mirror of
https://github.com/ceph/ceph-csi.git
synced 2024-12-25 14:30:22 +00:00
5a66991bb3
updating the kubernetes release to the latest in main go.mod Signed-off-by: Madhu Rajanna <madhupr007@gmail.com>
582 lines
23 KiB
Go
582 lines
23 KiB
Go
/*
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Copyright 2022 The Kubernetes Authors.
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Licensed under the Apache License, Version 2.0 (the "License");
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you may not use this file except in compliance with the License.
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You may obtain a copy of the License at
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http://www.apache.org/licenses/LICENSE-2.0
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Unless required by applicable law or agreed to in writing, software
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distributed under the License is distributed on an "AS IS" BASIS,
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WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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See the License for the specific language governing permissions and
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limitations under the License.
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*/
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package library
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import (
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"fmt"
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"math"
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"github.com/google/cel-go/checker"
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"github.com/google/cel-go/common"
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"github.com/google/cel-go/common/ast"
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"github.com/google/cel-go/common/types"
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"github.com/google/cel-go/common/types/ref"
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"github.com/google/cel-go/common/types/traits"
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"k8s.io/apiserver/pkg/cel"
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)
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// panicOnUnknown makes cost estimate functions panic on unrecognized functions.
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// This is only set to true for unit tests.
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var panicOnUnknown = false
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// builtInFunctions is a list of functions used in cost tests that are not handled by CostEstimator.
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var knownUnhandledFunctions = map[string]bool{
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"uint": true,
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"duration": true,
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"bytes": true,
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"timestamp": true,
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"value": true,
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"_==_": true,
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"_&&_": true,
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"_>_": true,
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"!_": true,
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"strings.quote": true,
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}
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// CostEstimator implements CEL's interpretable.ActualCostEstimator and checker.CostEstimator.
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type CostEstimator struct {
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// SizeEstimator provides a CostEstimator.EstimateSize that this CostEstimator will delegate size estimation
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// calculations to if the size is not well known (i.e. a constant).
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SizeEstimator checker.CostEstimator
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}
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const (
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// shortest repeatable selector requirement that allocates a values slice is 2 characters: k,
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selectorLengthToRequirementCount = float64(.5)
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// the expensive parts to represent each requirement are a struct and a values slice
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costPerRequirement = float64(common.ListCreateBaseCost + common.StructCreateBaseCost)
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)
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// a selector consists of a list of requirements held in a slice
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var baseSelectorCost = checker.CostEstimate{Min: common.ListCreateBaseCost, Max: common.ListCreateBaseCost}
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func selectorCostEstimate(selectorLength checker.SizeEstimate) checker.CostEstimate {
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parseCost := selectorLength.MultiplyByCostFactor(common.StringTraversalCostFactor)
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requirementCount := selectorLength.MultiplyByCostFactor(selectorLengthToRequirementCount)
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requirementCost := requirementCount.MultiplyByCostFactor(costPerRequirement)
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return baseSelectorCost.Add(parseCost).Add(requirementCost)
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}
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func (l *CostEstimator) CallCost(function, overloadId string, args []ref.Val, result ref.Val) *uint64 {
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switch function {
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case "check":
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// An authorization check has a fixed cost
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// This cost is set to allow for only two authorization checks per expression
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cost := uint64(350000)
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return &cost
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case "serviceAccount", "path", "group", "resource", "subresource", "namespace", "name", "allowed", "reason", "error", "errored":
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// All authorization builder and accessor functions have a nominal cost
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cost := uint64(1)
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return &cost
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case "fieldSelector", "labelSelector":
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// field and label selector parse is a string parse into a structured set of requirements
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if len(args) >= 2 {
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selectorLength := actualSize(args[1])
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cost := selectorCostEstimate(checker.SizeEstimate{Min: selectorLength, Max: selectorLength})
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return &cost.Max
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}
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case "isSorted", "sum", "max", "min", "indexOf", "lastIndexOf":
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var cost uint64
