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IdnMapping.cs
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IdnMapping.cs
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// Licensed to the .NET Foundation under one or more agreements.
// The .NET Foundation licenses this file to you under the MIT license.
// This file contains the IDN functions and implementation.
//
// This allows encoding of non-ASCII domain names in a "punycode" form,
// for example:
//
// \u5B89\u5BA4\u5948\u7F8E\u6075-with-SUPER-MONKEYS
//
// is encoded as:
//
// xn---with-SUPER-MONKEYS-pc58ag80a8qai00g7n9n
//
// Additional options are provided to allow unassigned IDN characters and
// to validate according to the Std3ASCII Rules (like DNS names).
//
// There are also rules regarding bidirectionality of text and the length
// of segments.
//
// For additional rules see also:
// RFC 3490 - Internationalizing Domain Names in Applications (IDNA)
// RFC 3491 - Nameprep: A Stringprep Profile for Internationalized Domain Names (IDN)
// RFC 3492 - Punycode: A Bootstring encoding of Unicode for Internationalized Domain Names in Applications (IDNA)
using System.Diagnostics;
using System.Diagnostics.CodeAnalysis;
using System.Runtime.CompilerServices;
using System.Text;
namespace System.Globalization
{
// IdnMapping class used to map names to Punycode
public sealed partial class IdnMapping
{
private bool _allowUnassigned;
private bool _useStd3AsciiRules;
public IdnMapping()
{
}
public bool AllowUnassigned
{
get => _allowUnassigned;
set => _allowUnassigned = value;
}
public bool UseStd3AsciiRules
{
get => _useStd3AsciiRules;
set => _useStd3AsciiRules = value;
}
// Gets ASCII (Punycode) version of the string
public string GetAscii(string unicode) =>
GetAscii(unicode, 0);
public string GetAscii(string unicode, int index)
{
ArgumentNullException.ThrowIfNull(unicode);
return GetAscii(unicode, index, unicode.Length - index);
}
public string GetAscii(string unicode, int index, int count)
{
ArgumentNullException.ThrowIfNull(unicode);
ArgumentOutOfRangeException.ThrowIfNegative(index);
ArgumentOutOfRangeException.ThrowIfNegative(count);
if (index > unicode.Length)
throw new ArgumentOutOfRangeException(nameof(index), SR.ArgumentOutOfRange_IndexMustBeLessOrEqual);
if (index > unicode.Length - count)
throw new ArgumentOutOfRangeException(nameof(unicode), SR.ArgumentOutOfRange_IndexCountBuffer);
if (count == 0)
{
throw new ArgumentException(SR.Argument_IdnBadLabelSize, nameof(unicode));
}
if (unicode[index + count - 1] == 0)
{
throw new ArgumentException(SR.Format(SR.Argument_InvalidCharSequence, index + count - 1), nameof(unicode));
}
if (GlobalizationMode.Invariant)
{
return GetAsciiInvariant(unicode, index, count);
}
unsafe
{
fixed (char* pUnicode = unicode)
{
return GlobalizationMode.UseNls ?
NlsGetAsciiCore(unicode, pUnicode + index, count) :
IcuGetAsciiCore(unicode, pUnicode + index, count);
}
}
}
// Gets Unicode version of the string. Normalized and limited to IDNA characters.
public string GetUnicode(string ascii) =>
GetUnicode(ascii, 0);
public string GetUnicode(string ascii, int index)
{
ArgumentNullException.ThrowIfNull(ascii);
return GetUnicode(ascii, index, ascii.Length - index);
}
public string GetUnicode(string ascii, int index, int count)
{
ArgumentNullException.ThrowIfNull(ascii);
ArgumentOutOfRangeException.ThrowIfNegative(index);
ArgumentOutOfRangeException.ThrowIfNegative(count);
if (index > ascii.Length)
throw new ArgumentOutOfRangeException(nameof(index), SR.ArgumentOutOfRange_IndexMustBeLessOrEqual);
if (index > ascii.Length - count)
throw new ArgumentOutOfRangeException(nameof(ascii), SR.ArgumentOutOfRange_IndexCountBuffer);
// This is a case (i.e. explicitly null-terminated input) where behavior in .NET and Win32 intentionally differ.
