Related
Apparently, the following is the valid syntax:
b'The string'
I would like to know:
What does this b character in front of the string mean?
What are the effects of using it?
What are appropriate situations to use it?
I found a related question right here on SO, but that question is about PHP though, and it states the b is used to indicate the string is binary, as opposed to Unicode, which was needed for code to be compatible from version of PHP < 6, when migrating to PHP 6. I don't think this applies to Python.
I did find this documentation on the Python site about using a u character in the same syntax to specify a string as Unicode. Unfortunately, it doesn't mention the b character anywhere in that document.
Also, just out of curiosity, are there more symbols than the b and u that do other things?
Python 3.x makes a clear distinction between the types:
str = '...' literals = a sequence of Unicode characters (Latin-1, UCS-2 or UCS-4, depending on the widest character in the string)
bytes = b'...' literals = a sequence of octets (integers between 0 and 255)
If you're familiar with:
Java or C#, think of str as String and bytes as byte[];
SQL, think of str as NVARCHAR and bytes as BINARY or BLOB;
Windows registry, think of str as REG_SZ and bytes as REG_BINARY.
If you're familiar with C(++), then forget everything you've learned about char and strings, because a character is not a byte. That idea is long obsolete.
You use str when you want to represent text.
print('שלום עולם')
You use bytes when you want to represent low-level binary data like structs.
NaN = struct.unpack('>d', b'\xff\xf8\x00\x00\x00\x00\x00\x00')[0]
You can encode a str to a bytes object.
>>> '\uFEFF'.encode('UTF-8')
b'\xef\xbb\xbf'
And you can decode a bytes into a str.
>>> b'\xE2\x82\xAC'.decode('UTF-8')
'€'
But you can't freely mix the two types.
>>> b'\xEF\xBB\xBF' + 'Text with a UTF-8 BOM'
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: can't concat bytes to str
The b'...' notation is somewhat confusing in that it allows the bytes 0x01-0x7F to be specified with ASCII characters instead of hex numbers.
>>> b'A' == b'\x41'
True
But I must emphasize, a character is not a byte.
>>> 'A' == b'A'
False
In Python 2.x
Pre-3.0 versions of Python lacked this kind of distinction between text and binary data. Instead, there was:
unicode = u'...' literals = sequence of Unicode characters = 3.x str
str = '...' literals = sequences of confounded bytes/characters
Usually text, encoded in some unspecified encoding.
But also used to represent binary data like struct.pack output.
In order to ease the 2.x-to-3.x transition, the b'...' literal syntax was backported to Python 2.6, in order to allow distinguishing binary strings (which should be bytes in 3.x) from text strings (which should be str in 3.x). The b prefix does nothing in 2.x, but tells the 2to3 script not to convert it to a Unicode string in 3.x.
So yes, b'...' literals in Python have the same purpose that they do in PHP.
Also, just out of curiosity, are there
more symbols than the b and u that do
other things?
The r prefix creates a raw string (e.g., r'\t' is a backslash + t instead of a tab), and triple quotes '''...''' or """...""" allow multi-line string literals.
To quote the Python 2.x documentation:
A prefix of 'b' or 'B' is ignored in
Python 2; it indicates that the
literal should become a bytes literal
in Python 3 (e.g. when code is
automatically converted with 2to3). A
'u' or 'b' prefix may be followed by
an 'r' prefix.
The Python 3 documentation states:
Bytes literals are always prefixed with 'b' or 'B'; they produce an instance of the bytes type instead of the str type. They may only contain ASCII characters; bytes with a numeric value of 128 or greater must be expressed with escapes.
The b denotes a byte string.
Bytes are the actual data. Strings are an abstraction.
If you had multi-character string object and you took a single character, it would be a string, and it might be more than 1 byte in size depending on encoding.
If took 1 byte with a byte string, you'd get a single 8-bit value from 0-255 and it might not represent a complete character if those characters due to encoding were > 1 byte.
TBH I'd use strings unless I had some specific low level reason to use bytes.
From server side, if we send any response, it will be sent in the form of byte type, so it will appear in the client as b'Response from server'
In order get rid of b'....' simply use below code:
Server file:
stri="Response from server"
c.send(stri.encode())
Client file:
print(s.recv(1024).decode())
then it will print Response from server
The answer to the question is that, it does:
data.encode()
and in order to decode it(remove the b, because sometimes you don't need it)
use:
data.decode()
Here's an example where the absence of b would throw a TypeError exception in Python 3.x
>>> f=open("new", "wb")
>>> f.write("Hello Python!")