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if len(args) > 0 {
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cost += traversalCost(args[0]) // these O(n) operations all cost roughly the cost of a single traversal
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}
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return &cost
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case "url", "lowerAscii", "upperAscii", "substring", "trim":
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if len(args) >= 1 {
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cost := uint64(math.Ceil(float64(actualSize(args[0])) * common.StringTraversalCostFactor))
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return &cost
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}
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case "replace", "split":
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if len(args) >= 1 {
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// cost is the traversal plus the construction of the result
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cost := uint64(math.Ceil(float64(actualSize(args[0])) * 2 * common.StringTraversalCostFactor))
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return &cost
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}
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case "join":
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if len(args) >= 1 {
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cost := uint64(math.Ceil(float64(actualSize(result)) * 2 * common.StringTraversalCostFactor))
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return &cost
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}
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case "find", "findAll":
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if len(args) >= 2 {
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strCost := uint64(math.Ceil((1.0 + float64(actualSize(args[0]))) * common.StringTraversalCostFactor))
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// We don't know how many expressions are in the regex, just the string length (a huge
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// improvement here would be to somehow get a count the number of expressions in the regex or
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// how many states are in the regex state machine and use that to measure regex cost).
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// For now, we're making a guess that each expression in a regex is typically at least 4 chars
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// in length.
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regexCost := uint64(math.Ceil(float64(actualSize(args[1])) * common.RegexStringLengthCostFactor))
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cost := strCost * regexCost
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return &cost
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}
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case "cidr", "isIP", "isCIDR":
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// IP and CIDR parsing is a string traversal.
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if len(args) >= 1 {
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cost := uint64(math.Ceil(float64(actualSize(args[0])) * common.StringTraversalCostFactor))
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return &cost
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}
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case "ip":
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// IP and CIDR parsing is a string traversal.
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if len(args) >= 1 {
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if overloadId == "cidr_ip" {
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// The IP member of the CIDR object is just accessing a field.
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// Nominal cost.
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cost := uint64(1)
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return &cost
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}
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cost := uint64(math.Ceil(float64(actualSize(args[0])) * common.StringTraversalCostFactor))
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return &cost
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}
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case "ip.isCanonical":
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if len(args) >= 1 {
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// We have to parse the string and then compare the parsed string to the original string.
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// So we double the cost of parsing the string.
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cost := uint64(math.Ceil(float64(actualSize(args[0])) * 2 * common.StringTraversalCostFactor))
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return &cost
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}
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case "masked", "prefixLength", "family", "isUnspecified", "isLoopback", "isLinkLocalMulticast", "isLinkLocalUnicast", "isGlobalUnicast":
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// IP and CIDR accessors are nominal cost.
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cost := uint64(1)
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return &cost
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case "containsIP":
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if len(args) >= 2 {
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cidrSize := actualSize(args[0])
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otherSize := actualSize(args[1])
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// This is the base cost of comparing two byte lists.
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// We will compare only up to the length of the CIDR prefix in bytes, so use the cidrSize twice.
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cost := uint64(math.Ceil(float64(cidrSize+cidrSize) * common.StringTraversalCostFactor))
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if overloadId == "cidr_contains_ip_string" {
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// If we are comparing a string, we must parse the string to into the right type, so add the cost of traversing the string again.
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cost += uint64(math.Ceil(float64(otherSize) * common.StringTraversalCostFactor))
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}
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return &cost
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}
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case "containsCIDR":
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if len(args) >= 2 {
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cidrSize := actualSize(args[0])
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otherSize := actualSize(args[1])
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// This is the base cost of comparing two byte lists.
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// We will compare only up to the length of the CIDR prefix in bytes, so use the cidrSize twice.
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cost := uint64(math.Ceil(float64(cidrSize+cidrSize) * common.StringTraversalCostFactor))
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// As we are comparing if a CIDR is within another CIDR, we first mask the base CIDR and
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// also compare the CIDR bits.
