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<h2 align="center"> zlib Usage Example </h2>

We often get questions about how the <tt>deflate()</tt> and <tt>inflate()</tt> functions should be used.

Users wonder when they should provide more input, when they should use more output,

what to do with a <tt>Z_BUF_ERROR</tt>, how to make sure the process terminates properly, and

so on.  So for those who have read <tt>zlib.h</tt> (a few times), and

would like further edification, below is an annotated example in C of simple routines to compress and decompress

from an input file to an output file using <tt>deflate()</tt> and <tt>inflate()</tt> respectively.  The

annotations are interspersed between lines of the code.  So please read between the lines.

We hope this helps explain some of the intricacies of <em>zlib</em>.

<p>

Without further adieu, here is the program <a href="zpipe.c"><tt>zpipe.c</tt></a>:

<pre><b>

/* zpipe.c: example of proper use of zlib's inflate() and deflate()

   Not copyrighted -- provided to the public domain

   Version 1.2  9 November 2004  Mark Adler */

/* Version history:

   1.0  30 Oct 2004  First version

   1.1   8 Nov 2004  Add void casting for unused return values

                     Use switch statement for inflate() return values

   1.2   9 Nov 2004  Add assertions to document zlib guarantees

 */

</b></pre><!-- -->

We now include the header files for the required definitions.  From

<tt>stdio.h</tt> we use <tt>fopen()</tt>, <tt>fread()</tt>, <tt>fwrite()</tt>,

<tt>feof()</tt>, <tt>ferror()</tt>, and <tt>fclose()</tt> for file i/o, and

<tt>fputs()</tt> for error messages.  From <tt>string.h</tt> we use

<tt>strcmp()</tt> for command line argument processing.

From <tt>assert.h</tt> we use the <tt>assert()</tt> macro.

From <tt>zlib.h</tt>

we use the basic compression functions <tt>deflateInit()</tt>,

<tt>deflate()</tt>, and <tt>deflateEnd()</tt>, and the basic decompression

functions <tt>inflateInit()</tt>, <tt>inflate()</tt>, and

<tt>inflateEnd()</tt>.

<pre><b>

#include <stdio.h>

#include <string.h>

#include <assert.h>

#include "zlib.h"

</b></pre><!-- -->

<tt>CHUNK</tt> is simply the buffer size for feeding data to and pulling data

from the <em>zlib</em> routines.  Larger buffer sizes would be more efficient,

especially for <tt>inflate()</tt>.  If the memory is available, buffers sizes

on the order of 128K or 256K bytes should be used.

<pre><b>

#define CHUNK 16384

</b></pre><!-- -->

The <tt>def()</tt> routine compresses data from an input file to an output file.  The output data

will be in the <em>zlib</em> format, which is different from the <em>gzip</em> or <em>zip</em>

formats.  The <em>zlib</em> format has a very small header of only two bytes to identify it as

a <em>zlib</em> stream and to provide decoding information, and a four-byte trailer with a fast

check value to verify the integrity of the uncompressed data after decoding.

<pre><b>

/* Compress from file source to file dest until EOF on source.

   def() returns Z_OK on success, Z_MEM_ERROR if memory could not be

   allocated for processing, Z_STREAM_ERROR if an invalid compression

   level is supplied, Z_VERSION_ERROR if the version of zlib.h and the

   version of the library linked do not match, or Z_ERRNO if there is

   an error reading or writing the files. */

int def(FILE *source, FILE *dest, int level)

{

</b></pre>

Here are the local variables for <tt>def()</tt>.  <tt>ret</tt> will be used for <em>zlib</em>

return codes.  <tt>flush</tt> will keep track of the current flushing state for <tt>deflate()</tt>,

which is either no flushing, or flush to completion after the end of the input file is reached.

