--- sidebar_position: 40 sidebar_label: Strings --- # Functions for Working with Strings :::note Functions for [searching](../../sql-reference/functions/string-search-functions.md) and [replacing](../../sql-reference/functions/string-replace-functions.md) in strings are described separately. ::: ## empty Checks whether the input string is empty. **Syntax** ``` sql empty(x) ``` A string is considered non-empty if it contains at least one byte, even if this is a space or a null byte. The function also works for [arrays](array-functions.md#function-empty) or [UUID](uuid-functions.md#empty). **Arguments** - `x` — Input value. [String](../data-types/string.md). **Returned value** - Returns `1` for an empty string or `0` for a non-empty string. Type: [UInt8](../data-types/int-uint.md). **Example** Query: ```sql SELECT empty(''); ``` Result: ```text ┌─empty('')─┐ │ 1 │ └───────────┘ ``` ## notEmpty Checks whether the input string is non-empty. **Syntax** ``` sql notEmpty(x) ``` A string is considered non-empty if it contains at least one byte, even if this is a space or a null byte. The function also works for [arrays](array-functions.md#function-notempty) or [UUID](uuid-functions.md#notempty). **Arguments** - `x` — Input value. [String](../data-types/string.md). **Returned value** - Returns `1` for a non-empty string or `0` for an empty string string. Type: [UInt8](../data-types/int-uint.md). **Example** Query: ```sql SELECT notEmpty('text'); ``` Result: ```text ┌─notEmpty('text')─┐ │ 1 │ └──────────────────┘ ``` ## length Returns the length of a string in bytes (not in characters, and not in code points). The result type is UInt64. The function also works for arrays. ## lengthUTF8 Returns the length of a string in Unicode code points (not in characters), assuming that the string contains a set of bytes that make up UTF-8 encoded text. If this assumption is not met, it returns some result (it does not throw an exception). The result type is UInt64. ## char_length, CHAR_LENGTH Returns the length of a string in Unicode code points (not in characters), assuming that the string contains a set of bytes that make up UTF-8 encoded text. If this assumption is not met, it returns some result (it does not throw an exception). The result type is UInt64. ## character_length, CHARACTER_LENGTH Returns the length of a string in Unicode code points (not in characters), assuming that the string contains a set of bytes that make up UTF-8 encoded text. If this assumption is not met, it returns some result (it does not throw an exception). The result type is UInt64. ## leftPad Pads the current string from the left with spaces or a specified string (multiple times, if needed) until the resulting string reaches the given length. Similarly to the MySQL `LPAD` function. **Syntax** ``` sql leftPad('string', 'length'[, 'pad_string']) ``` **Arguments** - `string` — Input string that needs to be padded. [String](../data-types/string.md). - `length` — The length of the resulting string. [UInt](../data-types/int-uint.md). If the value is less than the input string length, then the input string is returned as-is. - `pad_string` — The string to pad the input string with. [String](../data-types/string.md). Optional. If not specified, then the input string is padded with spaces. **Returned value** - The resulting string of the given length. Type: [String](../data-types/string.md). **Example** Query: ``` sql SELECT leftPad('abc', 7, '*'), leftPad('def', 7); ``` Result: ``` text ┌─leftPad('abc', 7, '*')─┬─leftPad('def', 7)─┐ │ ****abc │ def │ └────────────────────────┴───────────────────┘ ``` ## leftPadUTF8 Pads the current string from the left with spaces or a specified string (multiple times, if needed) until the resulting string reaches the given length. Similarly to the MySQL `LPAD` function. While in the [leftPad](#leftpad) function the length is measured in bytes, here in the `leftPadUTF8` function it is measured in code points. **Syntax** ``` sql leftPadUTF8('string','length'[, 'pad_string']) ``` **Arguments** - `string` — Input string that needs to be padded. [String](../data-types/string.md). - `length` — The length of the resulting string. [UInt](../data-types/int-uint.md). If the value is less