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// This has an additional cost of the length of the IP being traversed again, plus 1.
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cost += uint64(math.Ceil(float64(cidrSize)*common.StringTraversalCostFactor)) + 1
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if overloadId == "cidr_contains_cidr_string" {
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// If we are comparing a string, we must parse the string to into the right type, so add the cost of traversing the string again.
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cost += uint64(math.Ceil(float64(otherSize) * common.StringTraversalCostFactor))
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}
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return &cost
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}
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case "quantity", "isQuantity":
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if len(args) >= 1 {
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cost := uint64(math.Ceil(float64(actualSize(args[0])) * common.StringTraversalCostFactor))
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return &cost
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}
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case "validate":
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if len(args) >= 2 {
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format, isFormat := args[0].Value().(*cel.Format)
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if isFormat {
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strSize := actualSize(args[1])
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// Dont have access to underlying regex, estimate a long regexp
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regexSize := format.MaxRegexSize
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// Copied from CEL implementation for regex cost
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//
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// https://swtch.com/~rsc/regexp/regexp1.html applies to RE2 implementation supported by CEL
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// Add one to string length for purposes of cost calculation to prevent product of string and regex to be 0
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// in case where string is empty but regex is still expensive.
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strCost := uint64(math.Ceil((1.0 + float64(strSize)) * common.StringTraversalCostFactor))
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// We don't know how many expressions are in the regex, just the string length (a huge
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// improvement here would be to somehow get a count the number of expressions in the regex or
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// how many states are in the regex state machine and use that to measure regex cost).
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// For now, we're making a guess that each expression in a regex is typically at least 4 chars
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// in length.
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regexCost := uint64(math.Ceil(float64(regexSize) * common.RegexStringLengthCostFactor))
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cost := strCost * regexCost
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return &cost
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}
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}
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case "format.named":
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// Simply dictionary lookup
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cost := uint64(1)
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return &cost
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case "sign", "asInteger", "isInteger", "asApproximateFloat", "isGreaterThan", "isLessThan", "compareTo", "add", "sub":
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cost := uint64(1)
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return &cost
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case "getScheme", "getHostname", "getHost", "getPort", "getEscapedPath", "getQuery":
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// url accessors
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cost := uint64(1)
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return &cost
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}
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if panicOnUnknown && !knownUnhandledFunctions[function] {
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panic(fmt.Errorf("CallCost: unhandled function %q or args %v", function, args))
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}
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return nil
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}
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func (l *CostEstimator) EstimateCallCost(function, overloadId string, target *checker.AstNode, args []checker.AstNode) *checker.CallEstimate {
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// WARNING: Any changes to this code impact API compatibility! The estimated cost is used to determine which CEL rules may be written to a
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// CRD and any change (cost increases and cost decreases) are breaking.
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switch function {
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case "check":
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// An authorization check has a fixed cost
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// This cost is set to allow for only two authorization checks per expression
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return &checker.CallEstimate{CostEstimate: checker.CostEstimate{Min: 350000, Max: 350000}}
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case "serviceAccount", "path", "group", "resource", "subresource", "namespace", "name", "allowed", "reason", "error", "errored":
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// All authorization builder and accessor functions have a nominal cost
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return &checker.CallEstimate{CostEstimate: checker.CostEstimate{Min: 1, Max: 1}}
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case "fieldSelector", "labelSelector":
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// field and label selector parse is a string parse into a structured set of requirements
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if len(args) == 1 {
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return &checker.CallEstimate{CostEstimate: selectorCostEstimate(l.sizeEstimate(args[0]))}
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}
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case "isSorted", "sum", "max", "min", "indexOf", "lastIndexOf":
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if target != nil {
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// Charge 1 cost for comparing each element in the list
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elCost := checker.CostEstimate{Min: 1, Max: 1}
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// If the list contains strings or bytes, add the cost of traversing all the strings/bytes as a way
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// of estimating the additional comparison cost.