<tt>have</tt> is the amount of data returned from <tt>deflate()</tt>.  The <tt>strm</tt> structure

is used to pass information to and from the <em>zlib</em> routines, and to maintain the

<tt>deflate()</tt> state.  <tt>in</tt> and <tt>out</tt> are the input and output buffers for

<tt>deflate()</tt>.

<pre><b>

    int ret, flush;

    unsigned have;

    z_stream strm;

    char in[CHUNK];

    char out[CHUNK];

</b></pre><!-- -->

The first thing we do is to initialize the <em>zlib</em> state for compression using

<tt>deflateInit()</tt>.  This must be done before the first use of <tt>deflate()</tt>.

The <tt>zalloc</tt>, <tt>zfree</tt>, and <tt>opaque</tt> fields in the <tt>strm</tt>

structure must be initialized before calling <tt>deflateInit()</tt>.  Here they are

set to the <em>zlib</em> constant <tt>Z_NULL</tt> to request that <em>zlib</em> use

the default memory allocation routines.  An application may also choose to provide

custom memory allocation routines here.  <tt>deflateInit()</tt> will allocate on the

order of 256K bytes for the internal state.

(See <a href="zlib_tech.html"><em>zlib Technical Details</em></a>.)

<p>

<tt>deflateInit()</tt> is called with a pointer to the structure to be initialized and

the compression level, which is an integer in the range of -1 to 9.  Lower compression

levels result in faster execution, but less compression.  Higher levels result in

greater compression, but slower execution.  The <em>zlib</em> constant Z_DEFAULT_COMPRESSION,

equal to -1,

provides a good compromise between compression and speed and is equivalent to level 6.

Level 0 actually does no compression at all, and in fact expands the data slightly to produce

the <em>zlib</em> format (it is not a byte-for-byte copy of the input).

More advanced applications of <em>zlib</em>

may use <tt>deflateInit2()</tt> here instead.  Such an application may want to reduce how

much memory will be used, at some price in compression.  Or it may need to request a

<em>gzip</em> header and trailer instead of a <em>zlib</em> header and trailer, or raw

encoding with no header or trailer at all.

<p>

We must check the return value of <tt>deflateInit()</tt> against the <em>zlib</em> constant

<tt>Z_OK</tt> to make sure that it was able to

allocate memory for the internal state, and that the provided arguments were valid.

<tt>deflateInit()</tt> will also check that the version of <em>zlib</em> that the <tt>zlib.h</tt>

file came from matches the version of <em>zlib</em> actually linked with the program.  This

is especially important for environments in which <em>zlib</em> is a shared library.

<p>

Note that an application can initialize multiple, independent <em>zlib</em> streams, which can

operate in parallel.  The state information maintained in the structure allows the <em>zlib</em>

routines to be reentrant.

<pre><b>

    /* allocate deflate state */

    strm.zalloc = Z_NULL;

    strm.zfree = Z_NULL;

    strm.opaque = Z_NULL;

    ret = deflateInit(&strm, level);

    if (ret != Z_OK)

        return ret;

</b></pre><!-- -->

With the pleasantries out of the way, now we can get down to business.  The outer <tt>do</tt>-loop

reads all of the input file and exits at the bottom of the loop once end-of-file is reached.

This loop contains the only call of <tt>deflate()</tt>.  So we must make sure that all of the

input data has been processed and that all of the output data has been generated and consumed

before we fall out of the loop at the bottom.

<pre><b>

    /* compress until end of file */

    do {

</b></pre>

We start off by reading data from the input file.  The number of bytes read is put directly

into <tt>avail_in</tt>, and a pointer to those bytes is put into <tt>next_in</tt>.  We also

check to see if end-of-file on the input has been reached.  If we are at the end of file, then <tt>flush</tt> is set to the

<em>zlib</em> constant <tt>Z_FINISH</tt>, which is later passed to <tt>deflate()</tt> to

indicate that this is the last chunk of input data to compress.  We need to use <tt>feof()</tt>

to check for end-of-file as opposed to seeing if fewer than <tt>CHUNK</tt> bytes have been read.  The

reason is that if the input file length is an exact multiple of <tt>CHUNK</tt>, we will miss

the fact that we got to the end-of-file, and not know to tell <tt>deflate()</tt> to finish

up the compressed stream.  If we are not yet at the end of the input, then the <em>zlib</em>

constant <tt>Z_NO_FLUSH</tt> will be passed to <tt>deflate</tt> to indicate that we are still

in the middle of the uncompressed data.