than the input string length, then the input string is returned as-is. - `pad_string` — The string to pad the input string with. [String](../data-types/string.md). Optional. If not specified, then the input string is padded with spaces. **Returned value** - The resulting string of the given length. Type: [String](../data-types/string.md). **Example** Query: ``` sql SELECT leftPadUTF8('абвг', 7, '*'), leftPadUTF8('дежз', 7); ``` Result: ``` text ┌─leftPadUTF8('абвг', 7, '*')─┬─leftPadUTF8('дежз', 7)─┐ │ ***абвг │ дежз │ └─────────────────────────────┴────────────────────────┘ ``` ## rightPad Pads the current string from the right with spaces or a specified string (multiple times, if needed) until the resulting string reaches the given length. Similarly to the MySQL `RPAD` function. **Syntax** ``` sql rightPad('string', 'length'[, 'pad_string']) ``` **Arguments** - `string` — Input string that needs to be padded. [String](../data-types/string.md). - `length` — The length of the resulting string. [UInt](../data-types/int-uint.md). If the value is less than the input string length, then the input string is returned as-is. - `pad_string` — The string to pad the input string with. [String](../data-types/string.md). Optional. If not specified, then the input string is padded with spaces. **Returned value** - The resulting string of the given length. Type: [String](../data-types/string.md). **Example** Query: ``` sql SELECT rightPad('abc', 7, '*'), rightPad('abc', 7); ``` Result: ``` text ┌─rightPad('abc', 7, '*')─┬─rightPad('abc', 7)─┐ │ abc**** │ abc │ └─────────────────────────┴────────────────────┘ ``` ## rightPadUTF8 Pads the current string from the right with spaces or a specified string (multiple times, if needed) until the resulting string reaches the given length. Similarly to the MySQL `RPAD` function. While in the [rightPad](#rightpad) function the length is measured in bytes, here in the `rightPadUTF8` function it is measured in code points. **Syntax** ``` sql rightPadUTF8('string','length'[, 'pad_string']) ``` **Arguments** - `string` — Input string that needs to be padded. [String](../data-types/string.md). - `length` — The length of the resulting string. [UInt](../data-types/int-uint.md). If the value is less than the input string length, then the input string is returned as-is. - `pad_string` — The string to pad the input string with. [String](../data-types/string.md). Optional. If not specified, then the input string is padded with spaces. **Returned value** - The resulting string of the given length. Type: [String](../data-types/string.md). **Example** Query: ``` sql SELECT rightPadUTF8('абвг', 7, '*'), rightPadUTF8('абвг', 7); ``` Result: ``` text ┌─rightPadUTF8('абвг', 7, '*')─┬─rightPadUTF8('абвг', 7)─┐ │ абвг*** │ абвг │ └──────────────────────────────┴─────────────────────────┘ ``` ## lower, lcase Converts ASCII Latin symbols in a string to lowercase. ## upper, ucase Converts ASCII Latin symbols in a string to uppercase. ## lowerUTF8 Converts a string to lowercase, assuming the string contains a set of bytes that make up a UTF-8 encoded text. It does not detect the language. So for Turkish the result might not be exactly correct. If the length of the UTF-8 byte sequence is different for upper and lower case of a code point, the result may be incorrect for this code point. If the string contains a set of bytes that is not UTF-8, then the behavior is undefined. ## upperUTF8 Converts a string to uppercase, assuming the string contains a set of bytes that make up a UTF-8 encoded text. It does not detect the language. So for Turkish the result might not be exactly correct. If the length of the UTF-8 byte sequence is different for upper and lower case of a code point, the result may be incorrect for this code point. If the string contains a set of bytes that is not UTF-8, then the behavior is undefined. ## isValidUTF8 Returns 1, if the set of bytes is valid UTF-8 encoded, otherwise 0. ## toValidUTF8 Replaces invalid UTF-8 characters by the `�` (U+FFFD) character. All running in a row invalid characters are collapsed into the one replacement character. ``` sql toValidUTF8(input_string) ``` **Arguments** - `input_string` — Any set of bytes represented as