Java string length and varchar length matching comprehension (character and byte length understanding)

Source: Internet
Author: User
Tags java string length uppercase letter ultraedit

1: "Byte" is byte, "bit" is bit;

2:1 byte = 8 bit;

Char is 2 bytes in Java. Java uses unicode,2 bytes (16 bits) to represent one character.


But
String str = "compilation";
byte[] bytes = Str.getbytes (); I wonder why it takes 3 bytes here?
3 byte is 3*8=24 byte altogether, then char X how to put down again? I believe that char is 16 bytes,
But Str.getbytes () What the hell is going on with this thing?

Sorry, the expression is a bit messy, but it is really strange. I hope you can give us a hint.

1 Floor:

First, a char in Java is indeed 2 bytes. Java uses unicode,2 bytes to represent one character.

Second, the landlord you said byte[] bytes = Str.getbytes (), followed by 3 bytes, here and the previous concept is different. Java is a Unicode representation of a character, and the Unicode of the Chinese character "coding" is 2 bytes. The String.getbytes (encoding) method is to get a byte array representation of the specified encoding, usually gbk/gb2312 is 2 bytes, and Utf-8 is 3 bytes. If you do not specify encoding, the system default encoding is taken.

In addition, the landlord's "byte" is a bit messy, usually we say the byte refers to Byte, there is a "bit" concept (bit), usually 1 byte=8 bit.
"3 byte is a total of 3*8=24 bytes" This sentence should be expressed as "3 byte altogether is 3*8=24 a bit"

The relationship between Unicode and UTF-8

1. ASCII code

We know that inside the computer, all the information is ultimately represented as a binary string. Each bits (bit) has 0 and 12 states, so eight bits can combine 256 states, which is called a byte. In other words, a byte can be used to represent 256 different states, each of which corresponds to a symbol, which is 256 symbols, from 0000000 to 11111111.

In the 60 's, the United States developed a set of character encodings, which made a uniform provision for the relationship between English characters and bits. This is known as ASCII code and has been used so far.

The ASCII code specifies a total of 128 characters, such as a space "space" is 32 (binary 00100000), the uppercase letter A is 65 (binary 01000001). These 128 symbols (including 32 control symbols that cannot be printed out) take up only one byte of the latter 7 bits, and the first 1-bit uniform is 0.

2, non-ASCII encoding

It is enough to encode 128 symbols in English, but 128 symbols are not enough to represent other languages. For example, in French, where there is a phonetic symbol above the letter, it cannot be represented by an ASCII code. As a result, some European countries decided to use the highest bits of the bytes that were idle to incorporate new symbols. For example, the code for E in French is 130 (binary 10000010). In this way, the coding system used in these European countries can represent a maximum of 256 symbols.

However, there are new problems. Different countries have different letters, so even if they are encoded using 256 symbols, the letters are not the same. For example, 130 is represented in the French code, but in Hebrew it represents the letter Gimel (?), and in the Russian language, another symbol is represented in the code. But anyway, in all of these encodings, 0--127 represents the same symbol, not just the 128--255 section.

As for Asian countries, the use of symbols is more, the Chinese character is about 100,000. A byte can represent only 256 symbols, which is certainly not enough, and must be expressed using multiple bytes to express a symbol. For example, the common encoding method in Simplified Chinese is GB2312, which uses two bytes to represent a Chinese character, so it is theoretically possible to represent a maximum of 256x256=65536 symbols.

The issue of Chinese coding needs to be discussed in this article, which is not covered by this note. It is only pointed out that although a symbol is represented in multiple bytes, the Chinese character coding of the GB class is irrelevant to the Unicode and UTF-8.

3.Unicode

As mentioned in the previous section, there are many coding methods in the world, and the same binary numbers can be interpreted as different symbols. Therefore, if you want to open a text file, you must know its encoding, or in the wrong way to interpret the code, there will be garbled. Why do e-mails often appear garbled? It is because the sender and the recipient are using different encoding methods.

It can be imagined that if there is an encoding, all the symbols in the world are included. Each symbol is given a unique encoding, then the garbled problem disappears. This is Unicode, as its name indicates, which is an encoding of all symbols.

Unicode is of course a large collection, and now the scale can accommodate the 100多万个 symbol. Each symbol is encoded differently, for example, u+0639 means that the Arabic letter ain,u+0041 represents the capital letter of the English a,u+4e25 denotes the Chinese character "strict". The specific Symbol correspondence table, may query unicode.org, or the specialized Chinese character correspondence table.

