partialAttributeFactory) AbsoluteAttribute(id int64, names ...string) NamespacedAttribute {
	attr := fac.AttributeFactory.AbsoluteAttribute(id, names...)
	return &attributeMatcher{fac: fac, NamespacedAttribute: attr}
}

// MaybeAttribute implementation of the AttributeFactory interface which ensure that the set of
// 'maybe' NamespacedAttribute values are produced using the partialAttributeFactory rather than
// the base AttributeFactory implementation.
func (fac *partialAttributeFactory) MaybeAttribute(id int64, name string) Attribute {
	return &maybeAttribute{
		id: id,
		attrs: []NamespacedAttribute{
			fac.AbsoluteAttribute(id, fac.container.ResolveCandidateNames(name)...),
		},
		adapter:  fac.adapter,
		provider: fac.provider,
		fac:      fac,
	}
}

// matchesUnknownPatterns returns true if the variable names and qualifiers for a given
// Attribute value match any of the ActivationPattern objects in the set of unknown activation
// patterns on the given PartialActivation.
//
// For example, in the expression `a.b`, the Attribute is composed of variable `a`, with string
// qualifier `b`. When a PartialActivation is supplied, it indicates that some or all of the data
// provided in the input is unknown by specifying unknown AttributePatterns. An AttributePattern
// that refers to variable `a` with a string qualifier of `c` will not match `a.b`; however, any
// of the following patterns will match Attribute `a.b`:
//
// - `AttributePattern("a")`
// - `AttributePattern("a").Wildcard()`
// - `AttributePattern("a").QualString("b")`
// - `AttributePattern("a").QualString("b").QualInt(0)`
//
// Any AttributePattern which overlaps an Attribute or vice-versa will produce an Unknown result
// for the last pattern matched variable or qualifier in the Attribute. In the first matching
// example, the expression id representing variable `a` would be listed in the Unknown result,
// whereas in the other pattern examples, the qualifier `b` would be returned as the Unknown.
func (fac *partialAttributeFactory) matchesUnknownPatterns(
	vars PartialActivation,
	attrID int64,
	variableNames []string,
	qualifiers []Qualifier) (types.Unknown, error) {
	patterns := vars.UnknownAttributePatterns()
	candidateIndices := map[int]struct{}{}
	for _, variable := range variableNames {
		for i, pat := range patterns {
			if pat.VariableMatches(variable) {
				candidateIndices[i] = struct{}{}
			}
		}
	}
	// Determine whether to return early if there are no candidate unknown patterns.
	if len(candidateIndices) == 0 {
		return nil, nil
	}
	// Determine whether to return early if there are no qualifiers.
	if len(qualifiers) == 0 {
		return types.Unknown{attrID}, nil
	}
	// Resolve the attribute qualifiers into a static set. This prevents more dynamic
	// Attribute resolutions than necessary when there are multiple unknown patterns
	// that traverse the same Attribute-based qualifier field.
	newQuals := make([]Qualifier, len(qualifiers))
	for i, qual := range qualifiers {
		attr, isAttr := qual.(Attribute)
		if isAttr {
			val, err := attr.Resolve(vars)
			if err != nil {
				return nil, err
			}
			unk, isUnk := val.(types.Unknown)
			if isUnk {
				return unk, nil
			}
			// If this resolution behavior ever changes, new implementations of the
			// qualifierValueEquator may be required to handle proper resolution.
			qual, err = fac.NewQualifier(nil, qual.ID(), val)
			if err != nil {
				return nil, err
			}
		}
		newQuals[i] = qual
	}
	// Determine whether any of the unknown patterns match.
	for patIdx := range candidateIndices {
		pat := patterns[patIdx]
		isUnk := true
		matchExprID := attrID
		qualPats := pat.QualifierPatterns()
		for i, qual := range newQuals {
			if i >= len(qualPats) {
				break
			}
			matchExprID = qual.ID()
			qualPat := qualPats[i]
			// Note, the AttributeQualifierPattern relies on the input Qualifier not being an
			// Attribute, since there is no way to resolve the Attribute with the information
			// provided to the Matches call.
			if !qualPat.Matches(qual) {
				isUnk = false
				break
			}
		}
		if isUnk {
			return types.Unknown{matchExprID}, nil
		}
	}
	return nil, nil
}