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: 'str' does not support the buffer interface
Adding a b prefix would fix the problem.
It turns it into a bytes literal (or str in 2.x), and is valid for 2.6+.
The r prefix causes backslashes to be "uninterpreted" (not ignored, and the difference does matter).
In addition to what others have said, note that a single character in unicode can consist of multiple bytes.
The way unicode works is that it took the old ASCII format (7-bit code that looks like 0xxx xxxx) and added multi-bytes sequences where all bytes start with 1 (1xxx xxxx) to represent characters beyond ASCII so that Unicode would be backwards-compatible with ASCII.
>>> len('Öl') # German word for 'oil' with 2 characters
2
>>> 'Öl'.encode('UTF-8') # convert str to bytes
b'\xc3\x96l'
>>> len('Öl'.encode('UTF-8')) # 3 bytes encode 2 characters !
3
You can use JSON to convert it to dictionary
import json
data = b'{"key":"value"}'
print(json.loads(data))
{"key":"value"}
FLASK:
This is an example from flask. Run this on terminal line:
import requests
requests.post(url='http://localhost(example)/',json={'key':'value'})
In flask/routes.py
#app.route('/', methods=['POST'])
def api_script_add():
print(request.data) # --> b'{"hi":"Hello"}'
print(json.loads(request.data))
return json.loads(request.data)
{'key':'value'}
b"hello" is not a string (even though it looks like one), but a byte sequence. It is a sequence of 5 numbers, which, if you mapped them to a character table, would look like h e l l o. However the value itself is not a string, Python just has a convenient syntax for defining byte sequences using text characters rather than the numbers itself. This saves you some typing, and also often byte sequences are meant to be interpreted as characters. However, this is not always the case - for example, reading a JPG file will produce a sequence of nonsense letters inside b"..." because JPGs have a non-text structure.
.encode() and .decode() convert between strings and bytes.
bytes(somestring.encode()) is the solution that worked for me in python 3.
def compare_types():
output = b'sometext'
print(output)
print(type(output))
somestring = 'sometext'
encoded_string = somestring.encode()
output = bytes(encoded_string)
print(output)
print(type(output))
compare_types()
Apparently, the following is the valid syntax:
b'The string'
I would like to know:
What does this b character in front of the string mean?
What are the effects of using it?
What are appropriate situations to use it?
I found a related question right here on SO, but that question is about PHP though, and it states the b is used to indicate the string is binary, as opposed to Unicode, which was needed for code to be compatible from version of PHP < 6, when migrating to PHP 6. I don't think this applies to Python.
I did find this documentation on the Python site about using a u character in the same syntax to specify a string as Unicode. Unfortunately, it doesn't mention the b character anywhere in that document.
Also, just out of curiosity, are there more symbols than the b and u that do other things?
Python 3.x makes a clear distinction between the types:
str = '...' literals = a sequence of Unicode characters (Latin-1, UCS-2 or UCS-4, depending on the widest character in the string)
bytes = b'...' literals = a sequence of octets (integers between 0 and 255)
If you're familiar with:
Java or C#, think of str as String and bytes as byte[];
SQL, think of str as NVARCHAR and bytes as BINARY or BLOB;
Windows registry, think of str as REG_SZ and bytes as REG_BINARY.
If you're familiar with C(++), then forget everything you've learned about char and strings, because a character is not a byte. That idea is long obsolete.
You use str when you want to represent text.
print('שלום עולם')
You use bytes when you want to represent low-level binary data like structs.
NaN = struct.unpack('>d', b'\xff\xf8\x00\x00\x00\x00\x00\x00')[0]
You can encode a str to a bytes object.
>>> '\uFEFF'.encode('UTF-8')
b'\xef\xbb\xbf'
And you can decode a bytes into a str.
>>> b'\xE2\x82\xAC'.decode('UTF-8')
'€'
But you can't freely mix the two types.
>>> b'\xEF\xBB\xBF' + 'Text with a UTF-8 BOM'
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: can't concat bytes to str
The b'...' notation is somewhat confusing in that it allows the bytes 0x01-0x7F to be specified with ASCII characters instead of hex numbers.