4. Problems with Unicode

It is important to note that Unicode is just a set of symbols, which only specifies the binary code of the symbol, but does not specify how the binary code should be stored.

For example, the Chinese character "strict" Unicode is hexadecimal number 4E25, converted to a binary number is a full 15 bits (100111000100101), that is to say, the symbol of at least 2 bytes. Representing other larger symbols, it may take 3 bytes or 4 bytes, or more.

There are two serious problems here, and the first question is, how can you differentiate between Unicode and ASCII? How does the computer know that three bytes represents a symbol instead of three symbols? The second problem is that we already know that the English alphabet is only one byte to express enough, if Unicode uniform rules, each symbol with three or four bytes, then each letter must have two to three bytes is 0, which is a great waste for storage, the size of the text file will be two or three times times larger , it is unacceptable.

They result in: 1) There is a variety of Unicode storage methods, which means that there are many different binary formats that can be used to represent Unicode. 2) Unicode cannot be promoted for a long period of time until the advent of the Internet.

5.utf-8

The popularization of the Internet has strongly demanded the emergence of a unified coding method. UTF-8 is the most widely used form of Unicode implementation on the Internet. Other implementations include UTF-16 (characters in two-byte or four-byte notation) and UTF-32 (characters in four-byte notation), but not on the Internet. Again, the relationship here is that UTF-8 is one of the ways Unicode is implemented.

One of the biggest features of UTF-8 is that it is a variable-length coding method. It can use 1~4 bytes to represent a symbol, varying the length of a byte depending on the symbol.

The coding rules for UTF-8 are simple, with only two lines:

1) for a single-byte symbol, the first bit of the byte is set to 0, and the next 7 bits are the Unicode code for the symbol. So for the English alphabet, the UTF-8 encoding and ASCII code are the same.

2) for n-byte notation (n>1), the first n bits are set to 1, the n+1 bit is set to 0, and the first two bits of the subsequent bytes are set to 10. The rest of the bits are not mentioned, all of which are Unicode codes for this symbol.

The following table summarizes the encoding rules, and the letter x represents the bits that are available for encoding.

Unicode Symbol Range | UTF-8 Encoding method
(hex) | (binary)
--------------------+---------------------------------------------
0000 0000-0000 007F | 0xxxxxxx
0000 0080-0000 07FF | 110xxxxx 10xxxxxx
0000 0800-0000 FFFF | 1110xxxx 10xxxxxx 10xxxxxx
0001 0000-0010 FFFF | 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx

According to the above table, it is very simple to interpret UTF-8 coding. If the first bit of a byte is 0, then the byte is a single character, and if the first bit is 1, how many consecutive 1 is the number of bytes that the current character occupies.

Below, or take the Chinese character "Yan" as an example, demonstrates how to implement UTF-8 encoding.

Known as "Strict" Unicode is 4E25 (100111000100101), according to the table above, you can find 4E25 in the range of the third row (0000 0800-0000 FFFF), so "strict" UTF-8 encoding requires three bytes, that is, the format is " 1110xxxx 10xxxxxx 10xxxxxx ". Then, starting from the last bits of "Yan", the X in the format is filled in sequentially, and the extra bits complement 0. This gets, "strict" UTF-8 code is "11100100 10111000 10100101", converted into 16 binary is e4b8a5.

6. Conversion between Unicode and UTF-8

Using the example in the previous section, you can see that the Unicode code for "strict" is 4e25,utf-8 encoding is E4B8A5, and the two are not the same. The transitions between them can be implemented by the program.

Under the Windows platform, one of the simplest ways to convert is to use the built-in Notepad applet Notepad.exe. After opening the file, click "Save as" on the "File" menu, you will get out of a dialog box, at the bottom there is a "coded" drop-down bar.

There are four options: Ansi,unicode,unicode big endian and UTF-8.

1) ANSI is the default encoding method. For English documents is ASCII encoding, for the Simplified Chinese file is GB2312 encoding (only for the Windows Simplified Chinese version, if the traditional Chinese version will use the BIG5 code).

2) Unicode encoding refers to the UCS-2 encoding method, which is a Unicode code that is stored directly in characters with two bytes. This option uses the little endian format.

