a bytes-like object is required, not 'str' (python) [duplicate] - python

I've very recently migrated to Python 3.5.
This code was working properly in Python 2.7:
with open(fname, 'rb') as f:
lines = [x.strip() for x in f.readlines()]
for line in lines:
tmp = line.strip().lower()
if 'some-pattern' in tmp: continue
# ... code
But in 3.5, on the if 'some-pattern' in tmp: continue line, I get an error which says:
TypeError: a bytes-like object is required, not 'str'
I was unable to fix the problem using .decode() on either side of the in, nor could I fix it using
if tmp.find('some-pattern') != -1: continue
What is wrong, and how do I fix it?

You opened the file in binary mode:
with open(fname, 'rb') as f:
This means that all data read from the file is returned as bytes objects, not str. You cannot then use a string in a containment test:
if 'some-pattern' in tmp: continue
You'd have to use a bytes object to test against tmp instead:
if b'some-pattern' in tmp: continue
or open the file as a textfile instead by replacing the 'rb' mode with 'r'.

You can encode your string by using .encode()
Example:
'Hello World'.encode()
As the error describes, in order to write a string to a file you need to encode it to a byte-like object first, and encode() is encoding it to a byte-string.

Like it has been already mentioned, you are reading the file in binary mode and then creating a list of bytes. In your following for loop you are comparing string to bytes and that is where the code is failing.
Decoding the bytes while adding to the list should work. The changed code should look as follows:
with open(fname, 'rb') as f:
lines = [x.decode('utf8').strip() for x in f.readlines()]
The bytes type was introduced in Python 3 and that is why your code worked in Python 2. In Python 2 there was no data type for bytes:
>>> s=bytes('hello')
>>> type(s)
<type 'str'>

You have to change from wb to w:
def __init__(self):
self.myCsv = csv.writer(open('Item.csv', 'wb'))
self.myCsv.writerow(['title', 'link'])
to
def __init__(self):
self.myCsv = csv.writer(open('Item.csv', 'w'))
self.myCsv.writerow(['title', 'link'])
After changing this, the error disappears, but you can't write to the file (in my case). So after all, I don't have an answer?
Source: How to remove ^M
Changing to 'rb' brings me the other error: io.UnsupportedOperation: write

Use the encode() function along with the hardcoded string value given in a single quote.
Example:
file.write(answers[i] + '\n'.encode())
Or
line.split(' +++$+++ '.encode())

For this small example, adding the only b before
'GET http://www.py4inf.com/code/romeo.txt HTTP/1.0\n\n' solved my problem:
import socket
mysock = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
mysock.connect(('www.py4inf.com', 80))
mysock.send(b'GET http://www.py4inf.com/code/romeo.txt HTTP/1.0\n\n')
while True:
data = mysock.recv(512)
if (len(data) < 1):
break
print (data);
mysock.close()
What does the 'b' character do in front of a string literal?

You opened the file in binary mode:
The following code will throw
a TypeError: a bytes-like object is required, not 'str'.
for line in lines:
print(type(line))# <class 'bytes'>
if 'substring' in line:
print('success')
The following code will work - you have to use the decode() function:
for line in lines:
line = line.decode()
print(type(line))# <class 'str'>
if 'substring' in line:
print('success')

Try opening your file as text:
with open(fname, 'rt') as f:
lines = [x.strip() for x in f.readlines()]
Additionally, here is a link for Python 3.x on the official page:
io — Core tools for working with streams.
And this is the open function: open
If you are really trying to handle it as a binary then consider encoding your string.

I got this error when I was trying to convert a char (or string) to bytes, the code was something like this with Python 2.7:
# -*- coding: utf-8 -*-
print(bytes('ò'))
This is the way of Python 2.7 when dealing with Unicode characters.
This won't work with Python 3.6, since bytes require an extra argument for encoding, but this can be little tricky, since different encoding may output different result:
print(bytes('ò', 'iso_8859_1')) # prints: b'\xf2'
print(bytes('ò', 'utf-8')) # prints: b'\xc3\xb2'
In my case I had to use iso_8859_1 when encoding bytes in order to solve the issue.

