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487 lines
12 KiB
Go
487 lines
12 KiB
Go
// go-qrcode
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// Copyright 2014 Tom Harwood
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package qrcode
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import (
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"errors"
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"log"
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bitset "github.com/skip2/go-qrcode/bitset"
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)
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// Data encoding.
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//
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// The main data portion of a QR Code consists of one or more segments of data.
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// A segment consists of:
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//
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// - The segment Data Mode: numeric, alphanumeric, or byte.
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// - The length of segment in bits.
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// - Encoded data.
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//
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// For example, the string "123ZZ#!#!" may be represented as:
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//
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// [numeric, 3, "123"] [alphanumeric, 2, "ZZ"] [byte, 4, "#!#!"]
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//
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// Multiple data modes exist to minimise the size of encoded data. For example,
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// 8-bit bytes require 8 bits to encode each, but base 10 numeric data can be
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// encoded at a higher density of 3 numbers (e.g. 123) per 10 bits.
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//
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// Some data can be represented in multiple modes. Numeric data can be
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// represented in all three modes, whereas alphanumeric data (e.g. 'A') can be
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// represented in alphanumeric and byte mode.
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//
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// Starting a new segment (to use a different Data Mode) has a cost, the bits to
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// state the new segment Data Mode and length. To minimise each QR Code's symbol
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// size, an optimisation routine coalesces segment types where possible, to
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// reduce the encoded data length.
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//
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// There are several other data modes available (e.g. Kanji mode) which are not
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// implemented here.
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// A segment encoding mode.
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type dataMode uint8
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const (
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// Each dataMode is a subset of the subsequent dataMode:
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// dataModeNone < dataModeNumeric < dataModeAlphanumeric < dataModeByte
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//
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// This ordering is important for determining which data modes a character can
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// be encoded with. E.g. 'E' can be encoded in both dataModeAlphanumeric and
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// dataModeByte.
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dataModeNone dataMode = 1 << iota
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dataModeNumeric
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dataModeAlphanumeric
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dataModeByte
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)
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// dataModeString returns d as a short printable string.
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func dataModeString(d dataMode) string {
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switch d {
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case dataModeNone:
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return "none"
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case dataModeNumeric:
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return "numeric"
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case dataModeAlphanumeric:
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return "alphanumeric"
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case dataModeByte:
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return "byte"
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}
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return "unknown"
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}
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type dataEncoderType uint8
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const (
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dataEncoderType1To9 dataEncoderType = iota
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dataEncoderType10To26
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dataEncoderType27To40
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)
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// segment is a single segment of data.
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type segment struct {
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// Data Mode (e.g. numeric).
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dataMode dataMode
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// segment data (e.g. "abc").
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data []byte
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}
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// A dataEncoder encodes data for a particular QR Code version.
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type dataEncoder struct {
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// Minimum & maximum versions supported.
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minVersion int
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maxVersion int
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// Mode indicator bit sequences.
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numericModeIndicator *bitset.Bitset
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alphanumericModeIndicator *bitset.Bitset
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byteModeIndicator *bitset.Bitset
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// Character count lengths.
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numNumericCharCountBits int
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numAlphanumericCharCountBits int
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numByteCharCountBits int
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// The raw input data.
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data []byte
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// The data classified into unoptimised segments.
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actual []segment
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// The data classified into optimised segments.
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optimised []segment
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}
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// newDataEncoder constructs a dataEncoder.
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func newDataEncoder(t dataEncoderType) *dataEncoder {
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d := &dataEncoder{}
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switch t {
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case dataEncoderType1To9:
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d = &dataEncoder{
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minVersion: 1,
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maxVersion: 9,
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numericModeIndicator: bitset.New(b0, b0, b0, b1),
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alphanumericModeIndicator: bitset.New(b0, b0, b1, b0),
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byteModeIndicator: bitset.New(b0, b1, b0, b0),
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numNumericCharCountBits: 10,
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numAlphanumericCharCountBits: 9,
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numByteCharCountBits: 8,
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}
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case dataEncoderType10To26:
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d = &dataEncoder{
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minVersion: 10,
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maxVersion: 26,
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numericModeIndicator: bitset.New(b0, b0, b0, b1),
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alphanumericModeIndicator: bitset.New(b0, b0, b1, b0),
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byteModeIndicator: bitset.New(b0, b1, b0, b0),
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numNumericCharCountBits: 12,
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numAlphanumericCharCountBits: 11,
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numByteCharCountBits: 16,
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}
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case dataEncoderType27To40:
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d = &dataEncoder{
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minVersion: 27,
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maxVersion: 40,
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numericModeIndicator: bitset.New(b0, b0, b0, b1),
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alphanumericModeIndicator: bitset.New(b0, b0, b1, b0),
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byteModeIndicator: bitset.New(b0, b1, b0, b0),
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numNumericCharCountBits: 14,
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numAlphanumericCharCountBits: 13,
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numByteCharCountBits: 16,
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}
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default:
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log.Panic("Unknown dataEncoderType")
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}
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return d
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}
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// encode data as one or more segments and return the encoded data.