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if elNode := l.listElementNode(*target); elNode != nil {
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k := elNode.Type().Kind()
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if k == types.StringKind || k == types.BytesKind {
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sz := l.sizeEstimate(elNode)
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elCost = elCost.Add(sz.MultiplyByCostFactor(common.StringTraversalCostFactor))
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}
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return &checker.CallEstimate{CostEstimate: l.sizeEstimate(*target).MultiplyByCost(elCost)}
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} else { // the target is a string, which is supported by indexOf and lastIndexOf
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return &checker.CallEstimate{CostEstimate: l.sizeEstimate(*target).MultiplyByCostFactor(common.StringTraversalCostFactor)}
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}
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}
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case "url":
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if len(args) == 1 {
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sz := l.sizeEstimate(args[0])
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return &checker.CallEstimate{CostEstimate: sz.MultiplyByCostFactor(common.StringTraversalCostFactor)}
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}
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case "lowerAscii", "upperAscii", "substring", "trim":
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if target != nil {
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sz := l.sizeEstimate(*target)
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return &checker.CallEstimate{CostEstimate: sz.MultiplyByCostFactor(common.StringTraversalCostFactor), ResultSize: &sz}
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}
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case "replace":
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if target != nil && len(args) >= 2 {
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sz := l.sizeEstimate(*target)
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toReplaceSz := l.sizeEstimate(args[0])
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replaceWithSz := l.sizeEstimate(args[1])
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var replaceCount, retainedSz checker.SizeEstimate
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// find the longest replacement:
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if toReplaceSz.Min == 0 {
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// if the string being replaced is empty, replace surrounds all characters in the input string with the replacement.
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if sz.Max < math.MaxUint64 {
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replaceCount.Max = sz.Max + 1
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} else {
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replaceCount.Max = sz.Max
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}
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// Include the length of the longest possible original string length.
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retainedSz.Max = sz.Max
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} else if replaceWithSz.Max <= toReplaceSz.Min {
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// If the replacement does not make the result longer, use the original string length.
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replaceCount.Max = 0
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retainedSz.Max = sz.Max
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} else {
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// Replace the smallest possible substrings with the largest possible replacement
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// as many times as possible.
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replaceCount.Max = uint64(math.Ceil(float64(sz.Max) / float64(toReplaceSz.Min)))
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}
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// find the shortest replacement:
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if toReplaceSz.Max == 0 {
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// if the string being replaced is empty, replace surrounds all characters in the input string with the replacement.
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if sz.Min < math.MaxUint64 {
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replaceCount.Min = sz.Min + 1
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} else {
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replaceCount.Min = sz.Min
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}
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// Include the length of the shortest possible original string length.
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retainedSz.Min = sz.Min
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} else if toReplaceSz.Max <= replaceWithSz.Min {
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// If the replacement does not make the result shorter, use the original string length.
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replaceCount.Min = 0
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retainedSz.Min = sz.Min
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} else {
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// Replace the largest possible substrings being with the smallest possible replacement
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// as many times as possible.
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replaceCount.Min = uint64(math.Ceil(float64(sz.Min) / float64(toReplaceSz.Max)))
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}
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size := replaceCount.Multiply(replaceWithSz).Add(retainedSz)
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// cost is the traversal plus the construction of the result
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return &checker.CallEstimate{CostEstimate: sz.MultiplyByCostFactor(2 * common.StringTraversalCostFactor), ResultSize: &size}
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}
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case "split":
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if target != nil {
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sz := l.sizeEstimate(*target)
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// Worst case size is where is that a separator of "" is used, and each char is returned as a list element.
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max := sz.Max
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if len(args) > 1 {
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if v := args[1].Expr().AsLiteral(); v != nil {
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if i, ok := v.Value().(int64); ok {
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max = uint64(i)
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}
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}
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}
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// Cost is the traversal plus the construction of the result.