Summary
Python 2.x encouraged many bad habits WRT text handling. In particular, its type named str does not actually represent text per the Unicode standard (that type is unicode), and the default "string literal" in fact produces a sequence of raw bytes - with some convenience functions for treating it like a string, if you can get away with assuming a "code page" style encoding.
In 3.x, "string literals" now produce actual strings, and built-in functionality no longer does any implicit conversions between the two types. Thus, the same code now has a TypeError, because the literal and the variable are of incompatible types. To fix the problem, one of the values must be either replaced or converted, so that the types match.
The Python documentation has an extremely detailed guide to working with Unicode properly.
In the example in the question, the input file is processed as if it contains text. Therefore, the file should have been opened in a text mode in the first place. The only good reason the file would have been opened in binary mode even in 2.x is to avoid universal newline translation; in 3.x, this is done by specifying the newline keyword parameter when opening a file in text mode.
To read a file as text properly requires knowing a text encoding, which is specified in the code by (string) name. The encoding iso-8859-1 is a safe fallback; it interprets each byte separately, as representing one of the first 256 Unicode code points, in order (so it will never raise an exception due to invalid data). utf-8 is much more common as of the time of writing, but it does not accept arbitrary data. (However, in many cases, for English text, the distinction will not matter; both of those encodings, and many more, are supersets of ASCII.)
Thus:
with open(fname, 'r', newline='\n', encoding='iso-8859-1') as f:
lines = [x.strip() for x in f.readlines()]
# proceed as before
# If the results are wrong, take additional steps to ascertain the correct encoding
How the error is created when migrating from 2.x to 3.x
In 2.x, 'some-pattern' creates a str, i.e. a sequence of bytes that the programmer is then likely to pretend is text. The str type is the same as the bytes type, and different from the unicode type that properly represents text. Many methods are offered to treat this data as if it were text, but it is not a proper representation of text. The meaning of each value as a text character (the encoding) is assumed. (In order to enable the illusion of raw data as "text", there would sometimes be implicit conversions between the str and unicode types. However, this results in confusing errors of its own - such as getting UnicodeDecodeError from an attempt to encode, or vice-versa).
In 3.x, 'some-pattern' creates what is also called a str; but now str means the Unicode-using, properly-text-representing string type. (unicode is no longer used as a type name, and only bytes refers to the sequence-of-bytes type.) Some changes were made to bytes to dissociate it from the text-with-assumed-encoding interpretation (in particular, indexing into a bytes object now results in an int, rather than a 1-element bytes), but many strange legacy methods persist (including ones rarely used even with actual strings any more, like zfill).
Why this causes a problem
The data, tmp, is a bytes instance. It came from a binary source: in this case, a file opened with a 'b' file mode. In other cases, it could come from a raw network socket, a web request made with urllib or similar, or some other API call.
This means that it cannot do anything meaningful in combination with a string. The elements of a string are Unicode code points (i.e., abstractions that represent, for the most part, text characters, in a universal form that represents all world languages and many other symbols). The elements of a bytes are, well, bytes. (Specifically in 3.x, they are interpreted as unsigned integers ranging from 0 to 255 inclusive.)
When the code was migrated, the literal 'some-pattern' went from describing a bytes, to describing text. Thus, the code went from making a legal comparison (byte-sequence to byte-sequence), to making an illegal one (string to byte-sequence).
Fixing the problem
In order to operate on a string and a byte-sequence - whether it's checking for equality with ==, lexicographic comparison with <, substring search with in, concatenation with +, or anything else - either the string must be converted to a byte-sequence, or vice-versa. In general, only one of these will be the correct, sensible answer, and it will depend on the context.
Fixing the source
Sometimes, one of the values can be seen to be "wrong" in the first place. For example, if reading the file was intended to result in text, then it should have been opened in a text mode. In 3.x, the file encoding can simply be passed as an encoding keyword argument to open, and conversion to Unicode is handled seamlessly without having to feed a binary file to an explicit translation step (thus, universal newline handling still takes place seamlessly).
In the case of the original example, that could look like:
with open(fname, 'r') as f:
lines = [x.strip() for x in f.readlines()]
This example assumes a platform-dependent default encoding for the file. This will normally work for files that were created in straightforward ways, on the same computer. In the general case, however, the encoding of the data must be known in order to work with it properly.
If the encoding is known to be, for example, UTF-8, that is trivially specified:
with open(fname, 'r', encoding='utf-8') as f:
lines = [x.strip() for x in f.readlines()]
Similarly, a string literal that should have been a bytes literal is simply missing a prefix: to make the bytes sequence representing integer values [101, 120, 97, 109, 112, 108, 101] (i.e., the ASCII values of the letters example), write the bytes literal b'example', rather than the string literal `'example'). Similarly the other way around.
In the case of the original example, that would look like:
if b'some-pattern' in tmp:
There is a safeguard built in to this: the bytes literal syntax only allows ASCII characters, so something like b'ëxãmþlê' will be caught as a SyntaxError, regardless of the encoding of the source file (since it is not clear which byte values are meant; in the old implied-encoding schemes, the ASCII range was well established, but everything else was up in the air.) Of course, bytes literals with elements representing values 128..255 can still be written by using \x escaping for those values: for example, b'\xebx\xe3m\xfel\xea' will produce a byte-sequence corresponding to the text ëxãmþlê in Latin-1 (ISO 8859-1) encoding.
Converting, when appropriate
Conversion between byte-sequences and text is only possible when an encoding has been determined. It has always been so; we just used to assume an encoding locally, and then mostly ignore that we had done so. (Programmers in places like East Asia have been more aware of the problem historically, because they commonly need to work with scripts that have more than 256 distinct symbols, and thus their text requires multi-byte encodings.)
In 3.x, because there is no pressure to be able to treat byte-sequences implicitly as text with an assumed encoding, there are therefore no implicit conversion steps behind the scenes. This means that understanding the API is straightforward: Bytes are raw data; therefore, they are used to encode text, which is an abstraction. Therefore, the .encode() method is provided by str (which represents text), in order to encode text into raw data. Similarly, the .decode() method is provided by bytes (which represents a byte-sequence), in order to decode raw data into text.
Applying these to the example code, again supposing UTF-8 encoding is appropriate, gives:
if 'some-pattern'.encode('utf-8') in tmp:
and
if 'some-pattern' in tmp.decode('utf-8'):