the [String](../../sql-reference/data-types/string.md) data type object. Returned value: Valid UTF-8 string. **Example** ``` sql SELECT toValidUTF8('\x61\xF0\x80\x80\x80b'); ``` ``` text ┌─toValidUTF8('a����b')─┐ │ a�b │ └───────────────────────┘ ``` ## repeat Repeats a string as many times as specified and concatenates the replicated values as a single string. Alias: `REPEAT`. **Syntax** ``` sql repeat(s, n) ``` **Arguments** - `s` — The string to repeat. [String](../../sql-reference/data-types/string.md). - `n` — The number of times to repeat the string. [UInt](../../sql-reference/data-types/int-uint.md). **Returned value** The single string, which contains the string `s` repeated `n` times. If `n` \< 1, the function returns empty string. Type: `String`. **Example** Query: ``` sql SELECT repeat('abc', 10); ``` Result: ``` text ┌─repeat('abc', 10)──────────────┐ │ abcabcabcabcabcabcabcabcabcabc │ └────────────────────────────────┘ ``` ## reverse Reverses the string (as a sequence of bytes). ## reverseUTF8 Reverses a sequence of Unicode code points, assuming that the string contains a set of bytes representing a UTF-8 text. Otherwise, it does something else (it does not throw an exception). ## format(pattern, s0, s1, …) Formatting constant pattern with the string listed in the arguments. `pattern` is a simplified Python format pattern. Format string contains “replacement fields” surrounded by curly braces `{}`. Anything that is not contained in braces is considered literal text, which is copied unchanged to the output. If you need to include a brace character in the literal text, it can be escaped by doubling: `{{ '{{' }}` and `{{ '}}' }}`. Field names can be numbers (starting from zero) or empty (then they are treated as consequence numbers). ``` sql SELECT format('{1} {0} {1}', 'World', 'Hello') ``` ``` text ┌─format('{1} {0} {1}', 'World', 'Hello')─┐ │ Hello World Hello │ └─────────────────────────────────────────┘ ``` ``` sql SELECT format('{} {}', 'Hello', 'World') ``` ``` text ┌─format('{} {}', 'Hello', 'World')─┐ │ Hello World │ └───────────────────────────────────┘ ``` ## concat Concatenates the strings listed in the arguments, without a separator. **Syntax** ``` sql concat(s1, s2, ...) ``` **Arguments** Values of type String or FixedString. **Returned values** Returns the String that results from concatenating the arguments. If any of argument values is `NULL`, `concat` returns `NULL`. **Example** Query: ``` sql SELECT concat('Hello, ', 'World!'); ``` Result: ``` text ┌─concat('Hello, ', 'World!')─┐ │ Hello, World! │ └─────────────────────────────┘ ``` ## concatAssumeInjective Same as [concat](#concat), the difference is that you need to ensure that `concat(s1, s2, ...) → sn` is injective, it will be used for optimization of GROUP BY. The function is named “injective” if it always returns different result for different values of arguments. In other words: different arguments never yield identical result. **Syntax** ``` sql concatAssumeInjective(s1, s2, ...) ``` **Arguments** Values of type String or FixedString. **Returned values** Returns the String that results from concatenating the arguments. If any of argument values is `NULL`, `concatAssumeInjective` returns `NULL`. **Example** Input table: ``` sql CREATE TABLE key_val(`key1` String, `key2` String, `value` UInt32) ENGINE = TinyLog; INSERT INTO key_val VALUES ('Hello, ','World',1), ('Hello, ','World',2), ('Hello, ','World!',3), ('Hello',', World!',2); SELECT * from key_val; ``` ``` text ┌─key1────┬─key2─────┬─value─┐ │ Hello, │ World │ 1 │ │ Hello, │ World │ 2 │ │ Hello, │ World! │ 3 │ │ Hello │ , World! │ 2 │ └─────────┴──────────┴───────┘ ``` Query: ``` sql SELECT concat(key1, key2), sum(value) FROM key_val GROUP BY concatAssumeInjective(key1, key2); ``` Result: ``` text ┌─concat(key1, key2)─┬─sum(value)─┐ │ Hello, World! │ 3 │ │ Hello, World! │ 2 │ │ Hello, World │ 3 │ └────────────────────┴────────────┘ ``` ## substring(s, offset, length), mid(s, offset, length), substr(s, offset, length) Returns a substring starting with the byte from the ‘offset’ index that is ‘length’ bytes long. Character indexing starts from one (as in standard SQL). ## substringUTF8(s, offset, length) The same as ‘substring’, but for Unicode code points. Works under the assumption that the string contains a set of bytes representing a UTF-8 encoded text. If this assumption is not met, it returns some result (it does not throw an exception). ## appendTrailingCharIfAbsent(s, c) If the ‘s’ string is non-empty and does not contain the ‘c’ character at the end, it appends the ‘c’ character to the end. ## convertCharset(s, from, to) Returns the string ‘s’ that was converted from the encoding in ‘from’ to the encoding in ‘to’. ## base64Encode(s) Encodes ‘s’ string into base64 Alias: `TO_BASE64`. ## base64Decode(s) Decode base64-encoded string ‘s’ into original string. In case of failure raises an exception. Alias: `FROM_BASE64`. ## tryBase64Decode(s) Similar to base64Decode, but in case of error an empty string would be returned. ## endsWith(s, suffix) Returns whether to end with the specified suffix. Returns 1 if the string ends with the specified suffix, otherwise it returns 0. ## startsWith(str, prefix) Returns 1 whether string starts with the specified prefix, otherwise it returns 0. ``` sql SELECT startsWith('Spider-Man', 'Spi'); ``` **Returned values** - 1, if the string starts with the specified prefix. - 0, if the string does not start with the specified prefix. **Example** Query: ``` sql SELECT startsWith('Hello, world!', 'He'); ``` Result: ``` text ┌─startsWith('Hello, world!', 'He')─┐ │ 1 │ └───────────────────────────────────┘ ``` ## trim Removes all specified characters from the start or end of a string. By default removes all consecutive occurrences of common whitespace (ASCII character 32) from both ends of a string. **Syntax** ``` sql trim([[LEADING|TRAILING|BOTH] trim_character FROM] input_string) ``` **Arguments** - `trim_character` — Specified characters for trim. [String](../../sql-reference/data-types/string.md). - `input_string` — String for trim. [String](../../sql-reference/data-types/string.md). **Returned value** A string without leading and (or) trailing specified characters. Type: `String`. **Example** Query: ``` sql SELECT trim(BOTH ' ()' FROM '( Hello, world! )'); ``` Result: ``` text ┌─trim(BOTH ' ()' FROM '( Hello, world! )')─┐ │ Hello, world! │ └───────────────────────────────────────────────┘ ``` ## trimLeft Removes all consecutive occurrences of common whitespace (ASCII character 32) from the beginning of a string. It does not remove other kinds of whitespace characters (tab, no-break space, etc.). **Syntax** ``` sql trimLeft(input_string) ``` Alias: `ltrim(input_string)`. **Arguments** - `input_string` — string to trim. [String](../../sql-reference/data-types/string.md). **Returned value** A string without leading common whitespaces. Type: `String`. **Example** Query: ``` sql SELECT trimLeft(' Hello, world! '); ``` Result: ``` text ┌─trimLeft(' Hello, world! ')─┐ │ Hello, world! │ └─────────────────────────────────────┘ ``` ## trimRight Removes all consecutive occurrences of common whitespace (ASCII character 32) from the end of a string. It does not remove other kinds of whitespace characters (tab, no-break space, etc.). **Syntax** ``` sql trimRight(input_string) ``` Alias: `rtrim(input_string)`. **Arguments** - `input_string` — string to trim. [String](../../sql-reference/data-types/string.md). **Returned value** A string without trailing common whitespaces. Type: `String`. **Example** Query: ``` sql SELECT trimRight(' Hello, world! '); ``` Result: ``` text ┌─trimRight(' Hello, world! ')─┐ │ Hello, world! │ └──────────────────────────────────────┘ ``` ## trimBoth Removes all consecutive occurrences of common whitespace (ASCII character 32) from both ends of a string. It does not remove other kinds of whitespace characters (tab, no-break space, etc.). **Syntax** ``` sql trimBoth(input_string) ``` Alias: `trim(input_string)`. **Arguments** - `input_string` — string to trim. [String](../../sql-reference/data-types/string.md). **Returned value** A string without leading and trailing common whitespaces. Type: `String`. **Example** Query: ``` sql SELECT trimBoth(' Hello, world! '); ``` Result: ``` text ┌─trimBoth(' Hello, world! ')─┐ │ Hello, world! │ └─────────────────────────────────────┘ ``` ## CRC32(s) Returns the CRC32 checksum of a string, using