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return &checker.CallEstimate{CostEstimate: sz.MultiplyByCostFactor(2 * common.StringTraversalCostFactor), ResultSize: &checker.SizeEstimate{Min: 0, Max: max}}
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}
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case "join":
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if target != nil {
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var sz checker.SizeEstimate
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listSize := l.sizeEstimate(*target)
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if elNode := l.listElementNode(*target); elNode != nil {
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elemSize := l.sizeEstimate(elNode)
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sz = listSize.Multiply(elemSize)
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}
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if len(args) > 0 {
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sepSize := l.sizeEstimate(args[0])
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minSeparators := uint64(0)
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maxSeparators := uint64(0)
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if listSize.Min > 0 {
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minSeparators = listSize.Min - 1
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}
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if listSize.Max > 0 {
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maxSeparators = listSize.Max - 1
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}
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sz = sz.Add(sepSize.Multiply(checker.SizeEstimate{Min: minSeparators, Max: maxSeparators}))
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}
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return &checker.CallEstimate{CostEstimate: sz.MultiplyByCostFactor(common.StringTraversalCostFactor), ResultSize: &sz}
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}
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case "find", "findAll":
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if target != nil && len(args) >= 1 {
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sz := l.sizeEstimate(*target)
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// Add one to string length for purposes of cost calculation to prevent product of string and regex to be 0
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// in case where string is empty but regex is still expensive.
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strCost := sz.Add(checker.SizeEstimate{Min: 1, Max: 1}).MultiplyByCostFactor(common.StringTraversalCostFactor)
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// We don't know how many expressions are in the regex, just the string length (a huge
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|
// improvement here would be to somehow get a count the number of expressions in the regex or
|
|
// how many states are in the regex state machine and use that to measure regex cost).
|
|
// For now, we're making a guess that each expression in a regex is typically at least 4 chars
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// in length.
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regexCost := l.sizeEstimate(args[0]).MultiplyByCostFactor(common.RegexStringLengthCostFactor)
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// worst case size of result is that every char is returned as separate find result.
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return &checker.CallEstimate{CostEstimate: strCost.Multiply(regexCost), ResultSize: &checker.SizeEstimate{Min: 0, Max: sz.Max}}
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}
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case "cidr", "isIP", "isCIDR":
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|
if target != nil {
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sz := l.sizeEstimate(args[0])
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return &checker.CallEstimate{CostEstimate: sz.MultiplyByCostFactor(common.StringTraversalCostFactor)}
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}
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case "ip":
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if target != nil && len(args) >= 1 {
|
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if overloadId == "cidr_ip" {
|
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// The IP member of the CIDR object is just accessing a field.
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// Nominal cost.
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return &checker.CallEstimate{CostEstimate: checker.CostEstimate{Min: 1, Max: 1}}
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}
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sz := l.sizeEstimate(args[0])
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return &checker.CallEstimate{CostEstimate: sz.MultiplyByCostFactor(common.StringTraversalCostFactor)}
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} else if target != nil {
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// The IP member of a CIDR is a just accessing a field, nominal cost.
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return &checker.CallEstimate{CostEstimate: checker.CostEstimate{Min: 1, Max: 1}}
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}
|
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case "ip.isCanonical":
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if target != nil && len(args) >= 1 {
|
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sz := l.sizeEstimate(args[0])
|
|
// We have to parse the string and then compare the parsed string to the original string.
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|
// So we double the cost of parsing the string.
|
|
return &checker.CallEstimate{CostEstimate: sz.MultiplyByCostFactor(2 * common.StringTraversalCostFactor)}
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}
|
|
case "masked", "prefixLength", "family", "isUnspecified", "isLoopback", "isLinkLocalMulticast", "isLinkLocalUnicast", "isGlobalUnicast":
|
|
// IP and CIDR accessors are nominal cost.
|
|
return &checker.CallEstimate{CostEstimate: checker.CostEstimate{Min: 1, Max: 1}}
|
|
case "containsIP":
|
|
if target != nil && len(args) >= 1 {
|
|
// The base cost of the function is the cost of comparing two byte lists.