// attributeMatcher embeds the NamespacedAttribute interface which allows it to participate in
// AttributePattern matching against Attribute values without having to modify the code paths that
// identify Attributes in expressions.
type attributeMatcher struct {
	NamespacedAttribute
	qualifiers []Qualifier
	fac        *partialAttributeFactory
}

// AddQualifier implements the Attribute interface method.
func (m *attributeMatcher) AddQualifier(qual Qualifier) (Attribute, error) {
	// Add the qualifier to the embedded NamespacedAttribute. If the input to the Resolve
	// method is not a PartialActivation, or does not match an unknown attribute pattern, the
	// Resolve method is directly invoked on the underlying NamespacedAttribute.
	_, err := m.NamespacedAttribute.AddQualifier(qual)
	if err != nil {
		return nil, err
	}
	// The attributeMatcher overloads TryResolve and will attempt to match unknown patterns against
	// the variable name and qualifier set contained within the Attribute. These values are not
	// directly inspectable on the top-level NamespacedAttribute interface and so are tracked within
	// the attributeMatcher.
	m.qualifiers = append(m.qualifiers, qual)
	return m, nil
}

// Resolve is an implementation of the Attribute interface method which uses the
// attributeMatcher TryResolve implementation rather than the embedded NamespacedAttribute
// Resolve implementation.
func (m *attributeMatcher) Resolve(vars Activation) (interface{}, error) {
	obj, found, err := m.TryResolve(vars)
	if err != nil {
		return nil, err
	}
	if !found {
		return nil, fmt.Errorf("no such attribute: %v", m.NamespacedAttribute)
	}
	return obj, nil
}

// TryResolve is an implementation of the NamespacedAttribute interface method which tests
// for matching unknown attribute patterns and returns types.Unknown if present. Otherwise,
// the standard Resolve logic applies.
func (m *attributeMatcher) TryResolve(vars Activation) (interface{}, bool, error) {
	id := m.NamespacedAttribute.ID()
	// Bug in how partial activation is resolved, should search parents as well.
	partial, isPartial := toPartialActivation(vars)
	if isPartial {
		unk, err := m.fac.matchesUnknownPatterns(
			partial,
			id,
			m.CandidateVariableNames(),
			m.qualifiers)
		if err != nil {
			return nil, true, err
		}
		if unk != nil {
			return unk, true, nil
		}
	}
	return m.NamespacedAttribute.TryResolve(vars)
}

// Qualify is an implementation of the Qualifier interface method.
func (m *attributeMatcher) Qualify(vars Activation, obj interface{}) (interface{}, error) {
	val, err := m.Resolve(vars)
	if err != nil {
		return nil, err
	}
	unk, isUnk := val.(types.Unknown)
	if isUnk {
		return unk, nil
	}
	qual, err := m.fac.NewQualifier(nil, m.ID(), val)
	if err != nil {
		return nil, err
	}
	return qual.Qualify(vars, obj)
}

func toPartialActivation(vars Activation) (PartialActivation, bool) {
	pv, ok := vars.(PartialActivation)
	if ok {
		return pv, true
	}
	if vars.Parent() != nil {
		return toPartialActivation(vars.Parent())
	}
	return nil, false
}
rebase: bump k8s.io/kubernetes from 1.26.2 to 1.27.2 Bumps [k8s.io/kubernetes](https://github.com/kubernetes/kubernetes) from 1.26.2 to 1.27.2. - [Release notes](https://github.com/kubernetes/kubernetes/releases) - [Commits](https://github.com/kubernetes/kubernetes/compare/v1.26.2...v1.27.2) --- updated-dependencies: - dependency-name: k8s.io/kubernetes dependency-type: direct:production update-type: version-update:semver-minor ... Signed-off-by: dependabot[bot] <support@github.com> 2023-05-29 21:03:29 +00:00			`// Copyright 2020 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 interpreter`

