2020-05-27 18:28:00 +00:00
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package random
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import (
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"context"
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"crypto/rand"
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"fmt"
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"io"
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"math"
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"sort"
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"time"
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"unicode"
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"github.com/hashicorp/go-multierror"
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)
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var (
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LowercaseCharset = sortCharset("abcdefghijklmnopqrstuvwxyz")
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UppercaseCharset = sortCharset("ABCDEFGHIJKLMNOPQRSTUVWXYZ")
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NumericCharset = sortCharset("0123456789")
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FullSymbolCharset = sortCharset("!\"#$%&'()*+,-./:;<=>?@[\\]^_`{|}~")
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ShortSymbolCharset = sortCharset("-")
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AlphabeticCharset = sortCharset(UppercaseCharset + LowercaseCharset)
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AlphaNumericCharset = sortCharset(AlphabeticCharset + NumericCharset)
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AlphaNumericShortSymbolCharset = sortCharset(AlphaNumericCharset + ShortSymbolCharset)
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AlphaNumericFullSymbolCharset = sortCharset(AlphaNumericCharset + FullSymbolCharset)
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LowercaseRuneset = []rune(LowercaseCharset)
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UppercaseRuneset = []rune(UppercaseCharset)
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NumericRuneset = []rune(NumericCharset)
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FullSymbolRuneset = []rune(FullSymbolCharset)
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ShortSymbolRuneset = []rune(ShortSymbolCharset)
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AlphabeticRuneset = []rune(AlphabeticCharset)
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AlphaNumericRuneset = []rune(AlphaNumericCharset)
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AlphaNumericShortSymbolRuneset = []rune(AlphaNumericShortSymbolCharset)
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AlphaNumericFullSymbolRuneset = []rune(AlphaNumericFullSymbolCharset)
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// DefaultStringGenerator has reasonable default rules for generating strings
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2020-06-11 22:08:20 +00:00
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DefaultStringGenerator = &StringGenerator{
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2020-05-27 18:28:00 +00:00
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Length: 20,
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Rules: []Rule{
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CharsetRule{
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Charset: LowercaseRuneset,
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MinChars: 1,
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},
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CharsetRule{
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Charset: UppercaseRuneset,
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MinChars: 1,
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},
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CharsetRule{
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Charset: NumericRuneset,
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MinChars: 1,
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},
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CharsetRule{
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Charset: ShortSymbolRuneset,
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MinChars: 1,
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},
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},
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}
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)
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func sortCharset(chars string) string {
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r := runes(chars)
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sort.Sort(r)
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return string(r)
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}
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// StringGenerator generats random strings from the provided charset & adhering to a set of rules. The set of rules
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// are things like CharsetRule which requires a certain number of characters from a sub-charset.
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type StringGenerator struct {
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// Length of the string to generate.
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Length int `mapstructure:"length" json:"length"`
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// Rules the generated strings must adhere to.
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Rules serializableRules `mapstructure:"-" json:"rule"` // This is "rule" in JSON so it matches the HCL property type
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// CharsetRule to choose runes from. This is computed from the rules, not directly configurable
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charset runes
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}
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// Generate a random string from the charset and adhering to the provided rules.
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// The io.Reader is optional. If not provided, it will default to the reader from crypto/rand
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func (g *StringGenerator) Generate(ctx context.Context, rng io.Reader) (str string, err error) {
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if _, hasTimeout := ctx.Deadline(); !hasTimeout {
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var cancel func()
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ctx, cancel = context.WithTimeout(ctx, 1*time.Second) // Ensure there's a timeout on the context
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defer cancel()
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}
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// Ensure the generator is configured well since it may be manually created rather than parsed from HCL
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err = g.validateConfig()
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if err != nil {
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return "", err
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}
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LOOP:
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for {
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select {
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case <-ctx.Done():
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return "", fmt.Errorf("timed out generating string")
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default:
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str, err = g.generate(rng)
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if err != nil {
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return "", err
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}
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if str == "" {
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continue LOOP
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}
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return str, err
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}
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}
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}
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func (g *StringGenerator) generate(rng io.Reader) (str string, err error) {
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// If performance improvements need to be made, this can be changed to read a batch of
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// potential strings at once rather than one at a time. This will significantly
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// improve performance, but at the cost of added complexity.
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candidate, err := randomRunes(rng, g.charset, g.Length)
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if err != nil {
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return "", fmt.Errorf("unable to generate random characters: %w", err)
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}
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for _, rule := range g.Rules {
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if !rule.Pass(candidate) {
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return "", nil
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}
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}
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// Passed all rules
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return string(candidate), nil
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}
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const (
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// maxCharsetLen is the maximum length a charset is allowed to be when generating a candidate string.
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// This is the total number of numbers available for selecting an index out of the charset slice.
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maxCharsetLen = 256
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)
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// randomRunes creates a random string based on the provided charset. The charset is limited to 255 characters, but
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// could be expanded if needed. Expanding the maximum charset size will decrease performance because it will need to
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// combine bytes into a larger integer using binary.BigEndian.Uint16() function.