<p>

If there is an error in reading from the input file, the process is aborted with

<tt>deflateEnd()</tt> being called to free the allocated <em>zlib</em> state before returning

the error.  We wouldn't want a memory leak, now would we?  <tt>deflateEnd()</tt> can be called

at any time after the state has been initialized.  Once that's done, <tt>deflateInit()</tt> (or

<tt>deflateInit2()</tt>) would have to be called to start a new compression process.  There is

no point here in checking the <tt>deflateEnd()</tt> return code.  The deallocation can't fail.

<pre><b>

        strm.avail_in = fread(in, 1, CHUNK, source);

        if (ferror(source)) {

            (void)deflateEnd(&strm);

            return Z_ERRNO;

        }

        flush = feof(source) ? Z_FINISH : Z_NO_FLUSH;

        strm.next_in = in;

</b></pre><!-- -->

The inner <tt>do</tt>-loop passes our chunk of input data to <tt>deflate()</tt>, and then

keeps calling <tt>deflate()</tt> until it is done producing output.  Once there is no more

new output, <tt>deflate()</tt> is guaranteed to have consumed all of the input, i.e.,

<tt>avail_in</tt> will be zero.

<pre><b>

        /* run deflate() on input until output buffer not full, finish

           compression if all of source has been read in */

        do {

</b></pre>

Output space is provided to <tt>deflate()</tt> by setting <tt>avail_out</tt> to the number

of available output bytes and <tt>next_out</tt> to a pointer to that space.

<pre><b>

            strm.avail_out = CHUNK;

            strm.next_out = out;

</b></pre>

Now we call the compression engine itself, <tt>deflate()</tt>.  It takes as many of the

<tt>avail_in</tt> bytes at <tt>next_in</tt> as it can process, and writes as many as

<tt>avail_out</tt> bytes to <tt>next_out</tt>.  Those counters and pointers are then

updated past the input data consumed and the output data written.  It is the amount of

output space available that may limit how much input is consumed.

Hence the inner loop to make sure that

all of the input is consumed by providing more output space each time.  Since <tt>avail_in</tt>

and <tt>next_in</tt> are updated by <tt>deflate()</tt>, we don't have to mess with those

between <tt>deflate()</tt> calls until it's all used up.

<p>

The parameters to <tt>deflate()</tt> are a pointer to the <tt>strm</tt> structure containing

the input and output information and the internal compression engine state, and a parameter

indicating whether and how to flush data to the output.  Normally <tt>deflate</tt> will consume

several K bytes of input data before producing any output (except for the header), in order

to accumulate statistics on the data for optimum compression.  It will then put out a burst of

compressed data, and proceed to consume more input before the next burst.  Eventually,

<tt>deflate()</tt>

must be told to terminate the stream, complete the compression with provided input data, and

write out the trailer check value.  <tt>deflate()</tt> will continue to compress normally as long

as the flush parameter is <tt>Z_NO_FLUSH</tt>.  Once the <tt>Z_FINISH</tt> parameter is provided,

<tt>deflate()</tt> will begin to complete the compressed output stream.  However depending on how

much output space is provided, <tt>deflate()</tt> may have to be called several times until it

has provided the complete compressed stream, even after it has consumed all of the input.  The flush

parameter must continue to be <tt>Z_FINISH</tt> for those subsequent calls.

