UTF-8 is a variable-width encoding for Unicode. UTF-8 uses one to four bytes per character, depending on the Unicode symbol. UTF-8 has the following properties.
- The classical US-ASCII characters (0 to 0x7f) encode as themselves, so files and strings that are encoded with ASCII values have the same encoding under both ASCII and UTF-8.
- All UCS characters beyond (0x7f) are encoded as a multibyte sequence consisting only of bytes in the range of 0x80 to 0xfd. This means that no ASCII byte (including a null byte) can appear as part of another character. This property supports the use of string handling functions.
- It's easy to convert between UTF-8 and UCS-2 and UCS-4 fixed-width representations of characters.
- The lexicographic sorting order of UCS-4 strings is preserved.
- All possible 2^31 UCS codes can be encoded using UTF-8
Generally, all programs should perform checks for any UTF-8 data for UTF-8 validity before performing other checks. The table below lists all valid UTF-8 Sequences.
UCS Code (HEX) |
Binary UTF-8 Format |
Valid UTF-8 Values (HEX) |
|---|---|---|
00-7F |
0xxxxxxx |
00-7F |
80-7FF |
110xxxxx 10xxxxxx |
C2-DF 80-BF |
800-FFF |
1110xxxx 10xxxxxx 10xxxxxx |
E0 A0*-BF 80-BF |
1000-FFFF |
1110xxxx 10xxxxxx 10xxxxxx |
E1-EF 80-BF 80-BF |
10000-3FFFF |
11110xxx 10xxxxxx 10xxxxxx 10xxxxxx |
F0 90*-BF 80-BF 80-BF |
40000-FFFFFF |
11110xxx 10xxxxxx 10xxxxxx 10xxxxxx |
F1-F3 80-BF 80-BF 80-BF |
40000-FFFFFF |
11110xxx 10xxxxxx 10xxxxxx 10xxxxxx |
F1-F3 80-BF 80-BF 80-BF |
100000-10FFFFF |
11110xxx 10xxxxxx 10xxxxxx 10xxxxxx |
F4 80-8F* 80-BF 80-BF |
Although UTF-8 originated from the Plan 9 developers [[Pike 93]], Plan 9's own support only covers the low 16-bit range. In general, many "Unicode" systems only support the low 16-bit range, not the full 31-bit ISO 10646 code space [ISO/IEC 10646:2003(E)].
Security Related Issues
According to [[Yergeau 98]]:
Implementors of UTF-8 need to consider the security aspects of how they handle invalid UTF-8 sequences. It is conceivable that in some circumstances an attacker would be able to exploit an incautious UTF-8 parser by sending it an octet sequence that is not permitted by the UTF-8 syntax.
A particularly subtle form of this attack could be carried out against a parser which performs security-critical validity checks against the UTF-8 encoded form of its input, but interprets certain invalid octet sequences as characters. For example, a parser might prohibit the null character when encoded as the single-octet sequence
00, but allow the invalid two-octet sequenceC0 80and interpret it as a null character. Another example might be a parser which prohibits the octet sequence2F 2E 2E 2F("/../"), yet permits the invalid octet sequence2F C0 AE 2E 2F.
Below are more specific recommendations.
Only Accept the "shortest" form
Only the "shortest" form of UTF-8 should be permitted. Naive decoders might accept encoding that are longer than necessary, allowing for potentially dangerous input to have multiple representations. For example:
- Process A performs security checks, but does not check for non-shortest UTF-8 forms.
- Process B accepts the byte sequence from process A, and transform it into UTF-16 while interpreting possible non-shortest forms.
- The UTF-16 text may then contain characters that should have been filtered out by process A, and could potentially be dangerous.
These non-"shortest" UTF-8 attacks have been used to bypass security validations in high profile products, such as Microsoft's IIS web server.
Handling Invalid Inputs
UTF-8 decoders have no uniformly defined behavior upon encountering an invalid input. Below are several ways a UTF-8 decoder might behave in the event of an invalid byte sequence:
- Insert a replacement character (e.g. '?', the "wild-card" character)
- Ignore the bytes.
- Interpret the bytes according to a different character encoding (often the ISO-8859-1 character map)
- Not notice and decode as if the bytes were some similar bit of UTF-8.
- Stop decoding and report an error
The following function from [[Viega 03]] will detect invalid character sequences in a string but will not reject non-minimal forms. It returns 1 if the string is comprised only of legitimate sequences; else it returns 0.
int spc_utf8_isvalid(const unsigned char *input) {
int nb;
const unsigned char *c = input;
for (c = input; *c; c += (nb + 1)) {
if (!(*c & 0x80)) nb = 0;
else if ((*c & 0xc0) == 0x80) return 0;
else if ((*c & 0xe0) == 0xc0) nb = 1;
else if ((*c & 0xf0) == 0xe0) nb = 2;
else if ((*c & 0xf8) == 0xf0) nb = 3;
else if ((*c & 0xfc) == 0xf8) nb = 4;
else if ((*c & 0xfe) == 0xfc) nb = 5;
while (nb-- > 0)
if ((*(c + nb) & 0xc0) != 0x80) return 0;
}
return 1;
}
Broken Surrogates
Encoding of individual or out of order surrogate halves should not be permitted. Broken surrogates are invalid in Unicode, and introduce ambiguity when they appear in Unicode data. Broken surrogates are often signs of bad data transmission. They could also indicate internal bugs in an application, or intentional efforts to find security vulnerabilities.
Risk Assessment
Failing to properly handle UTF8 encoded data can result in a data integrity violation or denial of service situation.
Recommendation |
Severity |
Likelihood |
Remediation Cost |
Priority |
Level |
|---|---|---|---|---|---|
MSC10-A |
2 (medium) |
1 (unlikely) |
1 (high) |
P2 |
L3 |
Automated Detection
The LDRA tool suite V 7.6.0 is able to detect violations of this recommendation.
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
Reference
[ISO/IEC 10646:2003(E)] Information technology - Universal Multiple-Octet Coded Character Set (UCS), First Edition. December, 2003.
[[Kuhn 06]] UTF-8 and Unicode FAQ for Unix/Linux
[[Pike 93]]
[[Viega 03]] Section 3.12. "Detecting Illegal UTF-8 Characters"
[[Wheeler 06]] Secure Programming for Linux and Unix HOWTO
[[Yergeau 98]] RFC 2279 - UTF-8, a transformation format of ISO 10646
MSC09-A. Character Encoding - Use Subset of ASCII for Safety 14. Miscellaneous (MSC) MSC11-A. Incorporate diagnostic tests using assertions