|
|
// The byte lists will be either ipv4 or ipv6 so will have a length of 4, or 16 bytes.
|
|
sz := checker.SizeEstimate{Min: 4, Max: 16}
|
|
|
|
// We have to compare the two strings to determine if the CIDR/IP is in the other CIDR.
|
|
ipCompCost := sz.Add(sz).MultiplyByCostFactor(common.StringTraversalCostFactor)
|
|
|
|
if overloadId == "cidr_contains_ip_string" {
|
|
// If we are comparing a string, we must parse the string to into the right type, so add the cost of traversing the string again.
|
|
ipCompCost = ipCompCost.Add(checker.CostEstimate(l.sizeEstimate(args[0])).MultiplyByCostFactor(common.StringTraversalCostFactor))
|
|
}
|
|
|
|
return &checker.CallEstimate{CostEstimate: ipCompCost}
|
|
}
|
|
case "containsCIDR":
|
|
if target != nil && len(args) >= 1 {
|
|
// The base cost of the function is the cost of comparing two byte lists.
|
|
// The byte lists will be either ipv4 or ipv6 so will have a length of 4, or 16 bytes.
|
|
sz := checker.SizeEstimate{Min: 4, Max: 16}
|
|
|
|
// We have to compare the two strings to determine if the CIDR/IP is in the other CIDR.
|
|
ipCompCost := sz.Add(sz).MultiplyByCostFactor(common.StringTraversalCostFactor)
|
|
|
|
// As we are comparing if a CIDR is within another CIDR, we first mask the base CIDR and
|
|
// also compare the CIDR bits.
|
|
// This has an additional cost of the length of the IP being traversed again, plus 1.
|
|
ipCompCost = ipCompCost.Add(sz.MultiplyByCostFactor(common.StringTraversalCostFactor))
|
|
ipCompCost = ipCompCost.Add(checker.CostEstimate{Min: 1, Max: 1})
|
|
|
|
if overloadId == "cidr_contains_cidr_string" {
|
|
// If we are comparing a string, we must parse the string to into the right type, so add the cost of traversing the string again.
|
|
ipCompCost = ipCompCost.Add(checker.CostEstimate(l.sizeEstimate(args[0])).MultiplyByCostFactor(common.StringTraversalCostFactor))
|
|
}
|
|
|
|
return &checker.CallEstimate{CostEstimate: ipCompCost}
|
|
}
|
|
case "quantity", "isQuantity":
|
|
if target != nil {
|
|
sz := l.sizeEstimate(args[0])
|
|
return &checker.CallEstimate{CostEstimate: sz.MultiplyByCostFactor(common.StringTraversalCostFactor)}
|
|
}
|
|
case "validate":
|
|
if target != nil {
|
|
sz := l.sizeEstimate(args[0])
|
|
return &checker.CallEstimate{CostEstimate: sz.MultiplyByCostFactor(common.StringTraversalCostFactor).MultiplyByCostFactor(cel.MaxNameFormatRegexSize * common.RegexStringLengthCostFactor)}
|
|
}
|
|
case "format.named":
|
|
return &checker.CallEstimate{CostEstimate: checker.CostEstimate{Min: 1, Max: 1}}
|
|
case "sign", "asInteger", "isInteger", "asApproximateFloat", "isGreaterThan", "isLessThan", "compareTo", "add", "sub":
|
|
return &checker.CallEstimate{CostEstimate: checker.CostEstimate{Min: 1, Max: 1}}
|
|
case "getScheme", "getHostname", "getHost", "getPort", "getEscapedPath", "getQuery":
|
|
// url accessors
|
|
return &checker.CallEstimate{CostEstimate: checker.CostEstimate{Min: 1, Max: 1}}
|
|
}
|
|
