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How do I implement a FIFO buffer to which I can efficiently add arbitrarily sized chunks of bytes to the head and from which I can efficiently pop arbitrarily sized chunks of bytes from the tail?


I have a class that reads bytes from file-like objects in chunks of arbitrary size and is itself a file-like object from which clients can read the bytes in chunks of arbitrary size.

The way I have this implemented is that whenever a client wants to read a chunk of bytes, the class will repeatedly read from the underlying file-like objects (with chunk sizes appropriate to those objects) and add the bytes to the head of a FIFO queue until there are enough bytes in the queue to serve a chunk of the requested size to the client. It then pops those bytes off of the tail of the queue and returns them to the client.

I have a performance problem that occurs when the chunk size for the underlying file-like objects is much larger than the chunk size that clients use when reading from the class.

Say the chunk size for the underlying file-like objects is 1 MiB and the chunk size the client reads with is 1 KiB. The first time the client requests 1 KiB, the class has to read 1 MiB and add it to the FIFO queue. Then, for that request and the subsequent 1023 requests, the class has to pop 1 KiB from the tail of the FIFO queue, which gradually decreases in size from 1 MiB to 0 bytes, at which time the cycle starts again.

I have currently implemented this with a StringIO object. Writing new bytes to the end of the StringIO object is fast, but removing bytes from the beginning is very slow, because a new StringIO object, that holds a copy of the entire previous buffer minus the first chunk of bytes, must be created.

SO questions that deal with similar issues tend to point to the deque container. However, deque is implemented as as doubly linked list. Writing a chunk to the deque would require splitting the chunk into objects, each containing a single byte. The deque would then add two pointers to each object for storing, probably increasing the memory requirements by at least an order of magnitude as compared to the bytes. Also, it would take a long time to traverse the linked list and deal with each object both to split chunks into objects and to join objects into chunks.

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up vote 13 down vote accepted

I have currently implemented this with a StringIO object. Writing new bytes to the end of the StringIO object is fast, but removing bytes from the beginning is very slow, because a new StringIO object, that holds a copy of the entire previous buffer minus the first chunk of bytes, must be created.

Actually the most typical way of implementing FIFO is two use wrap around buffer with two pointers as such:

enter image description here image source

Now, you can implement that with StringIO() using .seek() to read/write from appropriate location.

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Ooh, +1 for the wraparound. I hadn't thought of that. You'd need to know the maximum size in advance though; actually, I suppose it could be grown as needed... – Cameron Jun 6 '12 at 16:06
Thanks! This looks perfect. I did an experiment with StringIO that indicates that it will expand automatically to accommodate this. For instance, if the current size of the StringIO object is 10 bytes and PUTPT (the seek location) is at index 5, writing a 20 byte chunk automatically expands the StringIO object to 25 bytes, preserving the first 5 bytes and overwriting the rest. Though, if GETPT is currently after PUTPT, some more logic is required. – Roger Dahl Jun 6 '12 at 16:45
I've implemented this idea in my answer below. Cheers! – Cameron Jun 6 '12 at 19:13

Update: Here's an implementation of the circular buffer technique from vartec's answer (building on my original answer, preserved below for those curious):

from cStringIO import StringIO

class FifoFileBuffer(object):
    def __init__(self):
        self.buf = StringIO()
        self.available = 0    # Bytes available for reading
        self.size = 0
        self.write_fp = 0

    def read(self, size = None):
        """Reads size bytes from buffer"""
        if size is None or size > self.available:
            size = self.available
        size = max(size, 0)

        result = self.buf.read(size)
        self.available -= size

        if len(result) < size:
            result += self.buf.read(size - len(result))

        return result

    def write(self, data):
        """Appends data to buffer"""
        if self.size < self.available + len(data):
            # Expand buffer
            new_buf = StringIO()
            self.write_fp = self.available = new_buf.tell()
            read_fp = 0
            while self.size <= self.available + len(data):
                self.size = max(self.size, 1024) * 2
            new_buf.write('0' * (self.size - self.write_fp))
            self.buf = new_buf
            read_fp = self.buf.tell()

        written = self.size - self.write_fp
        self.write_fp += len(data)
        self.available += len(data)
        if written < len(data):
            self.write_fp -= self.size

Original answer (superseded by the one above):

You can use a buffer and track the start index (read file pointer), occasionally compacting it when it gets too large (this should yield pretty good amortized performance).

For example, wrap a StringIO object like so:

from cStringIO import StringIO
class FifoBuffer(object):
    def __init__(self):
        self.buf = StringIO()

    def read(self, *args, **kwargs):
        """Reads data from buffer"""
        self.buf.read(*args, **kwargs)

    def write(self, *args, **kwargs):
        """Appends data to buffer"""
        current_read_fp = self.buf.tell()
        if current_read_fp > 10 * 1024 * 1024:
            # Buffer is holding 10MB of used data, time to compact
            new_buf = StringIO()
            self.buf = new_buf
            current_read_fp = 0

        self.buf.seek(0, 2)    # Seek to end
        self.buf.write(*args, **kwargs)

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+1 This is awesome. Thank you for the complete implementation. – Roger Dahl Jun 6 '12 at 21:49
@Roger: No problem. I figured it might come in handy some day ;-) – Cameron Jun 6 '12 at 21:54
Just out of curiosity, is it any faster? – Zamfir Kerlukson Nov 29 '12 at 4:27
@Zamfir: No idea :-) Try it out and see? – Cameron Nov 29 '12 at 4:32

Can you assume anything about the expected read/write amounts?

Chunking the data into, for example, 1024 byte fragments and using deque[1] might then work better; you could just read N full chunks, then one last chunk to split and put the remainder back on the start of the queue.

1) collections.deque

class collections.deque([iterable[, maxlen]])

Returns a new deque object initialized left-to-right (using append()) with data from iterable. If iterable is not specified, the new deque is empty.

Deques are a generalization of stacks and queues (the name is pronounced “deck” and is short for “double-ended queue”). Deques support thread-safe, memory efficient appends and pops from either side of the deque with approximately the same O(1) performance in either direction. ...

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