>>> b'A' == b'\x41'
True
But I must emphasize, a character is not a byte.
>>> 'A' == b'A'
False
In Python 2.x
Pre-3.0 versions of Python lacked this kind of distinction between text and binary data. Instead, there was:
unicode = u'...' literals = sequence of Unicode characters = 3.x str
str = '...' literals = sequences of confounded bytes/characters
Usually text, encoded in some unspecified encoding.
But also used to represent binary data like struct.pack output.
In order to ease the 2.x-to-3.x transition, the b'...' literal syntax was backported to Python 2.6, in order to allow distinguishing binary strings (which should be bytes in 3.x) from text strings (which should be str in 3.x). The b prefix does nothing in 2.x, but tells the 2to3 script not to convert it to a Unicode string in 3.x.
So yes, b'...' literals in Python have the same purpose that they do in PHP.
Also, just out of curiosity, are there
more symbols than the b and u that do
other things?
The r prefix creates a raw string (e.g., r'\t' is a backslash + t instead of a tab), and triple quotes '''...''' or """...""" allow multi-line string literals.
To quote the Python 2.x documentation:
A prefix of 'b' or 'B' is ignored in
Python 2; it indicates that the
literal should become a bytes literal
in Python 3 (e.g. when code is
automatically converted with 2to3). A
'u' or 'b' prefix may be followed by
an 'r' prefix.
The Python 3 documentation states:
Bytes literals are always prefixed with 'b' or 'B'; they produce an instance of the bytes type instead of the str type. They may only contain ASCII characters; bytes with a numeric value of 128 or greater must be expressed with escapes.
The b denotes a byte string.
Bytes are the actual data. Strings are an abstraction.
If you had multi-character string object and you took a single character, it would be a string, and it might be more than 1 byte in size depending on encoding.
If took 1 byte with a byte string, you'd get a single 8-bit value from 0-255 and it might not represent a complete character if those characters due to encoding were > 1 byte.
TBH I'd use strings unless I had some specific low level reason to use bytes.
From server side, if we send any response, it will be sent in the form of byte type, so it will appear in the client as b'Response from server'
In order get rid of b'....' simply use below code:
Server file:
stri="Response from server"
c.send(stri.encode())
Client file:
print(s.recv(1024).decode())
then it will print Response from server
The answer to the question is that, it does:
data.encode()
and in order to decode it(remove the b, because sometimes you don't need it)
use:
data.decode()
Here's an example where the absence of b would throw a TypeError exception in Python 3.x
>>> f=open("new", "wb")
>>> f.write("Hello Python!")
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: 'str' does not support the buffer interface
Adding a b prefix would fix the problem.
It turns it into a bytes literal (or str in 2.x), and is valid for 2.6+.
The r prefix causes backslashes to be "uninterpreted" (not ignored, and the difference does matter).
In addition to what others have said, note that a single character in unicode can consist of multiple bytes.
The way unicode works is that it took the old ASCII format (7-bit code that looks like 0xxx xxxx) and added multi-bytes sequences where all bytes start with 1 (1xxx xxxx) to represent characters beyond ASCII so that Unicode would be backwards-compatible with ASCII.
>>> len('Öl') # German word for 'oil' with 2 characters
2
>>> 'Öl'.encode('UTF-8') # convert str to bytes
b'\xc3\x96l'
>>> len('Öl'.encode('UTF-8')) # 3 bytes encode 2 characters !
3
You can use JSON to convert it to dictionary
import json
data = b'{"key":"value"}'
print(json.loads(data))
{"key":"value"}
FLASK:
This is an example from flask. Run this on terminal line:
import requests
requests.post(url='http://localhost(example)/',json={'key':'value'})
In flask/routes.py
#app.route('/', methods=['POST'])
def api_script_add():
print(request.data) # --> b'{"hi":"Hello"}'
print(json.loads(request.data))
return json.loads(request.data)
{'key':'value'}
b"hello" is not a string (even though it looks like one), but a byte sequence. It is a sequence of 5 numbers, which, if you mapped them to a character table, would look like h e l l o. However the value itself is not a string, Python just has a convenient syntax for defining byte sequences using text characters rather than the numbers itself. This saves you some typing, and also often byte sequences are meant to be interpreted as characters. However, this is not always the case - for example, reading a JPG file will produce a sequence of nonsense letters inside b"..." because JPGs have a non-text structure.