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//
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// The returned data does not include the terminator bit sequence.
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func (d *dataEncoder) encode(data []byte) (*bitset.Bitset, error) {
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d.data = data
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d.actual = nil
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d.optimised = nil
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if len(data) == 0 {
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return nil, errors.New("no data to encode")
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}
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// Classify data into unoptimised segments.
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highestRequiredMode := d.classifyDataModes()
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// Optimise segments.
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err := d.optimiseDataModes()
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if err != nil {
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return nil, err
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}
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// Check if a single byte encoded segment would be more efficient.
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optimizedLength := 0
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for _, s := range d.optimised {
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length, err := d.encodedLength(s.dataMode, len(s.data))
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if err != nil {
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return nil, err
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}
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optimizedLength += length
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}
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singleByteSegmentLength, err := d.encodedLength(highestRequiredMode, len(d.data))
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if err != nil {
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return nil, err
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}
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if singleByteSegmentLength <= optimizedLength {
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d.optimised = []segment{segment{dataMode: highestRequiredMode, data: d.data}}
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}
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// Encode data.
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encoded := bitset.New()
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for _, s := range d.optimised {
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d.encodeDataRaw(s.data, s.dataMode, encoded)
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}
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return encoded, nil
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}
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// classifyDataModes classifies the raw data into unoptimised segments.
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// e.g. "123ZZ#!#!" =>
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// [numeric, 3, "123"] [alphanumeric, 2, "ZZ"] [byte, 4, "#!#!"].
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//
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// Returns the highest data mode needed to encode the data. e.g. for a mixed
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// numeric/alphanumeric input, the highest is alphanumeric.
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//
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// dataModeNone < dataModeNumeric < dataModeAlphanumeric < dataModeByte
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func (d *dataEncoder) classifyDataModes() dataMode {
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var start int
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mode := dataModeNone
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highestRequiredMode := mode
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for i, v := range d.data {
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newMode := dataModeNone
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switch {
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case v >= 0x30 && v <= 0x39:
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newMode = dataModeNumeric
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case v == 0x20 || v == 0x24 || v == 0x25 || v == 0x2a || v == 0x2b || v ==
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0x2d || v == 0x2e || v == 0x2f || v == 0x3a || (v >= 0x41 && v <= 0x5a):
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newMode = dataModeAlphanumeric
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default:
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newMode = dataModeByte
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}
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if newMode != mode {
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if i > 0 {
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d.actual = append(d.actual, segment{dataMode: mode, data: d.data[start:i]})
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start = i
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}
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mode = newMode
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}
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if newMode > highestRequiredMode {
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highestRequiredMode = newMode
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}
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}
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d.actual = append(d.actual, segment{dataMode: mode, data: d.data[start:len(d.data)]})
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return highestRequiredMode
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}
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// optimiseDataModes optimises the list of segments to reduce the overall output
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// encoded data length.
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//
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// The algorithm coalesces adjacent segments. segments are only coalesced when
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// the Data Modes are compatible, and when the coalesced segment has a shorter
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// encoded length than separate segments.
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//
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// Multiple segments may be coalesced. For example a string of alternating
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// alphanumeric/numeric segments ANANANANA can be optimised to just A.
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func (d *dataEncoder) optimiseDataModes() error {
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for i := 0; i < len(d.actual); {
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mode := d.actual[i].dataMode
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numChars := len(d.actual[i].data)
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j := i + 1
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for j < len(d.actual) {
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nextNumChars := len(d.actual[j].data)
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nextMode := d.actual[j].dataMode
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if nextMode > mode {
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break
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}
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coalescedLength, err := d.encodedLength(mode, numChars+nextNumChars)
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if err != nil {
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return err
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}
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seperateLength1, err := d.encodedLength(mode, numChars)
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if err != nil {
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return err
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}
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seperateLength2, err := d.encodedLength(nextMode, nextNumChars)
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if err != nil {
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return err
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}
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if coalescedLength < seperateLength1+seperateLength2 {
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j++
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numChars += nextNumChars
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} else {
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break
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}
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}
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optimised := segment{dataMode: mode,
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data: make([]byte, 0, numChars)}
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for k := i; k < j; k++ {
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optimised.data = append(optimised.data, d.actual[k].data...)