<p>

There are other values of the flush parameter that are used in more advanced applications.  You can

force <tt>deflate()</tt> to produce a burst of output that encodes all of the input data provided

so far, even if it wouldn't have otherwise, for example to control data latency on a link with

compressed data.  You can also ask that <tt>deflate()</tt> do that as well as erase any history up to

that point so that what follows can be decompressed independently, for example for random access

applications.  Both requests will degrade compression by an amount depending on how often such

requests are made.

<p>

<tt>deflate()</tt> has a return value that can indicate errors, yet we do not check it here.  Why

not?  Well, it turns out that <tt>deflate()</tt> can do no wrong here.  Let's go through

<tt>deflate()</tt>'s return values and dispense with them one by one.  The possible values are

<tt>Z_OK</tt>, <tt>Z_STREAM_END</tt>, <tt>Z_STREAM_ERROR</tt>, or <tt>Z_BUF_ERROR</tt>.  <tt>Z_OK</tt>

is, well, ok.  <tt>Z_STREAM_END</tt> is also ok and will be returned for the last call of

<tt>deflate()</tt>.  This is already guaranteed by calling <tt>deflate()</tt> with <tt>Z_FINISH</tt>

until it has no more output.  <tt>Z_STREAM_ERROR</tt> is only possible if the stream is not

initialized properly, but we did initialize it properly.  There is no harm in checking for

<tt>Z_STREAM_ERROR</tt> here, for example to check for the possibility that some

other part of the application inadvertently clobbered the memory containing the <em>zlib</em> state.

<tt>Z_BUF_ERROR</tt> will be explained further below, but

suffice it to say that this is simply an indication that <tt>deflate()</tt> could not consume

more input or produce more output.  <tt>deflate()</tt> can be called again with more output space

or more available input, which it will be in this code.

<pre><b>

            ret = deflate(&strm, flush);    /* no bad return value */

            assert(ret != Z_STREAM_ERROR);  /* state not clobbered */

</b></pre>

Now we compute how much output <tt>deflate()</tt> provided on the last call, which is the

difference between how much space was provided before the call, and how much output space

is still available after the call.  Then that data, if any, is written to the output file.

We can then reuse the output buffer for the next call of <tt>deflate()</tt>.  Again if there

is a file i/o error, we call <tt>deflateEnd()</tt> before returning to avoid a memory leak.

<pre><b>

            have = CHUNK - strm.avail_out;

            if (fwrite(out, 1, have, dest) != have || ferror(dest)) {

                (void)deflateEnd(&strm);

                return Z_ERRNO;

            }

</b></pre>

The inner <tt>do</tt>-loop is repeated until the last <tt>deflate()</tt> call fails to fill the

provided output buffer.  Then we know that <tt>deflate()</tt> has done as much as it can with

the provided input, and that all of that input has been consumed.  We can then fall out of this

loop and reuse the input buffer.

<p>

The way we tell that <tt>deflate()</tt> has no more output is by seeing that it did not fill

the output buffer, leaving <tt>avail_out</tt> greater than zero.  However suppose that

<tt>deflate()</tt> has no more output, but just so happened to exactly fill the output buffer!

<tt>avail_out</tt> is zero, and we can't tell that <tt>deflate()</tt> has done all it can.

As far as we know, <tt>deflate()</tt>

has more output for us.  So we call it again.  But now <tt>deflate()</tt> produces no output

at all, and <tt>avail_out</tt> remains unchanged as <tt>CHUNK</tt>.  That <tt>deflate()</tt> call

wasn't able to do anything, either consume input or produce output, and so it returns

<tt>Z_BUF_ERROR</tt>.  (See, I told you I'd cover this later.)  However this is not a problem at

all.  Now we finally have the desired indication that <tt>deflate()</tt> is really done,

and so we drop out of the inner loop to provide more input to <tt>deflate()</tt>.

<p>

With <tt>flush</tt> set to <tt>Z_FINISH</tt>, this final set of <tt>deflate()</tt> calls will

complete the output stream.  Once that is done, subsequent calls of <tt>deflate()</tt> would return

<tt>Z_STREAM_ERROR</tt> if the flush parameter is not <tt>Z_FINISH</tt>, and do no more processing

until the state is reinitialized.