			`import (`
			`"fmt"`

			`"github.com/google/cel-go/common/containers"`
			`"github.com/google/cel-go/common/types"`
			`"github.com/google/cel-go/common/types/ref"`
			`)`

			`// AttributePattern represents a top-level variable with an optional set of qualifier patterns.`
			`//`
			`// When using a CEL expression within a container, e.g. a package or namespace, the variable name`
			`// in the pattern must match the qualified name produced during the variable namespace resolution.`
			// For example, if variable `c` appears in an expression whose container is `a.b`, the variable
			// name supplied to the pattern must be `a.b.c`
			`//`
			`// The qualifier patterns for attribute matching must be one of the following:`
			`//`
			`// - valid map key type: string, int, uint, bool`
			`// - wildcard (*)`
			`//`
			`// Examples:`
			`//`
			`// 1. ns.myvar["complex-value"]`
			`// 2. ns.myvar["complex-value"][0]`
			`// 3. ns.myvar["complex-value"].*.name`
			`//`
			`// The first example is simple: match an attribute where the variable is 'ns.myvar' with a`
			`// field access on 'complex-value'. The second example expands the match to indicate that only`
			// a specific index `0` should match. And lastly, the third example matches any indexed access
			`// that later selects the 'name' field.`
			`type AttributePattern struct {`
			`variable string`
			`qualifierPatterns []*AttributeQualifierPattern`
			`}`

			`// NewAttributePattern produces a new mutable AttributePattern based on a variable name.`
			`func NewAttributePattern(variable string) *AttributePattern {`
			`return &AttributePattern{`
			`variable: variable,`
			`qualifierPatterns: []*AttributeQualifierPattern{},`
			`}`
			`}`

			`// QualString adds a string qualifier pattern to the AttributePattern. The string may be a valid`
			`// identifier, or string map key including empty string.`
			`func (apat AttributePattern) QualString(pattern string) AttributePattern {`
			`apat.qualifierPatterns = append(apat.qualifierPatterns,`
			`&AttributeQualifierPattern{value: pattern})`
			`return apat`
			`}`

			`// QualInt adds an int qualifier pattern to the AttributePattern. The index may be either a map or`
			`// list index.`
			`func (apat AttributePattern) QualInt(pattern int64) AttributePattern {`
			`apat.qualifierPatterns = append(apat.qualifierPatterns,`
			`&AttributeQualifierPattern{value: pattern})`
			`return apat`
			`}`

			`// QualUint adds an uint qualifier pattern for a map index operation to the AttributePattern.`
			`func (apat AttributePattern) QualUint(pattern uint64) AttributePattern {`
			`apat.qualifierPatterns = append(apat.qualifierPatterns,`
			`&AttributeQualifierPattern{value: pattern})`
			`return apat`
			`}`

			`// QualBool adds a bool qualifier pattern for a map index operation to the AttributePattern.`
			`func (apat AttributePattern) QualBool(pattern bool) AttributePattern {`
			`apat.qualifierPatterns = append(apat.qualifierPatterns,`
			`&AttributeQualifierPattern{value: pattern})`
			`return apat`
			`}`

			`// Wildcard adds a special sentinel qualifier pattern that will match any single qualifier.`
			`func (apat AttributePattern) Wildcard() AttributePattern {`
			`apat.qualifierPatterns = append(apat.qualifierPatterns,`
			`&AttributeQualifierPattern{wildcard: true})`
			`return apat`
			`}`

			`// VariableMatches returns true if the fully qualified variable matches the AttributePattern`
			`// fully qualified variable name.`
			`func (apat *AttributePattern) VariableMatches(variable string) bool {`
			`return apat.variable == variable`
			`}`

			`// QualifierPatterns returns the set of AttributeQualifierPattern values on the AttributePattern.`
			`func (apat AttributePattern) QualifierPatterns() []AttributeQualifierPattern {`
			`return apat.qualifierPatterns`
			`}`

			`// AttributeQualifierPattern holds a wildcard or valued qualifier pattern.`
			`type AttributeQualifierPattern struct {`
			`wildcard bool`
			`value interface{}`
			`}`