Related

How can I effectively store binary data in a file that's in a text format like CSV?

I'm currently working on a password storage program in Python, though C would likely be faster. I've been trying for the past hour or so to find a way to store a bytes object in a CSV file. I'm hashing the passwords with their own salt, and then storing that, and grabbing it again to check the password. It works perfectly well when it's stored in memory.
salt = os.urandom(64)
hash = hashlib.pbkdf2_hmac(
'sha256',
password.encode('utf-8'),
salt,
1000000
)
storage = salt + hash
salt_from_store = storage[:64]
hash_from_store = storage[64:]
However, when I try storing it in a CSV file, so it doesn't have to be constantly running, I get an error,
TypeError: write() argument must be str, not bytes
So, I converted it to a string using,
str(storage)
and that wrote just fine. But then, when I get it from the file, it's still a string, and the length goes from 128 (bytes) to 300+ (chars). It's also never consistent. I don't know the encoding, so I can't change it like that, when I print the bytes, it's a bunch of characters with backslashes and X's
b'\xfd\x3a'
and occasionally some random special characters. I'm not sure if there's a way to convert that to an int, and let it be converted back. Another issue is that I've found a way to do it, by changing
b"\xf1\x96"
to
"b\xf1\x96"
which prints the encoded text, rather than the bytes it's made up of. However, I don't know if that's a good way of changing it, and if it is, if there's a way to do it without something like
bytes[0] = '"'
bytes[1] = 'b'
If you want to save bytes as a string, you should probably encode them in a format made for this like base64. This is more efficient with space than directly writing hex.
Trying to convert arbitrary bytes to an encoding like utf-8 directly will likely result in UnicodeDecodeError errors.
In your case, you could do something like:
import os, hashlib, base64
password = "top_secret"
salt = os.urandom(64)
hash = hashlib.pbkdf2_hmac(
'sha256',
password.encode('utf-8'),
salt,
1000000
)
storage = salt + hash
# convert to a base64 string:
s = base64.b64encode(storage).decode('utf-8')
print(s) # <-- string you can save this to a file
# after reading it back from a file convert back to bytes
the_bytes = base64.b64decode(s)
the_bytes == storage
# True
To write bytes, either write to something that expects to contain bytes, or write text that represents the bytes in some way. CSV is fundamentally a text-based format. If you're going to use a CSV file, then you're going to open it in text mode, and write text to it.
Fundamentally, every file on the hard drive consists of bytes. This implies that, when you open the CSV file, you will be choosing (or using a default) text encoding scheme. So your bytes object will have to be converted twice (to text, and then into the underlying bytes in the file - which you could verify for example with a hex editor) on writing, and twice again on reading. That's just the reality of dealing with mixed data. Thankfully, half that work is taken care of for you automatically (by the open call, or wrappers for that like csv.Reader).
So, I converted it to a string using str(storage)
This is not actually a conversion in the sense that you're most likely interested in. This is asking for a printable, human-readable representation of the object (There is also repr, which asks for a more technically-oriented representation. For str and bytes objects, that's where the enclosing quotation marks come from, among other adjustments. When you print something, its str is used. When you evaluate something at the REPL, you see the repr of the result - except that when the result is None, it doesn't show anything at all). Specifically for dealing with bytes and str objects, Python has a concept of encoding and decoding, which uses explicit .encode (str->bytes) and .decode (bytes->str) methods. These are topics you can easily look up in the documentation (or previous Stack Overflow questions, or on the Internet in general).
when I print the bytes, it's a bunch of characters with backslashes and X's
Yes, this is the form that Python uses to tell you what data exists inside the bytes object. What you're saying here is basically the same as "when I print the list, it's a bunch of list elements with commas surrounded by square brackets", or "when I print the integer, it's a bunch of digit symbols".
But then, when I get it from the file, it's still a string, and the length goes from 128 (bytes) to 300+ (chars).
So decode it again. Of course you do need to encode properly. Everything that you get from the file will be a string, because you are opening the file in text mode, because CSV is a text format. (Incidentally, you are using the csv standard library module for this, right?)
It's also never consistent. I don't know the encoding
So tell it which encoding to use; and if you need to use a consistent amount of text, choose an encoding that consistently maps one byte to one Unicode code point (such as latin-1, also named iso-8859-1). But I suspect you don't actually care how long the text is (if anything, you'd care about the amount of bytes used in the file).
I've found a way to do it, by changing
You can only do this with literal data. Do not think in these terms. The b is part of the language syntax. It is not data.
You could use hex. Let's get some data:
>>> import os
>>> b = os.urandom(10)
>>> b
b'\xc5\xe2{\xdf\xd2\x13\xa7\x0b\xef\x07'
As a hex string that you can write to CSV:
>>> b.hex()
'c5e27bdfd213a70bef07'
Back to bytes:
>>> bytes.fromhex(b.hex())
b'\xc5\xe2{\xdf\xd2\x13\xa7\x0b\xef\x07'