// The .NET APIs should (and did in v4.0 and earlier) throw an ArgumentException on input that includes a terminating null.
// The Win32 APIs fail on an embedded null, but not on a terminating null.
if (count > 0 && ascii[index + count - 1] == (char)0)
throw new ArgumentException(SR.Argument_IdnBadPunycode, nameof(ascii));
if (GlobalizationMode.Invariant)
{
return GetUnicodeInvariant(ascii, index, count);
}
unsafe
{
fixed (char* pAscii = ascii)
{
return GlobalizationMode.UseNls ?
NlsGetUnicodeCore(ascii, pAscii + index, count) :
IcuGetUnicodeCore(ascii, pAscii + index, count);
}
}
}
public override bool Equals([NotNullWhen(true)] object? obj) =>
obj is IdnMapping that &&
_allowUnassigned == that._allowUnassigned &&
_useStd3AsciiRules == that._useStd3AsciiRules;
public override int GetHashCode() =>
(_allowUnassigned ? 100 : 200) + (_useStd3AsciiRules ? 1000 : 2000);
[MethodImpl(MethodImplOptions.AggressiveInlining)]
private static unsafe string GetStringForOutput(string originalString, char* input, int inputLength, char* output, int outputLength)
{
Debug.Assert(inputLength > 0);
if (originalString.Length == inputLength &&
inputLength == outputLength &&
Ordinal.EqualsIgnoreCase(ref *input, ref *output, inputLength))
{
return originalString;
}
return new string(output, 0, outputLength);
}
//
// Invariant implementation
//
private const char c_delimiter = '-';
private const string c_strAcePrefix = "xn--";
private const int c_labelLimit = 63; // Not including dots
private const int c_defaultNameLimit = 255; // Including dots
private const int c_initialN = 0x80;
private const int c_maxint = 0x7ffffff;
private const int c_initialBias = 72;
private const int c_punycodeBase = 36;
private const int c_tmin = 1;
private const int c_tmax = 26;
private const int c_skew = 38;
private const int c_damp = 700;
private string GetAsciiInvariant(string unicode, int index, int count)
{
if (index > 0 || count < unicode.Length)
{
unicode = unicode.Substring(index, count);
}
// Check for ASCII only string, which will be unchanged
if (ValidateStd3AndAscii(unicode, UseStd3AsciiRules, true))
{
return unicode;
}
// Cannot be null terminated (normalization won't help us with this one, and
// may have returned false before checking the whole string above)
Debug.Assert(count >= 1, "[IdnMapping.GetAscii] Expected 0 length strings to fail before now.");
if (unicode[^1] <= 0x1f)
{
throw new ArgumentException(SR.Format(SR.Argument_InvalidCharSequence, unicode.Length - 1), nameof(unicode));
}
// May need to check Std3 rules again for non-ascii
if (UseStd3AsciiRules)
{
ValidateStd3AndAscii(unicode, true, false);
}
// Go ahead and encode it
return PunycodeEncode(unicode);
}
// See if we're only ASCII
private static bool ValidateStd3AndAscii(string unicode, bool bUseStd3, bool bCheckAscii)
{
// If its empty, then its too small
if (unicode.Length == 0)
throw new ArgumentException(SR.Argument_IdnBadLabelSize, nameof(unicode));
int iLastDot = -1;
// Loop the whole string
for (int i = 0; i < unicode.Length; i++)
{
// Aren't allowing control chars (or 7f, but idn tables catch that, they don't catch \0 at end though)
if (unicode[i] <= 0x1f)
{
throw new ArgumentException(SR.Format(SR.Argument_InvalidCharSequence, i), nameof(unicode));
}
// If its Unicode or a control character, return false (non-ascii)
if (bCheckAscii && unicode[i] >= 0x7f)
return false;
// Check for dots
if (IsDot(unicode[i]))
{
// Can't have 2 dots in a row
if (i == iLastDot + 1)
throw new ArgumentException(SR.Argument_IdnBadLabelSize, nameof(unicode));
// If its too far between dots then fail