			`// Matches returns true if the qualifier pattern is a wildcard, or the Qualifier implements the`
			`// qualifierValueEquator interface and its IsValueEqualTo returns true for the qualifier pattern.`
			`func (qpat *AttributeQualifierPattern) Matches(q Qualifier) bool {`
			`if qpat.wildcard {`
			`return true`
			`}`
			`qve, ok := q.(qualifierValueEquator)`
			`return ok && qve.QualifierValueEquals(qpat.value)`
			`}`

			`// qualifierValueEquator defines an interface for determining if an input value, of valid map key`
			`// type, is equal to the value held in the Qualifier. This interface is used by the`
			`// AttributeQualifierPattern to determine pattern matches for non-wildcard qualifier patterns.`
			`//`
			`// Note: Attribute values are also Qualifier values; however, Attributes are resolved before`
			`// qualification happens. This is an implementation detail, but one relevant to why the Attribute`
			`// types do not surface in the list of implementations.`
			`//`
			`// See: partialAttributeFactory.matchesUnknownPatterns for more details on how this interface is`
			`// used.`
			`type qualifierValueEquator interface {`
			`// QualifierValueEquals returns true if the input value is equal to the value held in the`
			`// Qualifier.`
			`QualifierValueEquals(value interface{}) bool`
			`}`

			`// QualifierValueEquals implementation for boolean qualifiers.`
			`func (q *boolQualifier) QualifierValueEquals(value interface{}) bool {`
			`bval, ok := value.(bool)`
			`return ok && q.value == bval`
			`}`

			`// QualifierValueEquals implementation for field qualifiers.`
			`func (q *fieldQualifier) QualifierValueEquals(value interface{}) bool {`
			`sval, ok := value.(string)`
			`return ok && q.Name == sval`
			`}`

			`// QualifierValueEquals implementation for string qualifiers.`
			`func (q *stringQualifier) QualifierValueEquals(value interface{}) bool {`
			`sval, ok := value.(string)`
			`return ok && q.value == sval`
			`}`

			`// QualifierValueEquals implementation for int qualifiers.`
			`func (q *intQualifier) QualifierValueEquals(value interface{}) bool {`
			`return numericValueEquals(value, q.celValue)`
			`}`

			`// QualifierValueEquals implementation for uint qualifiers.`
			`func (q *uintQualifier) QualifierValueEquals(value interface{}) bool {`
			`return numericValueEquals(value, q.celValue)`
			`}`

			`// QualifierValueEquals implementation for double qualifiers.`
			`func (q *doubleQualifier) QualifierValueEquals(value interface{}) bool {`
			`return numericValueEquals(value, q.celValue)`
			`}`

			`// numericValueEquals uses CEL equality to determine whether two number values are`
			`func numericValueEquals(value interface{}, celValue ref.Val) bool {`
			`val := types.DefaultTypeAdapter.NativeToValue(value)`
			`return celValue.Equal(val) == types.True`
			`}`

			`// NewPartialAttributeFactory returns an AttributeFactory implementation capable of performing`
			`// AttributePattern matches with PartialActivation inputs.`
			`func NewPartialAttributeFactory(container *containers.Container,`
			`adapter ref.TypeAdapter,`
			`provider ref.TypeProvider) AttributeFactory {`
			`fac := NewAttributeFactory(container, adapter, provider)`
			`return &partialAttributeFactory{`
			`AttributeFactory: fac,`
			`container: container,`
			`adapter: adapter,`
			`provider: provider,`
			`}`
			`}`

			`type partialAttributeFactory struct {`
			`AttributeFactory`
			`container *containers.Container`
			`adapter ref.TypeAdapter`
			`provider ref.TypeProvider`
			`}`

			`// AbsoluteAttribute implementation of the AttributeFactory interface which wraps the`
			`// NamespacedAttribute resolution in an internal attributeMatcher object to dynamically match`
			`// unknown patterns from PartialActivation inputs if given.`
			`func (fac *partialAttributeFactory) AbsoluteAttribute(id int64, names ...string) NamespacedAttribute {`
			`attr := fac.AttributeFactory.AbsoluteAttribute(id, names...)`
			`return &attributeMatcher{fac: fac, NamespacedAttribute: attr}`
			`}`