Python 3, send a list over socket [duplicate]

I've very recently migrated to Python 3.5.
This code was working properly in Python 2.7:
with open(fname, 'rb') as f:
lines = [x.strip() for x in f.readlines()]
for line in lines:
tmp = line.strip().lower()
if 'some-pattern' in tmp: continue
# ... code
But in 3.5, on the if 'some-pattern' in tmp: continue line, I get an error which says:
TypeError: a bytes-like object is required, not 'str'
I was unable to fix the problem using .decode() on either side of the in, nor could I fix it using
if tmp.find('some-pattern') != -1: continue
What is wrong, and how do I fix it?
You opened the file in binary mode:
with open(fname, 'rb') as f:
This means that all data read from the file is returned as bytes objects, not str. You cannot then use a string in a containment test:
if 'some-pattern' in tmp: continue
You'd have to use a bytes object to test against tmp instead:
if b'some-pattern' in tmp: continue
or open the file as a textfile instead by replacing the 'rb' mode with 'r'.
You can encode your string by using .encode()
Example:
'Hello World'.encode()
As the error describes, in order to write a string to a file you need to encode it to a byte-like object first, and encode() is encoding it to a byte-string.
Like it has been already mentioned, you are reading the file in binary mode and then creating a list of bytes. In your following for loop you are comparing string to bytes and that is where the code is failing.
Decoding the bytes while adding to the list should work. The changed code should look as follows:
with open(fname, 'rb') as f:
lines = [x.decode('utf8').strip() for x in f.readlines()]
The bytes type was introduced in Python 3 and that is why your code worked in Python 2. In Python 2 there was no data type for bytes:
>>> s=bytes('hello')
>>> type(s)
<type 'str'>
You have to change from wb to w:
def __init__(self):
self.myCsv = csv.writer(open('Item.csv', 'wb'))
self.myCsv.writerow(['title', 'link'])
to
def __init__(self):
self.myCsv = csv.writer(open('Item.csv', 'w'))
self.myCsv.writerow(['title', 'link'])
After changing this, the error disappears, but you can't write to the file (in my case). So after all, I don't have an answer?
Source: How to remove ^M
Changing to 'rb' brings me the other error: io.UnsupportedOperation: write
Use the encode() function along with the hardcoded string value given in a single quote.
Example:
file.write(answers[i] + '\n'.encode())
Or
line.split(' +++$+++ '.encode())
For this small example, adding the only b before
'GET http://www.py4inf.com/code/romeo.txt HTTP/1.0\n\n' solved my problem:
import socket
mysock = socket.socket(socket.AF_INET, socket.SOCK_STREAM)
mysock.connect(('www.py4inf.com', 80))
mysock.send(b'GET http://www.py4inf.com/code/romeo.txt HTTP/1.0\n\n')
while True:
data = mysock.recv(512)
if (len(data) < 1):
break
print (data);
mysock.close()
What does the 'b' character do in front of a string literal?
You opened the file in binary mode:
The following code will throw
a TypeError: a bytes-like object is required, not 'str'.
for line in lines:
print(type(line))# <class 'bytes'>
if 'substring' in line:
print('success')
The following code will work - you have to use the decode() function:
for line in lines:
line = line.decode()
print(type(line))# <class 'str'>
if 'substring' in line:
print('success')
Try opening your file as text:
with open(fname, 'rt') as f:
lines = [x.strip() for x in f.readlines()]
Additionally, here is a link for Python 3.x on the official page:
io — Core tools for working with streams.
And this is the open function: open
If you are really trying to handle it as a binary then consider encoding your string.
I got this error when I was trying to convert a char (or string) to bytes, the code was something like this with Python 2.7:
# -*- coding: utf-8 -*-
print(bytes('ò'))
This is the way of Python 2.7 when dealing with Unicode characters.
This won't work with Python 3.6, since bytes require an extra argument for encoding, but this can be little tricky, since different encoding may output different result:
print(bytes('ò', 'iso_8859_1')) # prints: b'\xf2'
print(bytes('ò', 'utf-8')) # prints: b'\xc3\xb2'
In my case I had to use iso_8859_1 when encoding bytes in order to solve the issue.
Summary
Python 2.x encouraged many bad habits WRT text handling. In particular, its type named str does not actually represent text per the Unicode standard (that type is unicode), and the default "string literal" in fact produces a sequence of raw bytes - with some convenience functions for treating it like a string, if you can get away with assuming a "code page" style encoding.
In 3.x, "string literals" now produce actual strings, and built-in functionality no longer does any implicit conversions between the two types. Thus, the same code now has a TypeError, because the literal and the variable are of incompatible types. To fix the problem, one of the values must be either replaced or converted, so that the types match.
The Python documentation has an extremely detailed guide to working with Unicode properly.
In the example in the question, the input file is processed as if it contains text. Therefore, the file should have been opened in a text mode in the first place. The only good reason the file would have been opened in binary mode even in 2.x is to avoid universal newline translation; in 3.x, this is done by specifying the newline keyword parameter when opening a file in text mode.
To read a file as text properly requires knowing a text encoding, which is specified in the code by (string) name. The encoding iso-8859-1 is a safe fallback; it interprets each byte separately, as representing one of the first 256 Unicode code points, in order (so it will never raise an exception due to invalid data). utf-8 is much more common as of the time of writing, but it does not accept arbitrary data. (However, in many cases, for English text, the distinction will not matter; both of those encodings, and many more, are supersets of ASCII.)
Thus:
with open(fname, 'r', newline='\n', encoding='iso-8859-1') as f:
lines = [x.strip() for x in f.readlines()]
# proceed as before
# If the results are wrong, take additional steps to ascertain the correct encoding
How the error is created when migrating from 2.x to 3.x
In 2.x, 'some-pattern' creates a str, i.e. a sequence of bytes that the programmer is then likely to pretend is text. The str type is the same as the bytes type, and different from the unicode type that properly represents text. Many methods are offered to treat this data as if it were text, but it is not a proper representation of text. The meaning of each value as a text character (the encoding) is assumed. (In order to enable the illusion of raw data as "text", there would sometimes be implicit conversions between the str and unicode types. However, this results in confusing errors of its own - such as getting UnicodeDecodeError from an attempt to encode, or vice-versa).
In 3.x, 'some-pattern' creates what is also called a str; but now str means the Unicode-using, properly-text-representing string type. (unicode is no longer used as a type name, and only bytes refers to the sequence-of-bytes type.) Some changes were made to bytes to dissociate it from the text-with-assumed-encoding interpretation (in particular, indexing into a bytes object now results in an int, rather than a 1-element bytes), but many strange legacy methods persist (including ones rarely used even with actual strings any more, like zfill).
Why this causes a problem
The data, tmp, is a bytes instance. It came from a binary source: in this case, a file opened with a 'b' file mode. In other cases, it could come from a raw network socket, a web request made with urllib or similar, or some other API call.
This means that it cannot do anything meaningful in combination with a string. The elements of a string are Unicode code points (i.e., abstractions that represent, for the most part, text characters, in a universal form that represents all world languages and many other symbols). The elements of a bytes are, well, bytes. (Specifically in 3.x, they are interpreted as unsigned integers ranging from 0 to 255 inclusive.)
When the code was migrated, the literal 'some-pattern' went from describing a bytes, to describing text. Thus, the code went from making a legal comparison (byte-sequence to byte-sequence), to making an illegal one (string to byte-sequence).
Fixing the problem
In order to operate on a string and a byte-sequence - whether it's checking for equality with ==, lexicographic comparison with <, substring search with in, concatenation with +, or anything else - either the string must be converted to a byte-sequence, or vice-versa. In general, only one of these will be the correct, sensible answer, and it will depend on the context.
Fixing the source
Sometimes, one of the values can be seen to be "wrong" in the first place. For example, if reading the file was intended to result in text, then it should have been opened in a text mode. In 3.x, the file encoding can simply be passed as an encoding keyword argument to open, and conversion to Unicode is handled seamlessly without having to feed a binary file to an explicit translation step (thus, universal newline handling still takes place seamlessly).
In the case of the original example, that could look like:
with open(fname, 'r') as f:
lines = [x.strip() for x in f.readlines()]
This example assumes a platform-dependent default encoding for the file. This will normally work for files that were created in straightforward ways, on the same computer. In the general case, however, the encoding of the data must be known in order to work with it properly.
If the encoding is known to be, for example, UTF-8, that is trivially specified:
with open(fname, 'r', encoding='utf-8') as f:
lines = [x.strip() for x in f.readlines()]
Similarly, a string literal that should have been a bytes literal is simply missing a prefix: to make the bytes sequence representing integer values [101, 120, 97, 109, 112, 108, 101] (i.e., the ASCII values of the letters example), write the bytes literal b'example', rather than the string literal `'example'). Similarly the other way around.
In the case of the original example, that would look like:
if b'some-pattern' in tmp:
There is a safeguard built in to this: the bytes literal syntax only allows ASCII characters, so something like b'ëxãmþlê' will be caught as a SyntaxError, regardless of the encoding of the source file (since it is not clear which byte values are meant; in the old implied-encoding schemes, the ASCII range was well established, but everything else was up in the air.) Of course, bytes literals with elements representing values 128..255 can still be written by using \x escaping for those values: for example, b'\xebx\xe3m\xfel\xea' will produce a byte-sequence corresponding to the text ëxãmþlê in Latin-1 (ISO 8859-1) encoding.
Converting, when appropriate
Conversion between byte-sequences and text is only possible when an encoding has been determined. It has always been so; we just used to assume an encoding locally, and then mostly ignore that we had done so. (Programmers in places like East Asia have been more aware of the problem historically, because they commonly need to work with scripts that have more than 256 distinct symbols, and thus their text requires multi-byte encodings.)
In 3.x, because there is no pressure to be able to treat byte-sequences implicitly as text with an assumed encoding, there are therefore no implicit conversion steps behind the scenes. This means that understanding the API is straightforward: Bytes are raw data; therefore, they are used to encode text, which is an abstraction. Therefore, the .encode() method is provided by str (which represents text), in order to encode text into raw data. Similarly, the .decode() method is provided by bytes (which represents a byte-sequence), in order to decode raw data into text.
Applying these to the example code, again supposing UTF-8 encoding is appropriate, gives:
if 'some-pattern'.encode('utf-8') in tmp:
and
if 'some-pattern' in tmp.decode('utf-8'):