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}
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d.optimised = append(d.optimised, optimised)
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i = j
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}
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return nil
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}
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// encodeDataRaw encodes data in dataMode. The encoded data is appended to
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// encoded.
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func (d *dataEncoder) encodeDataRaw(data []byte, dataMode dataMode, encoded *bitset.Bitset) {
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modeIndicator := d.modeIndicator(dataMode)
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charCountBits := d.charCountBits(dataMode)
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// Append mode indicator.
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encoded.Append(modeIndicator)
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// Append character count.
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encoded.AppendUint32(uint32(len(data)), charCountBits)
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// Append data.
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switch dataMode {
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case dataModeNumeric:
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for i := 0; i < len(data); i += 3 {
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charsRemaining := len(data) - i
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var value uint32
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bitsUsed := 1
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for j := 0; j < charsRemaining && j < 3; j++ {
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value *= 10
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value += uint32(data[i+j] - 0x30)
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bitsUsed += 3
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}
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encoded.AppendUint32(value, bitsUsed)
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}
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case dataModeAlphanumeric:
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for i := 0; i < len(data); i += 2 {
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charsRemaining := len(data) - i
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var value uint32
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for j := 0; j < charsRemaining && j < 2; j++ {
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value *= 45
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value += encodeAlphanumericCharacter(data[i+j])
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}
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bitsUsed := 6
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if charsRemaining > 1 {
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bitsUsed = 11
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}
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encoded.AppendUint32(value, bitsUsed)
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}
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case dataModeByte:
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for _, b := range data {
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encoded.AppendByte(b, 8)
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}
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}
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}
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// modeIndicator returns the segment header bits for a segment of type dataMode.
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func (d *dataEncoder) modeIndicator(dataMode dataMode) *bitset.Bitset {
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switch dataMode {
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case dataModeNumeric:
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return d.numericModeIndicator
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case dataModeAlphanumeric:
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return d.alphanumericModeIndicator
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case dataModeByte:
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return d.byteModeIndicator
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default:
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log.Panic("Unknown data mode")
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}
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return nil
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}
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// charCountBits returns the number of bits used to encode the length of a data
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// segment of type dataMode.
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func (d *dataEncoder) charCountBits(dataMode dataMode) int {
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switch dataMode {
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case dataModeNumeric:
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return d.numNumericCharCountBits
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case dataModeAlphanumeric:
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return d.numAlphanumericCharCountBits
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case dataModeByte:
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return d.numByteCharCountBits
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default:
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log.Panic("Unknown data mode")
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}
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return 0
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}
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// encodedLength returns the number of bits required to encode n symbols in
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// dataMode.
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//
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// The number of bits required is affected by:
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// - QR code type - Mode Indicator length.
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// - Data mode - number of bits used to represent data length.
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// - Data mode - how the data is encoded.
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// - Number of symbols encoded.
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//
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// An error is returned if the mode is not supported, or the length requested is
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// too long to be represented.
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func (d *dataEncoder) encodedLength(dataMode dataMode, n int) (int, error) {
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modeIndicator := d.modeIndicator(dataMode)
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charCountBits := d.charCountBits(dataMode)
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if modeIndicator == nil {
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return 0, errors.New("mode not supported")
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}
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maxLength := (1 << uint8(charCountBits)) - 1
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if n > maxLength {
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return 0, errors.New("length too long to be represented")
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}
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length := modeIndicator.Len() + charCountBits
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switch dataMode {
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case dataModeNumeric:
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length += 10 * (n / 3)
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if n%3 != 0 {
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length += 1 + 3*(n%3)
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}
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case dataModeAlphanumeric:
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length += 11 * (n / 2)
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length += 6 * (n % 2)
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case dataModeByte:
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length += 8 * n
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}
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return length, nil
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}
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// encodeAlphanumericChar returns the QR Code encoded value of v.
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//
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// v must be a QR Code defined alphanumeric character: 0-9, A-Z, SP, $%*+-./ or
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// :. The characters are mapped to values in the range 0-44 respectively.
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func encodeAlphanumericCharacter(v byte) uint32 {
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c := uint32(v)
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switch {
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case c >= '0' && c <= '9':
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// 0-9 encoded as 0-9.
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return c - '0'
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case c >= 'A' && c <= 'Z':
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// A-Z encoded as 10-35.
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return c - 'A' + 10
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case c == ' ':
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return 36
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case c == '$':
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return 37
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case c == '%':
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return 38
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case c == '*':
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return 39
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case c == '+':
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return 40
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case c == '-':
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return 41
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case c == '.':
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return 42
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case c == '/':
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return 43
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case c == ':':
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return 44
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default:
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log.Panicf("encodeAlphanumericCharacter() with non alphanumeric char %v.", v)
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}
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return 0
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}
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