.encode() and .decode() convert between strings and bytes.
bytes(somestring.encode()) is the solution that worked for me in python 3.
def compare_types():
output = b'sometext'
print(output)
print(type(output))
somestring = 'sometext'
encoded_string = somestring.encode()
output = bytes(encoded_string)
print(output)
print(type(output))
compare_types()
Apparently, the following is the valid syntax:
b'The string'
I would like to know:
What does this b character in front of the string mean?
What are the effects of using it?
What are appropriate situations to use it?
I found a related question right here on SO, but that question is about PHP though, and it states the b is used to indicate the string is binary, as opposed to Unicode, which was needed for code to be compatible from version of PHP < 6, when migrating to PHP 6. I don't think this applies to Python.
I did find this documentation on the Python site about using a u character in the same syntax to specify a string as Unicode. Unfortunately, it doesn't mention the b character anywhere in that document.
Also, just out of curiosity, are there more symbols than the b and u that do other things?
Python 3.x makes a clear distinction between the types:
str = '...' literals = a sequence of Unicode characters (Latin-1, UCS-2 or UCS-4, depending on the widest character in the string)
bytes = b'...' literals = a sequence of octets (integers between 0 and 255)
If you're familiar with:
Java or C#, think of str as String and bytes as byte[];
SQL, think of str as NVARCHAR and bytes as BINARY or BLOB;
Windows registry, think of str as REG_SZ and bytes as REG_BINARY.
If you're familiar with C(++), then forget everything you've learned about char and strings, because a character is not a byte. That idea is long obsolete.
You use str when you want to represent text.
print('שלום עולם')
You use bytes when you want to represent low-level binary data like structs.
NaN = struct.unpack('>d', b'\xff\xf8\x00\x00\x00\x00\x00\x00')[0]
You can encode a str to a bytes object.
>>> '\uFEFF'.encode('UTF-8')
b'\xef\xbb\xbf'
And you can decode a bytes into a str.
>>> b'\xE2\x82\xAC'.decode('UTF-8')
'€'
But you can't freely mix the two types.
>>> b'\xEF\xBB\xBF' + 'Text with a UTF-8 BOM'
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: can't concat bytes to str
The b'...' notation is somewhat confusing in that it allows the bytes 0x01-0x7F to be specified with ASCII characters instead of hex numbers.
>>> b'A' == b'\x41'
True
But I must emphasize, a character is not a byte.
>>> 'A' == b'A'
False
In Python 2.x
Pre-3.0 versions of Python lacked this kind of distinction between text and binary data. Instead, there was:
unicode = u'...' literals = sequence of Unicode characters = 3.x str
str = '...' literals = sequences of confounded bytes/characters
Usually text, encoded in some unspecified encoding.
But also used to represent binary data like struct.pack output.
In order to ease the 2.x-to-3.x transition, the b'...' literal syntax was backported to Python 2.6, in order to allow distinguishing binary strings (which should be bytes in 3.x) from text strings (which should be str in 3.x). The b prefix does nothing in 2.x, but tells the 2to3 script not to convert it to a Unicode string in 3.x.
So yes, b'...' literals in Python have the same purpose that they do in PHP.
Also, just out of curiosity, are there
more symbols than the b and u that do
other things?
The r prefix creates a raw string (e.g., r'\t' is a backslash + t instead of a tab), and triple quotes '''...''' or """...""" allow multi-line string literals.
To quote the Python 2.x documentation:
A prefix of 'b' or 'B' is ignored in
Python 2; it indicates that the
literal should become a bytes literal
in Python 3 (e.g. when code is
automatically converted with 2to3). A
'u' or 'b' prefix may be followed by
an 'r' prefix.
The Python 3 documentation states:
Bytes literals are always prefixed with 'b' or 'B'; they produce an instance of the bytes type instead of the str type. They may only contain ASCII characters; bytes with a numeric value of 128 or greater must be expressed with escapes.
The b denotes a byte string.
Bytes are the actual data. Strings are an abstraction.
If you had multi-character string object and you took a single character, it would be a string, and it might be more than 1 byte in size depending on encoding.