CRC-32-IEEE 802.3 polynomial and initial value `0xffffffff` (zlib implementation). The result type is UInt32. ## CRC32IEEE(s) Returns the CRC32 checksum of a string, using CRC-32-IEEE 802.3 polynomial. The result type is UInt32. ## CRC64(s) Returns the CRC64 checksum of a string, using CRC-64-ECMA polynomial. The result type is UInt64. ## normalizeQuery Replaces literals, sequences of literals and complex aliases with placeholders. **Syntax** ``` sql normalizeQuery(x) ``` **Arguments** - `x` — Sequence of characters. [String](../../sql-reference/data-types/string.md). **Returned value** - Sequence of characters with placeholders. Type: [String](../../sql-reference/data-types/string.md). **Example** Query: ``` sql SELECT normalizeQuery('[1, 2, 3, x]') AS query; ``` Result: ``` text ┌─query────┐ │ [?.., x] │ └──────────┘ ``` ## normalizedQueryHash Returns identical 64bit hash values without the values of literals for similar queries. It helps to analyze query log. **Syntax** ``` sql normalizedQueryHash(x) ``` **Arguments** - `x` — Sequence of characters. [String](../../sql-reference/data-types/string.md). **Returned value** - Hash value. Type: [UInt64](../../sql-reference/data-types/int-uint.md#uint-ranges). **Example** Query: ``` sql SELECT normalizedQueryHash('SELECT 1 AS `xyz`') != normalizedQueryHash('SELECT 1 AS `abc`') AS res; ``` Result: ``` text ┌─res─┐ │ 1 │ └─────┘ ``` ## normalizeUTF8NFC Converts a string to [NFC normalized form](https://en.wikipedia.org/wiki/Unicode_equivalence#Normal_forms), assuming the string contains a set of bytes that make up a UTF-8 encoded text. **Syntax** ``` sql normalizeUTF8NFC(words) ``` **Arguments** - `words` — Input string that contains UTF-8 encoded text. [String](../../sql-reference/data-types/string.md). **Returned value** - String transformed to NFC normalization form. Type: [String](../../sql-reference/data-types/string.md). **Example** Query: ``` sql SELECT length('â'), normalizeUTF8NFC('â') AS nfc, length(nfc) AS nfc_len; ``` Result: ``` text ┌─length('â')─┬─nfc─┬─nfc_len─┐ │ 2 │ â │ 2 │ └─────────────┴─────┴─────────┘ ``` ## normalizeUTF8NFD Converts a string to [NFD normalized form](https://en.wikipedia.org/wiki/Unicode_equivalence#Normal_forms), assuming the string contains a set of bytes that make up a UTF-8 encoded text. **Syntax** ``` sql normalizeUTF8NFD(words) ``` **Arguments** - `words` — Input string that contains UTF-8 encoded text. [String](../../sql-reference/data-types/string.md). **Returned value** - String transformed to NFD normalization form. Type: [String](../../sql-reference/data-types/string.md). **Example** Query: ``` sql SELECT length('â'), normalizeUTF8NFD('â') AS nfd, length(nfd) AS nfd_len; ``` Result: ``` text ┌─length('â')─┬─nfd─┬─nfd_len─┐ │ 2 │ â │ 3 │ └─────────────┴─────┴─────────┘ ``` ## normalizeUTF8NFKC Converts a string to [NFKC normalized form](https://en.wikipedia.org/wiki/Unicode_equivalence#Normal_forms), assuming the string contains a set of bytes that make up a UTF-8 encoded text. **Syntax** ``` sql normalizeUTF8NFKC(words) ``` **Arguments** - `words` — Input string that contains UTF-8 encoded text. [String](../../sql-reference/data-types/string.md). **Returned value** - String transformed to NFKC normalization form. Type: [String](../../sql-reference/data-types/string.md). **Example** Query: ``` sql SELECT length('â'), normalizeUTF8NFKC('â') AS nfkc, length(nfkc) AS nfkc_len; ``` Result: ``` text ┌─length('â')─┬─nfkc─┬─nfkc_len─┐ │ 2 │ â │ 2 │ └─────────────┴──────┴──────────┘ ``` ## normalizeUTF8NFKD Converts a string to [NFKD normalized form](https://en.wikipedia.org/wiki/Unicode_equivalence#Normal_forms), assuming the string contains a set of bytes that make up a UTF-8 encoded text. **Syntax** ``` sql normalizeUTF8NFKD(words) ``` **Arguments** - `words` — Input string that contains UTF-8 encoded text. [String](../../sql-reference/data-types/string.md). **Returned value** - String transformed to NFKD normalization form. Type: [String](../../sql-reference/data-types/string.md). **Example** Query: ``` sql SELECT length('â'), normalizeUTF8NFKD('â') AS nfkd, length(nfkd) AS nfkd_len; ``` Result: ``` text ┌─length('â')─┬─nfkd─┬─nfkd_len─┐ │ 2 │ â │ 3 │ └─────────────┴──────┴──────────┘ ``` ## encodeXMLComponent Escapes characters to place string into XML text node or attribute. The following five XML predefined entities will be replaced: `<`, `&`, `>`, `"`, `'`. **Syntax** ``` sql encodeXMLComponent(x) ``` **Arguments** - `x` — The sequence of characters. [String](../../sql-reference/data-types/string.md). **Returned value** - The sequence of characters with escape characters. Type: [String](../../sql-reference/data-types/string.md). **Example** Query: ``` sql SELECT encodeXMLComponent('Hello, "world"!'); SELECT encodeXMLComponent('<123>'); SELECT encodeXMLComponent('&clickhouse'); SELECT encodeXMLComponent('\'foo\''); ``` Result: ``` text Hello, "world"! <123> &clickhouse 'foo' ``` ## decodeXMLComponent Replaces XML predefined entities with characters. Predefined entities are `"` `&` `'` `>` `<` This function also replaces numeric character references with Unicode characters. Both decimal (like `✓`) and hexadecimal (`✓`) forms are supported. **Syntax** ``` sql decodeXMLComponent(x) ``` **Arguments** - `x` — A sequence of characters. [String](../../sql-reference/data-types/string.md). **Returned value** - The sequence of characters after replacement. Type: [String](../../sql-reference/data-types/string.md). **Example** Query: ``` sql SELECT decodeXMLComponent(''foo''); SELECT decodeXMLComponent('< Σ >'); ``` Result: ``` text 'foo' < Σ > ``` **See Also** - [List of XML and HTML character entity references](https://en.wikipedia.org/wiki/List_of_XML_and_HTML_character_entity_references) ## extractTextFromHTML A function to extract text from HTML or XHTML. It does not necessarily 100% conform to any of the HTML, XML or XHTML standards, but the implementation is reasonably accurate and it is fast. The rules are the following: 1. Comments are skipped. Example: ``. Comment must end with `-->`. Nested comments are not possible. Note: constructions like `` and `` are not valid comments in HTML but they are skipped by other rules. 2. CDATA is pasted verbatim. Note: CDATA is XML/XHTML specific. But it is processed for "best-effort" approach. 3. `script` and `style` elements are removed with all their content. Note: it is assumed that closing tag cannot appear inside content. For example, in JS string literal has to be escaped like `"<\/script>"`. Note: comments and CDATA are possible inside `script` or `style` - then closing tags are not searched inside CDATA. Example: `]]>`. But they are still searched inside comments. Sometimes it becomes complicated: ` var y = "-->"; alert(x + y);` Note: `script` and `style` can be the names of XML namespaces - then they are not treated like usual `script` or `style` elements. Example: `Hello`. Note: whitespaces are possible after closing tag name: `` but not before: `< / script>`. 4. Other tags or tag-like elements are skipped without inner content. Example: `.` Note: it is expected that this HTML is illegal: `` Note: it also skips something like tags: `<>`, ``, etc. Note: tag without end is skipped to the end of input: `world`, `Helloworld` - there is no whitespace in HTML, but the function inserts it. Also consider: `Hello

world

`, `Hello
world`. This behavior is reasonable for data analysis, e.g. to convert HTML to a bag of words. 7. Also note that correct handling of whitespaces requires the support of `
` and CSS `display` and `white-space` properties.

**Syntax**

``` sql
extractTextFromHTML(x)
```

**Arguments**

-   `x` — input text. [String](../../sql-reference/data-types/string.md).

**Returned value**

-   Extracted text.

Type: [String](../../sql-reference/data-types/string.md).

**Example**

The first example contains several tags and a comment and also shows whitespace processing.
The second example shows `CDATA` and `script` tag processing.
In the third example text is extracted from the full HTML response received by the [url](../../sql-reference/table-functions/url.md) function.

Query:

``` sql
SELECT extractTextFromHTML(' 

A text withtags.

'); SELECT extractTextFromHTML('CDATA]]> '); SELECT extractTextFromHTML(html) FROM url('http://www.donothingfor2minutes.com/', RawBLOB, 'html String'); ``` Result: ``` text A text with tags . The content within CDATA Do Nothing for 2 Minutes 2:00   ```