if (i - iLastDot > c_labelLimit + 1)
throw new ArgumentException(SR.Argument_IdnBadLabelSize, nameof(unicode));
// If validating Std3, then char before dot can't be - char
if (bUseStd3 && i > 0)
ValidateStd3(unicode[i - 1], true);
// Remember where the last dot is
iLastDot = i;
continue;
}
// If necessary, make sure its a valid std3 character
if (bUseStd3)
{
ValidateStd3(unicode[i], i == iLastDot + 1);
}
}
// If we never had a dot, then we need to be shorter than the label limit
if (iLastDot == -1 && unicode.Length > c_labelLimit)
throw new ArgumentException(SR.Argument_IdnBadLabelSize, nameof(unicode));
// Need to validate entire string length, 1 shorter if last char wasn't a dot
if (unicode.Length > c_defaultNameLimit - (IsDot(unicode[^1]) ? 0 : 1))
throw new ArgumentException(SR.Format(SR.Argument_IdnBadNameSize,
c_defaultNameLimit - (IsDot(unicode[^1]) ? 0 : 1)), nameof(unicode));
// If last char wasn't a dot we need to check for trailing -
if (bUseStd3 && !IsDot(unicode[^1]))
ValidateStd3(unicode[^1], true);
return true;
}
/* PunycodeEncode() converts Unicode to Punycode. The input */
/* is represented as an array of Unicode code points (not code */
/* units; surrogate pairs are not allowed), and the output */
/* will be represented as an array of ASCII code points. The */
/* output string is *not* null-terminated; it will contain */
/* zeros if and only if the input contains zeros. (Of course */
/* the caller can leave room for a terminator and add one if */
/* needed.) The input_length is the number of code points in */
/* the input. The output_length is an in/out argument: the */
/* caller passes in the maximum number of code points that it */
/* can receive, and on successful return it will contain the */
/* number of code points actually output. The case_flags array */
/* holds input_length boolean values, where nonzero suggests that */
/* the corresponding Unicode character be forced to uppercase */
/* after being decoded (if possible), and zero suggests that */
/* it be forced to lowercase (if possible). ASCII code points */
/* are encoded literally, except that ASCII letters are forced */
/* to uppercase or lowercase according to the corresponding */
/* uppercase flags. If case_flags is a null pointer then ASCII */
/* letters are left as they are, and other code points are */
/* treated as if their uppercase flags were zero. The return */
/* value can be any of the punycode_status values defined above */
/* except punycode_bad_input; if not punycode_success, then */
/* output_size and output might contain garbage. */
private static string PunycodeEncode(string unicode)
{
// 0 length strings aren't allowed
if (unicode.Length == 0)
throw new ArgumentException(SR.Argument_IdnBadLabelSize, nameof(unicode));
StringBuilder output = new StringBuilder(unicode.Length);
int iNextDot = 0;
int iAfterLastDot = 0;
int iOutputAfterLastDot = 0;
// Find the next dot
while (iNextDot < unicode.Length)
{
// Legal "dot" separators (i.e: . in www.microsoft.com)
const string DotSeparators = ".\u3002\uFF0E\uFF61";
// Find end of this segment
iNextDot = unicode.AsSpan(iAfterLastDot).IndexOfAny(DotSeparators);
iNextDot = iNextDot < 0 ? unicode.Length : iNextDot + iAfterLastDot;
// Only allowed to have empty . section at end (www.microsoft.com.)
if (iNextDot == iAfterLastDot)
{
// Only allowed to have empty sections as trailing .
if (iNextDot != unicode.Length)
throw new ArgumentException(SR.Argument_IdnBadLabelSize, nameof(unicode));
// Last dot, stop
break;
}
// We'll need an Ace prefix
output.Append(c_strAcePrefix);
// Everything resets every segment.