python: extended ASCII codes

Hi I want to know how I can append and then print extended ASCII codes in python.
I have the following.
code = chr(247)
li = []
li.append(code)
print li
The result python print out is ['\xf7'] when it should be a division symbol. If I simple print code directly "print code" then I get the division symbol but not if I append it to a list. What am I doing wrong?
Thanks.
When you print a list, it outputs the default representation of all its elements - ie by calling repr() on each of them. The repr() of a string is its escaped code, by design. If you want to output all the elements of the list properly you should convert it to a string, eg via ', '.join(li).
Note that as those in the comments have stated, there isn't really any such thing as "extended ASCII", there are just various different encodings.
You probably want the charmap encoding, which lets you turn unicode into bytes without 'magic' conversions.
s='\xf7'
b=s.encode('charmap')
with open('/dev/stdout','wb') as f:
f.write(b)
f.flush()
Will print ÷ on my system.
Note that 'extended ASCII' refers to any of a number of proprietary extensions to ASCII, none of which were ever officially adopted and all of which are incompatible with each other. As a result, the symbol output by that code will vary based on the controlling terminal's choice of how to interpret it.
There's no single defined standard named "extend ASCII Codes"> - there are however, plenty of characters, tens of thousands, as defined in the Unicode standards.
You can be limited to the charset encoding of your text terminal, which you may think of as "Extend ASCII", but which might be "latin-1", for example (if you are on a Unix system such as Linux or Mac OS X, your text terminal will likely use UTF-8 encoding, and able to display any of the tens of thousands chars available in Unicode)
So, you must read this piece in order to understand what text is, after 1992 -
If you try to do any production application believing in "extended ASCII" you are harming yourself, your users and the whole eco-system at once: http://www.joelonsoftware.com/articles/Unicode.html
That said, Python2's (and Python3's) print will call the an implicit str conversion for the objects passed in. If you use a list, this conversion does not recursively calls str for each list element, instead, it uses the element's repr, which displays non ASCII characters as their numeric representation or other unsuitable notations.
You can simply join your desired characters in a unicode string, for example, and then print them normally, using the terminal encoding:
import sys
mytext = u""
mytext += unichr(247) #check the codes for unicode chars here: http://en.wikipedia.org/wiki/List_of_Unicode_characters
print mytext.encode(sys.stdout.encoding, errors="replace")
You are doing nothing wrong.
What you do is to add a string of length 1 to a list.
This string contains a character outside the range of printable characters, and outside of ASCII (which is only 7 bit). That's why its representation looks like '\xf7'.
If you print it, it will be transformed as good as the system can.
In Python 2, the byte will be just printed. The resulting output may be the division symbol, or any other thing, according to what your system's encoding is.
In Python 3, it is a unicode character and will be processed according to how stdout is set up. Normally, this indeed should be the division symbol.
In a representation of a list, the __repr__() of the string is called, leading to what you see.

Python, Encoding output to UTF-8

I have a definition that builds a string composed of UTF-8 encoded characters. The output files are opened using 'w+', "utf-8" arguments.
However, when I try to x.write(string) I get the UnicodeEncodeError: 'ascii' codec can't encode character u'\ufeff' in position 1: ordinal not in range(128)
I assume this is because normally for example you would do `print(u'something'). But I need to use a variable and the quotations in u'_' negate that...