			`// MaybeAttribute implementation of the AttributeFactory interface which ensure that the set of`
			`// 'maybe' NamespacedAttribute values are produced using the partialAttributeFactory rather than`
			`// the base AttributeFactory implementation.`
			`func (fac *partialAttributeFactory) MaybeAttribute(id int64, name string) Attribute {`
			`return &maybeAttribute{`
			`id: id,`
			`attrs: []NamespacedAttribute{`
			`fac.AbsoluteAttribute(id, fac.container.ResolveCandidateNames(name)...),`
			`},`
			`adapter: fac.adapter,`
			`provider: fac.provider,`
			`fac: fac,`
			`}`
			`}`

			`// matchesUnknownPatterns returns true if the variable names and qualifiers for a given`
			`// Attribute value match any of the ActivationPattern objects in the set of unknown activation`
			`// patterns on the given PartialActivation.`
			`//`
			// For example, in the expression `a.b`, the Attribute is composed of variable `a`, with string
			// qualifier `b`. When a PartialActivation is supplied, it indicates that some or all of the data
			`// provided in the input is unknown by specifying unknown AttributePatterns. An AttributePattern`
			// that refers to variable `a` with a string qualifier of `c` will not match `a.b`; however, any
			// of the following patterns will match Attribute `a.b`:
			`//`
			// - `AttributePattern("a")`
			// - `AttributePattern("a").Wildcard()`
			// - `AttributePattern("a").QualString("b")`
			// - `AttributePattern("a").QualString("b").QualInt(0)`
			`//`
			`// Any AttributePattern which overlaps an Attribute or vice-versa will produce an Unknown result`
			`// for the last pattern matched variable or qualifier in the Attribute. In the first matching`
			// example, the expression id representing variable `a` would be listed in the Unknown result,
			// whereas in the other pattern examples, the qualifier `b` would be returned as the Unknown.
			`func (fac *partialAttributeFactory) matchesUnknownPatterns(`
			`vars PartialActivation,`
			`attrID int64,`
			`variableNames []string,`
			`qualifiers []Qualifier) (types.Unknown, error) {`
			`patterns := vars.UnknownAttributePatterns()`
			`candidateIndices := map[int]struct{}{}`
			`for _, variable := range variableNames {`
			`for i, pat := range patterns {`
			`if pat.VariableMatches(variable) {`
			`candidateIndices[i] = struct{}{}`
			`}`
			`}`
			`}`
			`// Determine whether to return early if there are no candidate unknown patterns.`
			`if len(candidateIndices) == 0 {`
			`return nil, nil`
			`}`
			`// Determine whether to return early if there are no qualifiers.`
			`if len(qualifiers) == 0 {`
			`return types.Unknown{attrID}, nil`
			`}`
			`// Resolve the attribute qualifiers into a static set. This prevents more dynamic`
			`// Attribute resolutions than necessary when there are multiple unknown patterns`
			`// that traverse the same Attribute-based qualifier field.`
			`newQuals := make([]Qualifier, len(qualifiers))`
			`for i, qual := range qualifiers {`
			`attr, isAttr := qual.(Attribute)`
			`if isAttr {`
			`val, err := attr.Resolve(vars)`
			`if err != nil {`
			`return nil, err`
			`}`
			`unk, isUnk := val.(types.Unknown)`
			`if isUnk {`
			`return unk, nil`
			`}`
			`// If this resolution behavior ever changes, new implementations of the`
			`// qualifierValueEquator may be required to handle proper resolution.`
			`qual, err = fac.NewQualifier(nil, qual.ID(), val)`
			`if err != nil {`
			`return nil, err`
			`}`
			`}`
			`newQuals[i] = qual`
			`}`
			`// Determine whether any of the unknown patterns match.`
			`for patIdx := range candidateIndices {`
			`pat := patterns[patIdx]`
			`isUnk := true`
			`matchExprID := attrID`
			`qualPats := pat.QualifierPatterns()`
			`for i, qual := range newQuals {`
			`if i >= len(qualPats) {`
			`break`
			`}`
			`matchExprID = qual.ID()`
			`qualPat := qualPats[i]`
			`// Note, the AttributeQualifierPattern relies on the input Qualifier not being an`
			`// Attribute, since there is no way to resolve the Attribute with the information`
			`// provided to the Matches call.`
			`if !qualPat.Matches(qual) {`
			`isUnk = false`
			`break`
			`}`
			`}`
			`if isUnk {`
			`return types.Unknown{matchExprID}, nil`
			`}`
			`}`
			`return nil, nil`
			`}`