<p>

Some applications of <em>zlib</em> have two loops that call <tt>deflate()</tt>

instead of the single inner loop we have here.  The first loop would call

without flushing and feed all of the data to <tt>deflate()</tt>.  The second loop would call

<tt>deflate()</tt> with no more

data and the <tt>Z_FINISH</tt> parameter to complete the process.  As you can see from this

example, that can be avoided by simply keeping track of the current flush state.

<pre><b>

        } while (strm.avail_out == 0);

        assert(strm.avail_in == 0);     /* all input will be used */

</b></pre><!-- -->

Now we check to see if we have already processed all of the input file.  That information was

saved in the <tt>flush</tt> variable, so we see if that was set to <tt>Z_FINISH</tt>.  If so,

then we're done and we fall out of the outer loop.  We're guaranteed to get <tt>Z_STREAM_END</tt>

from the last <tt>deflate()</tt> call, since we ran it until the last chunk of input was

consumed and all of the output was generated.

<pre><b>

        /* done when last data in file processed */

    } while (flush != Z_FINISH);

    assert(ret == Z_STREAM_END);        /* stream will be complete */

</b></pre><!-- -->

The process is complete, but we still need to deallocate the state to avoid a memory leak

(or rather more like a memory hemorrhage if you didn't do this).  Then

finally we can return with a happy return value.

<pre><b>

    /* clean up and return */

    (void)deflateEnd(&strm);

    return Z_OK;

}

</b></pre><!-- -->

Now we do the same thing for decompression in the <tt>inf()</tt> routine. <tt>inf()</tt>

decompresses what is hopefully a valid <em>zlib</em> stream from the input file and writes the

uncompressed data to the output file.  Much of the discussion above for <tt>def()</tt>

applies to <tt>inf()</tt> as well, so the discussion here will focus on the differences between

the two.

<pre><b>

/* Decompress from file source to file dest until stream ends or EOF.

   inf() returns Z_OK on success, Z_MEM_ERROR if memory could not be

   allocated for processing, Z_DATA_ERROR if the deflate data is

   invalid or incomplete, Z_VERSION_ERROR if the version of zlib.h and

   the version of the library linked do not match, or Z_ERRNO if there

   is an error reading or writing the files. */

int inf(FILE *source, FILE *dest)

{

</b></pre>

The local variables have the same functionality as they do for <tt>def()</tt>.  The

only difference is that there is no <tt>flush</tt> variable, since <tt>inflate()</tt>

can tell from the <em>zlib</em> stream itself when the stream is complete.

<pre><b>

    int ret;

    unsigned have;

    z_stream strm;

    char in[CHUNK];

    char out[CHUNK];

</b></pre><!-- -->

The initialization of the state is the same, except that there is no compression level,

of course, and two more elements of the structure are initialized.  <tt>avail_in</tt>

and <tt>next_in</tt> must be initialized before calling <tt>inflateInit()</tt>.  This

is because the application has the option to provide the start of the zlib stream in

order for <tt>inflateInit()</tt> to have access to information about the compression

method to aid in memory allocation.  In the current implementation of <em>zlib</em>

(up through versions 1.2.x), the method-dependent memory allocations are deferred to the first call of

<tt>inflate()</tt> anyway.  However those fields must be initialized since later versions

of <em>zlib</em> that provide more compression methods may take advantage of this interface.

In any case, no decompression is performed by <tt>inflateInit()</tt>, so the

<tt>avail_out</tt> and <tt>next_out</tt> fields do not need to be initialized before calling.

<p>

Here <tt>avail_in</tt> is set to zero and <tt>next_in</tt> is set to <tt>Z_NULL</tt> to

indicate that no input data is being provided.