bool bRightToLeft = false;
// Check for RTL. If right-to-left, then 1st & last chars must be RTL
StrongBidiCategory eBidi = CharUnicodeInfo.GetBidiCategory(unicode, iAfterLastDot);
if (eBidi == StrongBidiCategory.StrongRightToLeft)
{
// It has to be right to left.
bRightToLeft = true;
// Check last char
int iTest = iNextDot - 1;
if (char.IsLowSurrogate(unicode, iTest))
{
iTest--;
}
eBidi = CharUnicodeInfo.GetBidiCategory(unicode, iTest);
if (eBidi != StrongBidiCategory.StrongRightToLeft)
{
// Oops, last wasn't RTL, last should be RTL if first is RTL
throw new ArgumentException(SR.Argument_IdnBadBidi, nameof(unicode));
}
}
// Handle the basic code points
int basicCount;
int numProcessed = 0; // Num code points that have been processed so far (this segment)
for (basicCount = iAfterLastDot; basicCount < iNextDot; basicCount++)
{
// Can't be lonely surrogate because it would've thrown in normalization
Debug.Assert(!char.IsLowSurrogate(unicode, basicCount), "[IdnMapping.punycode_encode]Unexpected low surrogate");
// Double check our bidi rules
StrongBidiCategory testBidi = CharUnicodeInfo.GetBidiCategory(unicode, basicCount);
// If we're RTL, we can't have LTR chars
if (bRightToLeft && testBidi == StrongBidiCategory.StrongLeftToRight)
{
// Oops, throw error
throw new ArgumentException(SR.Argument_IdnBadBidi, nameof(unicode));
}
// If we're not RTL we can't have RTL chars
if (!bRightToLeft && testBidi == StrongBidiCategory.StrongRightToLeft)
{
// Oops, throw error
throw new ArgumentException(SR.Argument_IdnBadBidi, nameof(unicode));
}
// If its basic then add it
if (Basic(unicode[basicCount]))
{
output.Append(EncodeBasic(unicode[basicCount]));
numProcessed++;
}
// If its a surrogate, skip the next since our bidi category tester doesn't handle it.
else if (char.IsSurrogatePair(unicode, basicCount))
basicCount++;
}
int numBasicCodePoints = numProcessed; // number of basic code points
// Stop if we ONLY had basic code points
if (numBasicCodePoints == iNextDot - iAfterLastDot)
{
// Get rid of xn-- and this segments done
output.Remove(iOutputAfterLastDot, c_strAcePrefix.Length);
}
else
{
// If it has some non-basic code points the input cannot start with xn--
if (unicode.AsSpan(iAfterLastDot).StartsWith(c_strAcePrefix, StringComparison.OrdinalIgnoreCase))
throw new ArgumentException(SR.Argument_IdnBadPunycode, nameof(unicode));
// Need to do ACE encoding
int numSurrogatePairs = 0; // number of surrogate pairs so far
// Add a delimiter (-) if we had any basic code points (between basic and encoded pieces)
if (numBasicCodePoints > 0)
{
output.Append(c_delimiter);
}
// Initialize the state
int n = c_initialN;
int delta = 0;
int bias = c_initialBias;
// Main loop
while (numProcessed < (iNextDot - iAfterLastDot))
{
/* All non-basic code points < n have been */
/* handled already. Find the next larger one: */
int j;
int m;
int test;
for (m = c_maxint, j = iAfterLastDot;
j < iNextDot;
j += IsSupplementary(test) ? 2 : 1)
{
test = char.ConvertToUtf32(unicode, j);
if (test >= n && test < m) m = test;
}
/* Increase delta enough to advance the decoder's */
/* <n,i> state to <m,0>, but guard against overflow: */
delta += (int)((m - n) * ((numProcessed - numSurrogatePairs) + 1));
Debug.Assert(delta > 0, "[IdnMapping.cs]1 punycode_encode - delta overflowed int");
n = m;
for (j = iAfterLastDot; j < iNextDot; j += IsSupplementary(test) ? 2 : 1)
{
// Make sure we're aware of surrogates
test = char.ConvertToUtf32(unicode, j);
// Adjust for character position (only the chars in our string already, some
// haven't been processed.