Any suggestions?
EDIT: Actual code here:
source = codecs.open("actionbreak/" + target + '.csv','r', "utf-8")
outTarget = codecs.open("actionbreak/" + newTarget, 'w+', "utf-8")
x = str(actionT(splitList[0], splitList[1]))
outTarget.write(x)
Essentially all this is supposed to be doing is building me a large amount of strings that look similar to this:
[日木曜 Deliverables]= CASE WHEN things = 11
THEN C ELSE 0 END
Are you using codecs.open()? Python 2.7's built-in open() does not support a specific encoding, meaning you have to manually encode non-ascii strings (as others have noted), but codecs.open() does support that and would probably be easier to drop in than manually encoding all the strings.
As you are actually using codecs.open(), going by your added code, and after a bit of looking things up myself, I suggest attempting to open the input and/or output file with encoding "utf-8-sig", which will automatically handle the BOM for UTF-8 (see http://docs.python.org/2/library/codecs.html#encodings-and-unicode, near the bottom of the section) I would think that would only matter for the input file, but if none of those combinations (utf-8-sig/utf-8, utf-8/utf-8-sig, utf-8-sig/utf-8-sig) work, then I believe the most likely situation would be that your input file is encoded in a different Unicode format with BOM, as Python's default UTF-8 codec interprets BOMs as regular characters so the input would not have an issue but output could.
Just noticed this, but... when you use codecs.open(), it expects a Unicode string, not an encoded one; try x = unicode(actionT(splitList[0], splitList[1])).
Your error can also occur when attempting to decode a unicode string (see http://wiki.python.org/moin/UnicodeEncodeError), but I don't think that should be happening unless actionT() or your list-splitting does something to the Unicode strings that causes them to be treated as non-Unicode strings.
In python 2.x there are two types of string: byte string and unicode string. First one contains bytes and last one - unicode code points. It is easy to determine, what type of string it is - unicode string starts with u:
# byte string
>>> 'abc'
'abc'
# unicode string:
>>> u'abc абв'
u'abc \u0430\u0431\u0432'
'abc' chars are the same, because the are in ASCII range. \u0430 is a unicode code point, it is out of ASCII range. "Code point" is python internal representation of unicode points, they can't be saved to file. It is needed to encode them to bytes first. Here how encoded unicode string looks like (as it is encoded, it becomes a byte string):
>>> s = u'abc абв'
>>> s.encode('utf8')
'abc \xd0\xb0\xd0\xb1\xd0\xb2'
This encoded string now can be written to file:
>>> s = u'abc абв'
>>> with open('text.txt', 'w+') as f:
... f.write(s.encode('utf8'))
Now, it is important to remember, what encoding we used when writing to file. Because to be able to read the data, we need to decode the content. Here what data looks like without decoding:
>>> with open('text.txt', 'r') as f:
... content = f.read()
>>> content
'abc \xd0\xb0\xd0\xb1\xd0\xb2'
You see, we've got encoded bytes, exactly the same as in s.encode('utf8'). To decode it is needed to provide coding name:
>>> content.decode('utf8')
u'abc \u0430\u0431\u0432'
After decode, we've got back our unicode string with unicode code points.
>>> print content.decode('utf8')
abc абв
xgord is right, but for further edification it's worth noting exactly what \ufeff means. It's known as a BOM or a byte order mark and basically it's a callback to the early days of unicode when people couldn't agree which way they wanted their unicode to go. Now all unicode documents are prefaced with either an \ufeff or an \uffef depending on which order they decide to arrange their bytes in.
If you hit an error on those characters in the first location you can be sure the issue is that you are not trying to decode it as utf-8, and the file is probably still fine.