If took 1 byte with a byte string, you'd get a single 8-bit value from 0-255 and it might not represent a complete character if those characters due to encoding were > 1 byte.
TBH I'd use strings unless I had some specific low level reason to use bytes.
From server side, if we send any response, it will be sent in the form of byte type, so it will appear in the client as b'Response from server'
In order get rid of b'....' simply use below code:
Server file:
stri="Response from server"
c.send(stri.encode())
Client file:
print(s.recv(1024).decode())
then it will print Response from server
The answer to the question is that, it does:
data.encode()
and in order to decode it(remove the b, because sometimes you don't need it)
use:
data.decode()
Here's an example where the absence of b would throw a TypeError exception in Python 3.x
>>> f=open("new", "wb")
>>> f.write("Hello Python!")
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: 'str' does not support the buffer interface
Adding a b prefix would fix the problem.
It turns it into a bytes literal (or str in 2.x), and is valid for 2.6+.
The r prefix causes backslashes to be "uninterpreted" (not ignored, and the difference does matter).
In addition to what others have said, note that a single character in unicode can consist of multiple bytes.
The way unicode works is that it took the old ASCII format (7-bit code that looks like 0xxx xxxx) and added multi-bytes sequences where all bytes start with 1 (1xxx xxxx) to represent characters beyond ASCII so that Unicode would be backwards-compatible with ASCII.
>>> len('Öl') # German word for 'oil' with 2 characters
2
>>> 'Öl'.encode('UTF-8') # convert str to bytes
b'\xc3\x96l'
>>> len('Öl'.encode('UTF-8')) # 3 bytes encode 2 characters !
3
You can use JSON to convert it to dictionary
import json
data = b'{"key":"value"}'
print(json.loads(data))
{"key":"value"}
FLASK:
This is an example from flask. Run this on terminal line:
import requests
requests.post(url='http://localhost(example)/',json={'key':'value'})
In flask/routes.py
#app.route('/', methods=['POST'])
def api_script_add():
print(request.data) # --> b'{"hi":"Hello"}'
print(json.loads(request.data))
return json.loads(request.data)
{'key':'value'}
b"hello" is not a string (even though it looks like one), but a byte sequence. It is a sequence of 5 numbers, which, if you mapped them to a character table, would look like h e l l o. However the value itself is not a string, Python just has a convenient syntax for defining byte sequences using text characters rather than the numbers itself. This saves you some typing, and also often byte sequences are meant to be interpreted as characters. However, this is not always the case - for example, reading a JPG file will produce a sequence of nonsense letters inside b"..." because JPGs have a non-text structure.
.encode() and .decode() convert between strings and bytes.
bytes(somestring.encode()) is the solution that worked for me in python 3.
def compare_types():
output = b'sometext'
print(output)
print(type(output))
somestring = 'sometext'
encoded_string = somestring.encode()
output = bytes(encoded_string)
print(output)
print(type(output))
compare_types()
My question is about python 3.0 strings.
My understanding is that for the line str = "a", the charcter 'a' is encoded (using utf-8 - for example) and stored in the str object. If UTF-8 representation of 'a' is 1 byte the string is 1 byte long. Am I right?
if the above is true what happens when we read a binary file using read(). Suppose I have a two byte file with two bytes of binary data and I read it in a string using read command like
open(fileName, mode='rb')
str= file.read()
now str will be two bytes long and each byte will be what was stored in the fileName. Am I right?
If I am right in the above point then the str object is not in any particual encoding format (like UTF, etc.), So what does it mean that python strings are always unicode? Also what will happen if I call str.encode(). It will make no sense?
As the str object read from file is actually a array of bytes. Is there any way to convert it to bytearray type?
You are confused. "Encodings" pertain to byte strings, not to unicode strings. Meaningful statements: "This byte string is utf-8 encoded.", "This byte string is 2 bytes long." Meaningless statements: "This unicode string is utf-8 encoded", "This unicode string is 2 bytes long"
str = "a" means "create a unicode string 'a' and a reference to it named str". Unicode strings are of course stored in some encoding because it needs to exist as bytes in memory, but that is not relevant. All your code treats it as if it has no encoding at all--it has been abstracted away from bytes. A unicode string is a sequence of unicode code points (i.e. of integers that represent characters).