if (test < n)
{
delta++;
Debug.Assert(delta > 0, "[IdnMapping.cs]2 punycode_encode - delta overflowed int");
}
if (test == n)
{
// Represent delta as a generalized variable-length integer:
int q, k;
for (q = delta, k = c_punycodeBase; ; k += c_punycodeBase)
{
int t = k <= bias ? c_tmin : k >= bias + c_tmax ? c_tmax : k - bias;
if (q < t) break;
Debug.Assert(c_punycodeBase != t, "[IdnMapping.punycode_encode]Expected c_punycodeBase (36) to be != t");
output.Append(EncodeDigit(t + (q - t) % (c_punycodeBase - t)));
q = (q - t) / (c_punycodeBase - t);
}
output.Append(EncodeDigit(q));
bias = Adapt(delta, (numProcessed - numSurrogatePairs) + 1, numProcessed == numBasicCodePoints);
delta = 0;
numProcessed++;
if (IsSupplementary(m))
{
numProcessed++;
numSurrogatePairs++;
}
}
}
++delta;
++n;
Debug.Assert(delta > 0, "[IdnMapping.cs]3 punycode_encode - delta overflowed int");
}
}
// Make sure its not too big
if (output.Length - iOutputAfterLastDot > c_labelLimit)
throw new ArgumentException(SR.Argument_IdnBadLabelSize, nameof(unicode));
// Done with this segment, add dot if necessary
if (iNextDot != unicode.Length)
output.Append('.');
iAfterLastDot = iNextDot + 1;
iOutputAfterLastDot = output.Length;
}
// Throw if we're too long
if (output.Length > c_defaultNameLimit - (IsDot(unicode[^1]) ? 0 : 1))
throw new ArgumentException(SR.Format(SR.Argument_IdnBadNameSize,
c_defaultNameLimit - (IsDot(unicode[^1]) ? 0 : 1)), nameof(unicode));
// Return our output string
return output.ToString();
}
// Is it a dot?
// are we U+002E (., full stop), U+3002 (ideographic full stop), U+FF0E (fullwidth full stop), or
// U+FF61 (halfwidth ideographic full stop).
// Note: IDNA Normalization gets rid of dots now, but testing for last dot is before normalization
private static bool IsDot(char c) =>
c == '.' || c == '\u3002' || c == '\uFF0E' || c == '\uFF61';
private static bool IsSupplementary(int cTest) =>
cTest >= 0x10000;
private static bool Basic(uint cp) =>
// Is it in ASCII range?
cp < 0x80;
// Validate Std3 rules for a character
private static void ValidateStd3(char c, bool bNextToDot)
{
// Check for illegal characters
if (c <= ',' || c == '/' || (c >= ':' && c <= '@') || // Lots of characters not allowed
(c >= '[' && c <= '`') || (c >= '{' && c <= (char)0x7F) ||
(c == '-' && bNextToDot))
throw new ArgumentException(SR.Format(SR.Argument_IdnBadStd3, c), nameof(c));
}
private string GetUnicodeInvariant(string ascii, int index, int count)
{
if (index > 0 || count < ascii.Length)
{
// We're only using part of the string
ascii = ascii.Substring(index, count);
}
// Convert Punycode to Unicode
string strUnicode = PunycodeDecode(ascii);
// Output name MUST obey IDNA rules & round trip (casing differences are allowed)
if (!ascii.Equals(GetAscii(strUnicode), StringComparison.OrdinalIgnoreCase))
throw new ArgumentException(SR.Argument_IdnIllegalName, nameof(ascii));
return strUnicode;
}
/* PunycodeDecode() converts Punycode to Unicode. The input is */
/* represented as an array of ASCII code points, and the output */
/* will be represented as an array of Unicode code points. The */
/* input_length is the number of code points in the input. The */
/* output_length is an in/out argument: the caller passes in */
/* the maximum number of code points that it can receive, and */
/* on successful return it will contain the actual number of */
/* code points output. The case_flags array needs room for at */
/* least output_length values, or it can be a null pointer if the */