3) The Unicode big endian encoding corresponds to the previous option. In the next section I will explain the meaning of little endian and big endian.

4) UTF-8 encoding, which is the encoding method mentioned in the previous section.

After selecting the "Encoding mode", click "Save" button, the file encoding method will be converted immediately.

7. Little Endian and Big endian

As mentioned in the previous section, Unicode codes can be stored directly in the UCS-2 format. Take the Chinese character "Yan" for example, the Unicode code is 4E25, need to be stored in two bytes, one byte is 4E, the other byte is 25. Storage, 4E in front, 25 in the back, is the big endian way, 25 in front, 4E in the back, is little endian way.

The two quirky names come from the book of Gulliver's Travels by British writer Swift. In the book, the Civil War broke out in the small country, the cause of the war is people arguing, whether to eat eggs from the big Head (Big-endian) or from the head (Little-endian) knocked open. For this matter, the war broke out six times, one Emperor gave his life, and the other emperor lost his throne.

Therefore, the first byte in front, is the "Big endian", the second byte in front is the "small Head Way" (Little endian).

Then, naturally, there is a problem: How does the computer know which encoding to use for a particular file?

Defined in the Unicode specification, each file is preceded by a character that represents the encoding sequence, which is named "0-width non-newline space" (ZERO wide no-break space), denoted by Feff. This happens to be two bytes, and FF is 1 larger than FE.

If the first two bytes of a text file are Fe FF, it means that the file is in a large head, and if the first two bytes are FF FE, it means that the file is in a small way.

8. Example

Below, give an example.

Open Notepad program Notepad.exe, create a new text file, the content is a "strict" word, followed by Ansi,unicode,unicode big endian and UTF-8 encoding method to save.

Then, use the "hex feature" in the text editing software UltraEdit to see how the file is encoded internally.

1) ANSI: The encoding of the file is two bytes "D1 CF", which is the "strict" GB2312 coding, which also implies that GB2312 is stored in the big head way.

2) Unicode: Encoding is four bytes "ff fe 4E", where "FF fe" indicates a small head mode of storage, the true encoding is 4E25.

3) Unicode Big endian: The encoding is four bytes "Fe FF 4E 25", wherein "FE FF" indicates that the head is stored in the way.

4) UTF-8: The encoding is six bytes "EF BB bf E4 B8 A5", the first three bytes "EF BB bf" indicates that this is UTF-8 encoding, and after three "E4B8A5" is the specific code of "strict", its storage sequence is consistent with the encoding order.

Nanyi

Date: October 28, 2007

Today at noon, I suddenly want to understand the relationship between Unicode and UTF-8, so I began to search the Internet information.

As a result, the problem was more complicated than I thought, and it was only after lunch that I saw 9 o'clock at night.

Here is my notes, mainly used to organize their own ideas. But I try to be easy to write and I hope to be useful to other friends. After all, character coding is the cornerstone of computer technology, and to be proficient in using computers, you must know a bit of character coding.

1. ASCII code

We know that inside the computer, all the information is ultimately represented as a binary string. Each bits (bit) has 0 and 12 states, so eight bits can combine 256 states, which is called a byte. In other words, a byte can be used to represent 256 different states, each of which corresponds to a symbol, which is 256 symbols, from 0000000 to 11111111.

In the 60 's, the United States developed a set of character encodings, which made a uniform provision for the relationship between English characters and bits. This is known as ASCII code and has been used so far.

The ASCII code specifies a total of 128 characters, such as a space "space" is 32 (binary 00100000), the uppercase letter A is 65 (binary 01000001). These 128 symbols (including 32 control symbols that cannot be printed out) take up only one byte of the latter 7 bits, and the first 1-bit uniform is 0.

2, non-ASCII encoding

It is enough to encode 128 symbols in English, but 128 symbols are not enough to represent other languages. For example, in French, where there is a phonetic symbol above the letter, it cannot be represented by an ASCII code. As a result, some European countries decided to use the highest bits of the bytes that were idle to incorporate new symbols. For example, the code for E in French is 130 (binary 10000010). In this way, the coding system used in these European countries can represent a maximum of 256 symbols.

However, there are new problems. Different countries have different letters, so even if they are encoded using 256 symbols, the letters are not the same. For example, 130 is represented in the French code, but in Hebrew it represents the letter Gimel (?), and in the Russian language, another symbol is represented in the code. But anyway, in all of these encodings, 0--127 represents the same symbol, not just the 128--255 section.