if panicOnUnknown && !knownUnhandledFunctions[function] {
|
|
panic(fmt.Errorf("EstimateCallCost: unhandled function %q, target %v, args %v", function, target, args))
|
|
}
|
|
return nil
|
|
}
|
|
|
|
func actualSize(value ref.Val) uint64 {
|
|
if sz, ok := value.(traits.Sizer); ok {
|
|
return uint64(sz.Size().(types.Int))
|
|
}
|
|
if panicOnUnknown {
|
|
// debug.PrintStack()
|
|
panic(fmt.Errorf("actualSize: non-sizer type %T", value))
|
|
}
|
|
return 1
|
|
}
|
|
|
|
func (l *CostEstimator) sizeEstimate(t checker.AstNode) checker.SizeEstimate {
|
|
if sz := t.ComputedSize(); sz != nil {
|
|
return *sz
|
|
}
|
|
if sz := l.EstimateSize(t); sz != nil {
|
|
return *sz
|
|
}
|
|
return checker.SizeEstimate{Min: 0, Max: math.MaxUint64}
|
|
}
|
|
|
|
func (l *CostEstimator) listElementNode(list checker.AstNode) checker.AstNode {
|
|
if params := list.Type().Parameters(); len(params) > 0 {
|
|
lt := params[0]
|
|
nodePath := list.Path()
|
|
if nodePath != nil {
|
|
// Provide path if we have it so that a OpenAPIv3 maxLength validation can be looked up, if it exists
|
|
// for this node.
|
|
path := make([]string, len(nodePath)+1)
|
|
copy(path, nodePath)
|
|
path[len(nodePath)] = "@items"
|
|
return &itemsNode{path: path, t: lt, expr: nil}
|
|
} else {
|
|
// Provide just the type if no path is available so that worst case size can be looked up based on type.
|
|
return &itemsNode{t: lt, expr: nil}
|
|
}
|
|
}
|
|
return nil
|
|
}
|
|
|
|
func (l *CostEstimator) EstimateSize(element checker.AstNode) *checker.SizeEstimate {
|
|
if l.SizeEstimator != nil {
|
|
return l.SizeEstimator.EstimateSize(element)
|
|
}
|
|
return nil
|
|
}
|
|
|
|
type itemsNode struct {
|
|
path []string
|
|
t *types.Type
|
|
expr ast.Expr
|
|
}
|
|
|
|
func (i *itemsNode) Path() []string {
|
|
return i.path
|
|
}
|
|
|
|
func (i *itemsNode) Type() *types.Type {
|
|
return i.t
|
|
}
|
|
|
|
func (i *itemsNode) Expr() ast.Expr {
|
|
return i.expr
|
|
}
|
|
|
|
func (i *itemsNode) ComputedSize() *checker.SizeEstimate {
|
|
return nil
|
|
}
|
|
|
|
var _ checker.AstNode = (*itemsNode)(nil)
|
|
|
|
// traversalCost computes the cost of traversing a ref.Val as a data tree.
|
|
func traversalCost(v ref.Val) uint64 {
|
|
// TODO: This could potentially be optimized by sampling maps and lists instead of traversing.
|
|
switch vt := v.(type) {
|
|
case types.String:
|
|
return uint64(float64(len(string(vt))) * common.StringTraversalCostFactor)
|
|
case types.Bytes:
|
|
return uint64(float64(len([]byte(vt))) * common.StringTraversalCostFactor)
|
|
case traits.Lister:
|
|
cost := uint64(0)
|
|
for it := vt.Iterator(); it.HasNext() == types.True; {
|
|
i := it.Next()
|
|
cost += traversalCost(i)
|
|
}
|
|
return cost
|
|
case traits.Mapper: // maps and objects
|
|
cost := uint64(0)
|
|
for it := vt.Iterator(); it.HasNext() == types.True; {
|
|
k := it.Next()
|
|
cost += traversalCost(k) + traversalCost(vt.Get(k))
|
|
}
|
|
return cost
|
|
default:
|
|
return 1
|
|
}
|
|
}
|