/* case information is not needed. A nonzero flag suggests that */
/* the corresponding Unicode character be forced to uppercase */
/* by the caller (if possible), while zero suggests that it be */
/* forced to lowercase (if possible). ASCII code points are */
/* output already in the proper case, but their flags will be set */
/* appropriately so that applying the flags would be harmless. */
/* The return value can be any of the punycode_status values */
/* defined above; if not punycode_success, then output_length, */
/* output, and case_flags might contain garbage. On success, the */
/* decoder will never need to write an output_length greater than */
/* input_length, because of how the encoding is defined. */
private static string PunycodeDecode(string ascii)
{
// 0 length strings aren't allowed
if (ascii.Length == 0)
throw new ArgumentException(SR.Argument_IdnBadLabelSize, nameof(ascii));
// Throw if we're too long
if (ascii.Length > c_defaultNameLimit - (IsDot(ascii[^1]) ? 0 : 1))
throw new ArgumentException(SR.Format(SR.Argument_IdnBadNameSize,
c_defaultNameLimit - (IsDot(ascii[^1]) ? 0 : 1)), nameof(ascii));
// output stringbuilder
StringBuilder output = new StringBuilder(ascii.Length);
// Dot searching
int iNextDot = 0;
int iAfterLastDot = 0;
int iOutputAfterLastDot = 0;
while (iNextDot < ascii.Length)
{
// Find end of this segment
iNextDot = ascii.IndexOf('.', iAfterLastDot);
if (iNextDot < 0 || iNextDot > ascii.Length)
iNextDot = ascii.Length;
// Only allowed to have empty . section at end (www.microsoft.com.)
if (iNextDot == iAfterLastDot)
{
// Only allowed to have empty sections as trailing .
if (iNextDot != ascii.Length)
throw new ArgumentException(SR.Argument_IdnBadLabelSize, nameof(ascii));
// Last dot, stop
break;
}
// In either case it can't be bigger than segment size
if (iNextDot - iAfterLastDot > c_labelLimit)
throw new ArgumentException(SR.Argument_IdnBadLabelSize, nameof(ascii));
// See if this section's ASCII or ACE
if (ascii.Length < c_strAcePrefix.Length + iAfterLastDot ||
string.Compare(ascii, iAfterLastDot, c_strAcePrefix, 0, c_strAcePrefix.Length, StringComparison.OrdinalIgnoreCase) != 0)
{
// Its ASCII, copy it
output.Append(ascii, iAfterLastDot, iNextDot - iAfterLastDot);
}
else
{
// Not ASCII, bump up iAfterLastDot to be after ACE Prefix
iAfterLastDot += c_strAcePrefix.Length;
// Get number of basic code points (where delimiter is)
// numBasicCodePoints < 0 if there're no basic code points
int iTemp = ascii.LastIndexOf(c_delimiter, iNextDot - 1);
// Trailing - not allowed
if (iTemp == iNextDot - 1)
throw new ArgumentException(SR.Argument_IdnBadPunycode, nameof(ascii));
int numBasicCodePoints;
if (iTemp <= iAfterLastDot)
numBasicCodePoints = 0;
else
{
numBasicCodePoints = iTemp - iAfterLastDot;
// Copy all the basic code points, making sure they're all in the allowed range,
// and losing the casing for all of them.
for (int copyAscii = iAfterLastDot; copyAscii < iAfterLastDot + numBasicCodePoints; copyAscii++)
{
// Make sure we don't allow unicode in the ascii part
if (ascii[copyAscii] > 0x7f)
throw new ArgumentException(SR.Argument_IdnBadPunycode, nameof(ascii));
// When appending make sure they get lower cased
output.Append((char)(char.IsAsciiLetterUpper(ascii[copyAscii]) ? ascii[copyAscii] - 'A' + 'a' : ascii[copyAscii]));
}
}
// Get ready for main loop. Start at beginning if we didn't have any
// basic code points, otherwise start after the -.