As for Asian countries, the use of symbols is more, the Chinese character is about 100,000. A byte can represent only 256 symbols, which is certainly not enough, and must be expressed using multiple bytes to express a symbol. For example, the common encoding method in Simplified Chinese is GB2312, which uses two bytes to represent a Chinese character, so it is theoretically possible to represent a maximum of 256x256=65536 symbols.

The issue of Chinese coding needs to be discussed in this article, which is not covered by this note. It is only pointed out that although a symbol is represented in multiple bytes, the Chinese character coding of the GB class is irrelevant to the Unicode and UTF-8.

3.Unicode

As mentioned in the previous section, there are many coding methods in the world, and the same binary numbers can be interpreted as different symbols. Therefore, if you want to open a text file, you must know its encoding, or in the wrong way to interpret the code, there will be garbled. Why do e-mails often appear garbled? It is because the sender and the recipient are using different encoding methods.

It can be imagined that if there is an encoding, all the symbols in the world are included. Each symbol is given a unique encoding, then the garbled problem disappears. This is Unicode, as its name indicates, which is an encoding of all symbols.

Unicode is of course a large collection, and now the scale can accommodate the 100多万个 symbol. Each symbol is encoded differently, for example, u+0639 means that the Arabic letter ain,u+0041 represents the capital letter of the English a,u+4e25 denotes the Chinese character "strict". The specific Symbol correspondence table, may query unicode.org, or the specialized Chinese character correspondence table.

4. Problems with Unicode

It is important to note that Unicode is just a set of symbols, which only specifies the binary code of the symbol, but does not specify how the binary code should be stored.

For example, the Chinese character "strict" Unicode is hexadecimal number 4E25, converted to a binary number is a full 15 bits (100111000100101), that is to say, the symbol of at least 2 bytes. Representing other larger symbols, it may take 3 bytes or 4 bytes, or more.

There are two serious problems here, and the first question is, how can you differentiate between Unicode and ASCII? How does the computer know that three bytes represents a symbol instead of three symbols? The second problem is that we already know that the English alphabet is only one byte to express enough, if Unicode uniform rules, each symbol with three or four bytes, then each letter must have two to three bytes is 0, which is a great waste for storage, the size of the text file will be two or three times times larger , it is unacceptable.

They result in: 1) There is a variety of Unicode storage methods, which means that there are many different binary formats that can be used to represent Unicode. 2) Unicode cannot be promoted for a long period of time until the advent of the Internet.

5.utf-8

The popularization of the Internet has strongly demanded the emergence of a unified coding method. UTF-8 is the most widely used form of Unicode implementation on the Internet. Other implementations include UTF-16 (characters in two-byte or four-byte notation) and UTF-32 (characters in four-byte notation), but not on the Internet. Again, the relationship here is that UTF-8 is one of the ways Unicode is implemented.

One of the biggest features of UTF-8 is that it is a variable-length coding method. It can use 1~4 bytes to represent a symbol, varying the length of a byte depending on the symbol.

The coding rules for UTF-8 are simple, with only two lines:

1) for a single-byte symbol, the first bit of the byte is set to 0, and the next 7 bits are the Unicode code for the symbol. So for the English alphabet, the UTF-8 encoding and ASCII code are the same.

2) for n-byte notation (n>1), the first n bits are set to 1, the n+1 bit is set to 0, and the first two bits of the subsequent bytes are set to 10. The rest of the bits are not mentioned, all of which are Unicode codes for this symbol.

The following table summarizes the encoding rules, and the letter x represents the bits that are available for encoding.

Unicode Symbol Range | UTF-8 Encoding method
(hex) | (binary)
--------------------+---------------------------------------------
0000 0000-0000 007F | 0xxxxxxx
0000 0080-0000 07FF | 110xxxxx 10xxxxxx
0000 0800-0000 FFFF | 1110xxxx 10xxxxxx 10xxxxxx
0001 0000-0010 FFFF | 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx

According to the above table, it is very simple to interpret UTF-8 coding. If the first bit of a byte is 0, then the byte is a single character, and if the first bit is 1, how many consecutive 1 is the number of bytes that the current character occupies.

Below, or take the Chinese character "Yan" as an example, demonstrates how to implement UTF-8 encoding.