Python 3 file input change in binary mode

In Python 3, when I opened a text file with mode string 'rb', and then did f.read(), I was taken aback to find the file contents enclosed in single quotes after the character 'b'.
In Python 2 I just get the file contents.
I'm sure this is well known, but I can't find anything about it in the doco. Could someone point me to it?
You get "just the file contents" in Python 3 as well. Most likely you can just keep on doing whatever you were doing anyway. Read on for a longer explanation:
The b'' signifies that the result value is a bytes string. A bytes-string is quite similar to a normal string, but not quite, and is used to handle binary, non-textual data.
Some of the methods on a string that doesn't make sense for binary data is gone, but most are still there. A big difference is that when you get a specific byte from a bytes string you get an integer back, while for a normal str you get a one-length str.
>>> b'foo'[1]
111
>>> 'foo'[1]
'o'
If you open the file in text mode with the 't' flag you get a str back. The Python 3 str is what in Python 2 was called unicode. It's used to handle textual data.
You convert back and forth between bytes and str with the .encode() and .decode methods.
First of all, the Python 2 str type has been renamed to bytes in Python 3, and byte literals use the b'' prefix. The Python 2 unicode type is the new Python 3 str type.
To get the Python 3 file behaviour in Python 2, you'd use io.open() or codecs.open(); Python 3 decodes text files to Unicode by default.
What you see is that for binary files, Python 3 gives you the exact same thing as in Python 2, namely byte strings. What changed then, is that the repr() of a byte string is prefixed with b and the print() function will use the repr() representation of any object passed to it except for unicode values.
To print your binary data as unicode text with the print() function., decode it to unicode first. But then you could perhaps have opened the file as a text file instead anyway.
The bytes type has some other improvements to reflect that you are dealing with binary data, not text. Indexing individual bytes or iterating over a bytes value gives you int values (between 0 and 255) and not characters, for example.
Sometimes we need (needed?) to know whether a text file had single-character newlines (0A) or double character newlines (0D0A).
We used to avoid confusion by opening the text file in binary mode, recognising 0D and 0A, and treating other bytes as regular text characters.
One could port such code by finding all binary﷓mode reads and replacing them with a new function oldread() that stripped off the added material, but it’s a bit painful.
I suppose the Python theologians thought of keeping ‘rb’ as it was, and adding a new ‘rx’ or something for the new behaviour. It seems a bit high-handed just to abolish something.
But, there it is, the question is certainly answered by a search for ‘rb’ in Lennert’s document.

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