// asciiIndex will be next character to read from ascii
int asciiIndex = iAfterLastDot + (numBasicCodePoints > 0 ? numBasicCodePoints + 1 : 0);
// initialize our state
int n = c_initialN;
int bias = c_initialBias;
int i = 0;
int w, k;
// no Supplementary characters yet
int numSurrogatePairs = 0;
// Main loop, read rest of ascii
while (asciiIndex < iNextDot)
{
/* Decode a generalized variable-length integer into delta, */
/* which gets added to i. The overflow checking is easier */
/* if we increase i as we go, then subtract off its starting */
/* value at the end to obtain delta. */
int oldi = i;
for (w = 1, k = c_punycodeBase; ; k += c_punycodeBase)
{
// Check to make sure we aren't overrunning our ascii string
if (asciiIndex >= iNextDot)
throw new ArgumentException(SR.Argument_IdnBadPunycode, nameof(ascii));
// decode the digit from the next char
int digit = DecodeDigit(ascii[asciiIndex++]);
Debug.Assert(w > 0, "[IdnMapping.punycode_decode]Expected w > 0");
if (digit > (c_maxint - i) / w)
throw new ArgumentException(SR.Argument_IdnBadPunycode, nameof(ascii));
i += (int)(digit * w);
int t = k <= bias ? c_tmin : k >= bias + c_tmax ? c_tmax : k - bias;
if (digit < t)
break;
Debug.Assert(c_punycodeBase != t, "[IdnMapping.punycode_decode]Expected t != c_punycodeBase (36)");
if (w > c_maxint / (c_punycodeBase - t))
throw new ArgumentException(SR.Argument_IdnBadPunycode, nameof(ascii));
w *= (c_punycodeBase - t);
}
bias = Adapt(i - oldi, (output.Length - iOutputAfterLastDot - numSurrogatePairs) + 1, oldi == 0);
/* i was supposed to wrap around from output.Length to 0, */
/* incrementing n each time, so we'll fix that now: */
Debug.Assert((output.Length - iOutputAfterLastDot - numSurrogatePairs) + 1 > 0,
"[IdnMapping.punycode_decode]Expected to have added > 0 characters this segment");
if (i / ((output.Length - iOutputAfterLastDot - numSurrogatePairs) + 1) > c_maxint - n)
throw new ArgumentException(SR.Argument_IdnBadPunycode, nameof(ascii));
n += (int)(i / (output.Length - iOutputAfterLastDot - numSurrogatePairs + 1));
i %= (output.Length - iOutputAfterLastDot - numSurrogatePairs + 1);
// Make sure n is legal
if (n < 0 || n > 0x10ffff || (n >= 0xD800 && n <= 0xDFFF))
throw new ArgumentException(SR.Argument_IdnBadPunycode, nameof(ascii));
// insert n at position i of the output: Really tricky if we have surrogates
int iUseInsertLocation;
string strTemp = char.ConvertFromUtf32(n);
// If we have supplimentary characters
if (numSurrogatePairs > 0)
{
// Hard way, we have supplimentary characters
int iCount;
for (iCount = i, iUseInsertLocation = iOutputAfterLastDot; iCount > 0; iCount--, iUseInsertLocation++)
{
// If its a surrogate, we have to go one more
if (iUseInsertLocation >= output.Length)
throw new ArgumentException(SR.Argument_IdnBadPunycode, nameof(ascii));
if (char.IsSurrogate(output[iUseInsertLocation]))
iUseInsertLocation++;
}
}
else
{
// No Supplementary chars yet, just add i
iUseInsertLocation = iOutputAfterLastDot + i;
}
// Insert it
output.Insert(iUseInsertLocation, strTemp);
// If it was a surrogate increment our counter
if (IsSupplementary(n))
numSurrogatePairs++;
// Index gets updated
i++;
}
// Do BIDI testing
bool bRightToLeft = false;
// Check for RTL. If right-to-left, then 1st & last chars must be RTL
StrongBidiCategory eBidi = CharUnicodeInfo.GetBidiCategory(output, iOutputAfterLastDot);
if (eBidi == StrongBidiCategory.StrongRightToLeft)
{
// It has to be right to left.