Yes and no. str here (the return value of read()) is a byte string, not a unicode string. "a" != b"a".
Your byte-string str possesses an unknown encoding and must be decoded to produce a unicode string. Byte strings don't have an encode() method because it is meaningless--they are either already an encoding of a unicode string, or they are not representing a unicode string at all (e.g. an image).
It's not an array of bytes, it's a byte-string. A bytearray is a mutable list of bytes. You can produce a bytearray with bytearray(byte_string), but bytearrays are intended for fairly specialized uses (e.g., to avoid copying for send-recv buffers), not casual use. Normally you just want a byte string.
When you read a file in binary mode, the value returned from the read() method is a bytes object, not a str object. The documentation covers this in depth.
>>> with open('foo', mode='rb') as f: s = f.read()
...
>>> s
b'abc\n'
>>> len(s)
4
>>> type(s)
<class 'bytes'>
Python strings store Unicode codepoints.
Codepoints are not the same thing as bytes. Bytes are a computer representation of numbers (most commonly between 0 and 255), and those numbers can be translated to codepoints through the process of decoding, and in the other direction with encoding. Python 3 strings contain codepoints, one for each character in the text.
Python source code can define string literals using a series of bytes, that the interpreter decodes to unicode using the UTF-8 codec by default, but you can set other codecs at the top of the file. On disk, the letter a in UTF-8 encoding is indeed just one byte, that is the nature of the UTF-8 standard.
If you read a file in text mode, Python applies the decoding process for you automatically, but when you open it in binary mode, no decoding is done and you get a bytes object instead. The contents of that object should reflect the contents of the file exactly. Note that it is not of type str, it is not unicode, it is not even a Python string. To turn bytes into a string you'd need to explicitly decode with the .decode() method.
A bytearray is trivially created from a bytes value, just call bytesarray() on it.
Apparently, the following is the valid syntax:
b'The string'
I would like to know:
What does this b character in front of the string mean?
What are the effects of using it?
What are appropriate situations to use it?
I found a related question right here on SO, but that question is about PHP though, and it states the b is used to indicate the string is binary, as opposed to Unicode, which was needed for code to be compatible from version of PHP < 6, when migrating to PHP 6. I don't think this applies to Python.
I did find this documentation on the Python site about using a u character in the same syntax to specify a string as Unicode. Unfortunately, it doesn't mention the b character anywhere in that document.
Also, just out of curiosity, are there more symbols than the b and u that do other things?
Python 3.x makes a clear distinction between the types:
str = '...' literals = a sequence of Unicode characters (Latin-1, UCS-2 or UCS-4, depending on the widest character in the string)
bytes = b'...' literals = a sequence of octets (integers between 0 and 255)
If you're familiar with:
Java or C#, think of str as String and bytes as byte[];
SQL, think of str as NVARCHAR and bytes as BINARY or BLOB;
Windows registry, think of str as REG_SZ and bytes as REG_BINARY.
If you're familiar with C(++), then forget everything you've learned about char and strings, because a character is not a byte. That idea is long obsolete.
You use str when you want to represent text.
print('שלום עולם')
You use bytes when you want to represent low-level binary data like structs.
NaN = struct.unpack('>d', b'\xff\xf8\x00\x00\x00\x00\x00\x00')[0]
You can encode a str to a bytes object.
>>> '\uFEFF'.encode('UTF-8')
b'\xef\xbb\xbf'
And you can decode a bytes into a str.
>>> b'\xE2\x82\xAC'.decode('UTF-8')
'€'
But you can't freely mix the two types.
>>> b'\xEF\xBB\xBF' + 'Text with a UTF-8 BOM'
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: can't concat bytes to str
The b'...' notation is somewhat confusing in that it allows the bytes 0x01-0x7F to be specified with ASCII characters instead of hex numbers.
>>> b'A' == b'\x41'
True
But I must emphasize, a character is not a byte.
>>> 'A' == b'A'
False
In Python 2.x
Pre-3.0 versions of Python lacked this kind of distinction between text and binary data. Instead, there was:
unicode = u'...' literals = sequence of Unicode characters = 3.x str
str = '...' literals = sequences of confounded bytes/characters
Usually text, encoded in some unspecified encoding.