			`// attributeMatcher embeds the NamespacedAttribute interface which allows it to participate in`
			`// AttributePattern matching against Attribute values without having to modify the code paths that`
			`// identify Attributes in expressions.`
			`type attributeMatcher struct {`
			`NamespacedAttribute`
			`qualifiers []Qualifier`
			`fac *partialAttributeFactory`
			`}`

			`// AddQualifier implements the Attribute interface method.`
			`func (m *attributeMatcher) AddQualifier(qual Qualifier) (Attribute, error) {`
			`// Add the qualifier to the embedded NamespacedAttribute. If the input to the Resolve`
			`// method is not a PartialActivation, or does not match an unknown attribute pattern, the`
			`// Resolve method is directly invoked on the underlying NamespacedAttribute.`
			`_, err := m.NamespacedAttribute.AddQualifier(qual)`
			`if err != nil {`
			`return nil, err`
			`}`
			`// The attributeMatcher overloads TryResolve and will attempt to match unknown patterns against`
			`// the variable name and qualifier set contained within the Attribute. These values are not`
			`// directly inspectable on the top-level NamespacedAttribute interface and so are tracked within`
			`// the attributeMatcher.`
			`m.qualifiers = append(m.qualifiers, qual)`
			`return m, nil`
			`}`

			`// Resolve is an implementation of the Attribute interface method which uses the`
			`// attributeMatcher TryResolve implementation rather than the embedded NamespacedAttribute`
			`// Resolve implementation.`
			`func (m *attributeMatcher) Resolve(vars Activation) (interface{}, error) {`
			`obj, found, err := m.TryResolve(vars)`
			`if err != nil {`
			`return nil, err`
			`}`
			`if !found {`
			`return nil, fmt.Errorf("no such attribute: %v", m.NamespacedAttribute)`
			`}`
			`return obj, nil`
			`}`

			`// TryResolve is an implementation of the NamespacedAttribute interface method which tests`
			`// for matching unknown attribute patterns and returns types.Unknown if present. Otherwise,`
			`// the standard Resolve logic applies.`
			`func (m *attributeMatcher) TryResolve(vars Activation) (interface{}, bool, error) {`
			`id := m.NamespacedAttribute.ID()`
			`// Bug in how partial activation is resolved, should search parents as well.`
			`partial, isPartial := toPartialActivation(vars)`
			`if isPartial {`
			`unk, err := m.fac.matchesUnknownPatterns(`
			`partial,`
			`id,`
			`m.CandidateVariableNames(),`
			`m.qualifiers)`
			`if err != nil {`
			`return nil, true, err`
			`}`
			`if unk != nil {`
			`return unk, true, nil`
			`}`
			`}`
			`return m.NamespacedAttribute.TryResolve(vars)`
			`}`

			`// Qualify is an implementation of the Qualifier interface method.`
			`func (m *attributeMatcher) Qualify(vars Activation, obj interface{}) (interface{}, error) {`
			`val, err := m.Resolve(vars)`
			`if err != nil {`
			`return nil, err`
			`}`
			`unk, isUnk := val.(types.Unknown)`
			`if isUnk {`
			`return unk, nil`
			`}`
			`qual, err := m.fac.NewQualifier(nil, m.ID(), val)`
			`if err != nil {`
			`return nil, err`
			`}`
			`return qual.Qualify(vars, obj)`
			`}`

			`func toPartialActivation(vars Activation) (PartialActivation, bool) {`
			`pv, ok := vars.(PartialActivation)`
			`if ok {`
			`return pv, true`
			`}`
			`if vars.Parent() != nil {`
			`return toPartialActivation(vars.Parent())`
			`}`
			`return nil, false`
			`}`