bRightToLeft = true;
}
// Check the rest of them to make sure RTL/LTR is consistent
for (int iTest = iOutputAfterLastDot; iTest < output.Length; iTest++)
{
// This might happen if we run into a pair
if (char.IsLowSurrogate(output[iTest]))
continue;
// Check to see if its LTR
eBidi = CharUnicodeInfo.GetBidiCategory(output, iTest);
if ((bRightToLeft && eBidi == StrongBidiCategory.StrongLeftToRight) ||
(!bRightToLeft && eBidi == StrongBidiCategory.StrongRightToLeft))
throw new ArgumentException(SR.Argument_IdnBadBidi, nameof(ascii));
}
// Its also a requirement that the last one be RTL if 1st is RTL
if (bRightToLeft && eBidi != StrongBidiCategory.StrongRightToLeft)
{
// Oops, last wasn't RTL, last should be RTL if first is RTL
throw new ArgumentException(SR.Argument_IdnBadBidi, nameof(ascii));
}
}
// See if this label was too long
if (iNextDot - iAfterLastDot > c_labelLimit)
throw new ArgumentException(SR.Argument_IdnBadLabelSize, nameof(ascii));
// Done with this segment, add dot if necessary
if (iNextDot != ascii.Length)
output.Append('.');
iAfterLastDot = iNextDot + 1;
iOutputAfterLastDot = output.Length;
}
// Throw if we're too long
if (output.Length > c_defaultNameLimit - (IsDot(output[^1]) ? 0 : 1))
throw new ArgumentException(SR.Format(SR.Argument_IdnBadNameSize, c_defaultNameLimit - (IsDot(output[^1]) ? 0 : 1)), nameof(ascii));
// Return our output string
return output.ToString();
}
// DecodeDigit(cp) returns the numeric value of a basic code */
// point (for use in representing integers) in the range 0 to */
// c_punycodeBase-1, or <0 if cp is does not represent a value. */
private static int DecodeDigit(char cp)
{
if (char.IsAsciiDigit(cp))
return cp - '0' + 26;
// Two flavors for case differences
if (char.IsAsciiLetterLower(cp))
return cp - 'a';
if (char.IsAsciiLetterUpper(cp))
return cp - 'A';
// Expected 0-9, A-Z or a-z, everything else is illegal
throw new ArgumentException(SR.Argument_IdnBadPunycode, nameof(cp));
}
private static int Adapt(int delta, int numpoints, bool firsttime)
{
uint k;
delta = firsttime ? delta / c_damp : delta / 2;
Debug.Assert(numpoints != 0, "[IdnMapping.adapt]Expected non-zero numpoints.");
delta += delta / numpoints;
for (k = 0; delta > ((c_punycodeBase - c_tmin) * c_tmax) / 2; k += c_punycodeBase)
{
delta /= c_punycodeBase - c_tmin;
}
Debug.Assert(delta + c_skew != 0, "[IdnMapping.adapt]Expected non-zero delta+skew.");
return (int)(k + (c_punycodeBase - c_tmin + 1) * delta / (delta + c_skew));
}
/* EncodeBasic(bcp,flag) forces a basic code point to lowercase */
/* if flag is false, uppercase if flag is true, and returns */
/* the resulting code point. The code point is unchanged if it */
/* is caseless. The behavior is undefined if bcp is not a basic */
/* code point. */
private static char EncodeBasic(char bcp)
{
if (char.IsAsciiLetterUpper(bcp))
bcp += (char)('a' - 'A');
return bcp;
}
/* EncodeDigit(d,flag) returns the basic code point whose value */
/* (when used for representing integers) is d, which needs to be in */
/* the range 0 to punycodeBase-1. The lowercase form is used unless flag is */
/* true, in which case the uppercase form is used. */
private static char EncodeDigit(int d)
{
Debug.Assert(d >= 0 && d < c_punycodeBase, "[IdnMapping.encode_digit]Expected 0 <= d < punycodeBase");
// 26-35 map to ASCII 0-9
if (d > 25) return (char)(d - 26 + '0');
// 0-25 map to a-z or A-Z
return (char)(d + 'a');
}
}
}