Known as "Strict" Unicode is 4E25 (100111000100101), according to the table above, you can find 4E25 in the range of the third row (0000 0800-0000 FFFF), so "strict" UTF-8 encoding requires three bytes, that is, the format is " 1110xxxx 10xxxxxx 10xxxxxx ". Then, starting from the last bits of "Yan", the X in the format is filled in sequentially, and the extra bits complement 0. This gets, "strict" UTF-8 code is "11100100 10111000 10100101", converted into 16 binary is e4b8a5.

6. Conversion between Unicode and UTF-8

Using the example in the previous section, you can see that the Unicode code for "strict" is 4e25,utf-8 encoding is E4B8A5, and the two are not the same. The transitions between them can be implemented by the program.

Under the Windows platform, one of the simplest ways to convert is to use the built-in Notepad applet Notepad.exe. After opening the file, click "Save as" on the "File" menu, you will get out of a dialog box, at the bottom there is a "coded" drop-down bar.

There are four options: Ansi,unicode,unicode big endian and UTF-8.

1) ANSI is the default encoding method. For English documents is ASCII encoding, for the Simplified Chinese file is GB2312 encoding (only for the Windows Simplified Chinese version, if the traditional Chinese version will use the BIG5 code).

2) Unicode encoding refers to the UCS-2 encoding method, which is a Unicode code that is stored directly in characters with two bytes. This option uses the little endian format.

3) The Unicode big endian encoding corresponds to the previous option. In the next section I will explain the meaning of little endian and big endian.

4) UTF-8 encoding, which is the encoding method mentioned in the previous section.

After selecting the "Encoding mode", click "Save" button, the file encoding method will be converted immediately.

7. Little Endian and Big endian

As mentioned in the previous section, Unicode codes can be stored directly in the UCS-2 format. Take the Chinese character "Yan" for example, the Unicode code is 4E25, need to be stored in two bytes, one byte is 4E, the other byte is 25. Storage, 4E in front, 25 in the back, is the big endian way, 25 in front, 4E in the back, is little endian way.

The two quirky names come from the book of Gulliver's Travels by British writer Swift. In the book, the Civil War broke out in the small country, the cause of the war is people arguing, whether to eat eggs from the big Head (Big-endian) or from the head (Little-endian) knocked open. For this matter, the war broke out six times, one Emperor gave his life, and the other emperor lost his throne.

Therefore, the first byte in front, is the "Big endian", the second byte in front is the "small Head Way" (Little endian).

Then, naturally, there is a problem: How does the computer know which encoding to use for a particular file?

Defined in the Unicode specification, each file is preceded by a character that represents the encoding sequence, which is named "0-width non-newline space" (ZERO wide no-break space), denoted by Feff. This happens to be two bytes, and FF is 1 larger than FE.

If the first two bytes of a text file are Fe FF, it means that the file is in a large head, and if the first two bytes are FF FE, it means that the file is in a small way.

8. Example

Below, give an example.

Open Notepad program Notepad.exe, create a new text file, the content is a "strict" word, followed by Ansi,unicode,unicode big endian and UTF-8 encoding method to save.

Then, use the "hex feature" in the text editing software UltraEdit to see how the file is encoded internally.

1) ANSI: The encoding of the file is two bytes "D1 CF", which is the "strict" GB2312 coding, which also implies that GB2312 is stored in the big head way.

2) Unicode: Encoding is four bytes "ff fe 4E", where "FF fe" indicates a small head mode of storage, the true encoding is 4E25.

3) Unicode Big endian: The encoding is four bytes "Fe FF 4E 25", wherein "FE FF" indicates that the head is stored in the way.

4) UTF-8: The encoding is six bytes "EF BB bf E4 B8 A5", the first three bytes "EF BB bf" indicates that this is UTF-8 encoding, and after three "E4B8A5" is the specific code of "strict", its storage sequence is consistent with the encoding order.

9. Extended Reading

* The Absolute Minimum every software Developer absolutely, positively must Know about Unicode and Character sets (on the most basic of the character set This knowledge)

* Talk about Unicode encoding

* Rfc3629:utf-8, a transformation format of ISO 10646 (if UTF-8 is implemented)

Part of this article goes from http://blog.csdn.net/xiaolei1021/article/details/52093706 Thank you to the author

Java string length and varchar length matching comprehension (character and byte length understanding)

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