But also used to represent binary data like struct.pack output.
In order to ease the 2.x-to-3.x transition, the b'...' literal syntax was backported to Python 2.6, in order to allow distinguishing binary strings (which should be bytes in 3.x) from text strings (which should be str in 3.x). The b prefix does nothing in 2.x, but tells the 2to3 script not to convert it to a Unicode string in 3.x.
So yes, b'...' literals in Python have the same purpose that they do in PHP.
Also, just out of curiosity, are there
more symbols than the b and u that do
other things?
The r prefix creates a raw string (e.g., r'\t' is a backslash + t instead of a tab), and triple quotes '''...''' or """...""" allow multi-line string literals.
To quote the Python 2.x documentation:
A prefix of 'b' or 'B' is ignored in
Python 2; it indicates that the
literal should become a bytes literal
in Python 3 (e.g. when code is
automatically converted with 2to3). A
'u' or 'b' prefix may be followed by
an 'r' prefix.
The Python 3 documentation states:
Bytes literals are always prefixed with 'b' or 'B'; they produce an instance of the bytes type instead of the str type. They may only contain ASCII characters; bytes with a numeric value of 128 or greater must be expressed with escapes.
The b denotes a byte string.
Bytes are the actual data. Strings are an abstraction.
If you had multi-character string object and you took a single character, it would be a string, and it might be more than 1 byte in size depending on encoding.
If took 1 byte with a byte string, you'd get a single 8-bit value from 0-255 and it might not represent a complete character if those characters due to encoding were > 1 byte.
TBH I'd use strings unless I had some specific low level reason to use bytes.
From server side, if we send any response, it will be sent in the form of byte type, so it will appear in the client as b'Response from server'
In order get rid of b'....' simply use below code:
Server file:
stri="Response from server"
c.send(stri.encode())
Client file:
print(s.recv(1024).decode())
then it will print Response from server
The answer to the question is that, it does:
data.encode()
and in order to decode it(remove the b, because sometimes you don't need it)
use:
data.decode()
Here's an example where the absence of b would throw a TypeError exception in Python 3.x
>>> f=open("new", "wb")
>>> f.write("Hello Python!")
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: 'str' does not support the buffer interface
Adding a b prefix would fix the problem.
It turns it into a bytes literal (or str in 2.x), and is valid for 2.6+.
The r prefix causes backslashes to be "uninterpreted" (not ignored, and the difference does matter).
In addition to what others have said, note that a single character in unicode can consist of multiple bytes.
The way unicode works is that it took the old ASCII format (7-bit code that looks like 0xxx xxxx) and added multi-bytes sequences where all bytes start with 1 (1xxx xxxx) to represent characters beyond ASCII so that Unicode would be backwards-compatible with ASCII.
>>> len('Öl') # German word for 'oil' with 2 characters
2
>>> 'Öl'.encode('UTF-8') # convert str to bytes
b'\xc3\x96l'
>>> len('Öl'.encode('UTF-8')) # 3 bytes encode 2 characters !
3
You can use JSON to convert it to dictionary
import json
data = b'{"key":"value"}'
print(json.loads(data))
{"key":"value"}
FLASK:
This is an example from flask. Run this on terminal line:
import requests
requests.post(url='http://localhost(example)/',json={'key':'value'})
In flask/routes.py
#app.route('/', methods=['POST'])
def api_script_add():
print(request.data) # --> b'{"hi":"Hello"}'
print(json.loads(request.data))
return json.loads(request.data)
{'key':'value'}
b"hello" is not a string (even though it looks like one), but a byte sequence. It is a sequence of 5 numbers, which, if you mapped them to a character table, would look like h e l l o. However the value itself is not a string, Python just has a convenient syntax for defining byte sequences using text characters rather than the numbers itself. This saves you some typing, and also often byte sequences are meant to be interpreted as characters. However, this is not always the case - for example, reading a JPG file will produce a sequence of nonsense letters inside b"..." because JPGs have a non-text structure.
.encode() and .decode() convert between strings and bytes.
bytes(somestring.encode()) is the solution that worked for me in python 3.
def compare_types():
output = b'sometext'
print(output)
print(type(output))
somestring = 'sometext'
encoded_string = somestring.encode()
output = bytes(encoded_string)
print(output)
print(type(output))
compare_types()