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func randomRunes(rng io.Reader, charset []rune, length int) (candidate []rune, err error) {
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if len(charset) == 0 {
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return nil, fmt.Errorf("no charset specified")
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}
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if len(charset) > maxCharsetLen {
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return nil, fmt.Errorf("charset is too long: limited to %d characters", math.MaxUint8)
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}
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if length <= 0 {
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return nil, fmt.Errorf("unable to generate a zero or negative length runeset")
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}
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// This can't always select indexes from [0-maxCharsetLen) because it could introduce bias to the character selection.
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// For instance, if the length of the charset is [a-zA-Z0-9-] (length of 63):
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// RNG ranges: [0-62][63-125][126-188][189-251] will equally select from the entirety of the charset. However,
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// the RNG values [252-255] will select the first 4 characters of the charset while ignoring the remaining 59.
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// This results in a bias towards the front of the charset.
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//
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// To avoid this, we determine the largest integer multiplier of the charset length that is <= maxCharsetLen
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// For instance, if the maxCharsetLen is 256 (the size of one byte) and the charset is length 63, the multiplier
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// equals 4:
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// 256/63 => 4.06
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// Trunc(4.06) => 4
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// Multiply by the charset length
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// Subtract 1 to account for 0-based counting and you get the max index value: 251
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maxAllowedRNGValue := (maxCharsetLen/len(charset))*len(charset) - 1
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// rngBufferMultiplier increases the size of the RNG buffer to account for lost
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// indexes due to the maxAllowedRNGValue
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rngBufferMultiplier := 1.0
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// Don't set a multiplier if we are able to use the entire range of indexes
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if maxAllowedRNGValue < maxCharsetLen {
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// Anything more complicated than an arbitrary percentage appears to have little practical performance benefit
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rngBufferMultiplier = 1.5
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}
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// Default to the standard crypto reader if one isn't provided
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if rng == nil {
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rng = rand.Reader
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}
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charsetLen := byte(len(charset))
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runes := make([]rune, 0, length)
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for len(runes) < length {
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// Generate a bunch of indexes
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data := make([]byte, int(float64(length)*rngBufferMultiplier))
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numBytes, err := rng.Read(data)
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if err != nil {
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return nil, err
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}
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// Append characters until either we're out of indexes or the length is long enough
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for i := 0; i < numBytes; i++ {
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// Be careful to ensure that maxAllowedRNGValue isn't >= 256 as it will overflow and this
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// comparison will prevent characters from being selected from the charset
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if data[i] > byte(maxAllowedRNGValue) {
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continue
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}
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index := data[i]
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if len(charset) != maxCharsetLen {
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index = index % charsetLen
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}
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r := charset[index]
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runes = append(runes, r)
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if len(runes) == length {
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break
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}
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}
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}
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return runes, nil
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}
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// validateConfig of the generator to ensure that we can successfully generate a string.
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func (g *StringGenerator) validateConfig() (err error) {
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merr := &multierror.Error{}
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// Ensure the sum of minimum lengths in the rules doesn't exceed the length specified
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minLen := getMinLength(g.Rules)
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if g.Length <= 0 {
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merr = multierror.Append(merr, fmt.Errorf("length must be > 0"))
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} else if g.Length < minLen {
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merr = multierror.Append(merr, fmt.Errorf("specified rules require at least %d characters but %d is specified", minLen, g.Length))
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}
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// Ensure we have a charset & all characters are printable
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if len(g.charset) == 0 {
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// Yes this is mutating the generator but this is done so we don't have to compute this on every generation
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g.charset = getChars(g.Rules)
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}
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if len(g.charset) == 0 {
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merr = multierror.Append(merr, fmt.Errorf("no charset specified"))
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} else {
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for _, r := range g.charset {
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if !unicode.IsPrint(r) {
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merr = multierror.Append(merr, fmt.Errorf("non-printable character in charset"))
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break
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}
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}
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}
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return merr.ErrorOrNil()
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}
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// getMinLength from the rules using the optional interface: `MinLength() int`
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func getMinLength(rules []Rule) (minLen int) {
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type minLengthProvider interface {
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MinLength() int
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}
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for _, rule := range rules {
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mlp, ok := rule.(minLengthProvider)
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if !ok {
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continue
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}
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minLen += mlp.MinLength()
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}
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return minLen
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}
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// getChars from the rules using the optional interface: `Chars() []rune`
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func getChars(rules []Rule) (chars []rune) {
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type charsetProvider interface {
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Chars() []rune
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}
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for _, rule := range rules {
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cp, ok := rule.(charsetProvider)
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if !ok {
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continue
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}
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chars = append(chars, cp.Chars()...)
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}
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return deduplicateRunes(chars)
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}
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// deduplicateRunes returns a new slice of sorted & de-duplicated runes
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func deduplicateRunes(original []rune) (deduped []rune) {
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if len(original) == 0 {
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return nil
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}
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m := map[rune]bool{}
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dedupedRunes := []rune(nil)
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for _, r := range original {
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if m[r] {
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continue
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}
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m[r] = true
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dedupedRunes = append(dedupedRunes, r)
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}
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// They don't have to be sorted, but this is being done to make the charset easier to visualize
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sort.Sort(runes(dedupedRunes))
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return dedupedRunes
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}
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