<pre><b>

    /* allocate inflate state */

    strm.zalloc = Z_NULL;

    strm.zfree = Z_NULL;

    strm.opaque = Z_NULL;

    strm.avail_in = 0;

    strm.next_in = Z_NULL;

    ret = inflateInit(&strm);

    if (ret != Z_OK)

        return ret;

</b></pre><!-- -->

The outer <tt>do</tt>-loop decompresses input until <tt>inflate()</tt> indicates

that it has reached the end of the compressed data and has produced all of the uncompressed

output.  This is in contrast to <tt>def()</tt> which processes all of the input file.

If end-of-file is reached before the compressed data self-terminates, then the compressed

data is incomplete and an error is returned.

<pre><b>

    /* decompress until deflate stream ends or end of file */

    do {

</b></pre>

We read input data and set the <tt>strm</tt> structure accordingly.  If we've reached the

end of the input file, then we leave the outer loop and report an error, since the

compressed data is incomplete.  Note that we may read more data than is eventually consumed

by <tt>inflate()</tt>, if the input file continues past the <em>zlib</em> stream.

For applications where <em>zlib</em> streams are embedded in other data, this routine would

need to be modified to return the unused data, or at least indicate how much of the input

data was not used, so the application would know where to pick up after the <em>zlib</em> stream.

<pre><b>

        strm.avail_in = fread(in, 1, CHUNK, source);

        if (ferror(source)) {

            (void)inflateEnd(&strm);

            return Z_ERRNO;

        }

        if (strm.avail_in == 0)

            break;

        strm.next_in = in;

</b></pre><!-- -->

The inner <tt>do</tt>-loop has the same function it did in <tt>def()</tt>, which is to

keep calling <tt>inflate()</tt> until has generated all of the output it can with the

provided input.

<pre><b>

        /* run inflate() on input until output buffer not full */

        do {

</b></pre>

Just like in <tt>def()</tt>, the same output space is provided for each call of <tt>inflate()</tt>.

<pre><b>

            strm.avail_out = CHUNK;

            strm.next_out = out;

</b></pre>

Now we run the decompression engine itself.  There is no need to adjust the flush parameter, since

the <em>zlib</em> format is self-terminating. The main difference here is that there are

return values that we need to pay attention to.  <tt>Z_DATA_ERROR</tt>

indicates that <tt>inflate()</tt> detected an error in the <em>zlib</em> compressed data format,

which means that either the data is not a <em>zlib</em> stream to begin with, or that the data was

corrupted somewhere along the way since it was compressed.  The other error to be processed is

<tt>Z_MEM_ERROR</tt>, which can occur since memory allocation is deferred until <tt>inflate()</tt>

needs it, unlike <tt>deflate()</tt>, whose memory is allocated at the start by <tt>deflateInit()</tt>.

<p>

Advanced applications may use

<tt>deflateSetDictionary()</tt> to prime <tt>deflate()</tt> with a set of likely data to improve the

first 32K or so of compression.  This is noted in the <em>zlib</em> header, so <tt>inflate()</tt>

requests that that dictionary be provided before it can start to decompress.  Without the dictionary,

correct decompression is not possible.  For this routine, we have no idea what the dictionary is,

so the <tt>Z_NEED_DICT</tt> indication is converted to a <tt>Z_DATA_ERROR</tt>.

<p>

<tt>inflate()</tt> can also return <tt>Z_STREAM_ERROR</tt>, which should not be possible here,

but could be checked for as noted above for <tt>def()</tt>.  <tt>Z_BUF_ERROR</tt> does not need to be

checked for here, for the same reasons noted for <tt>def()</tt>.  <tt>Z_STREAM_END</tt> will be

checked for later.

<pre><b>

            ret = inflate(&strm, Z_NO_FLUSH);

            assert(ret != Z_STREAM_ERROR);  /* state not clobbered */

            switch (ret) {

            case Z_NEED_DICT:

                ret = Z_DATA_ERROR;     /* and fall through */

            case Z_DATA_ERROR:

            case Z_MEM_ERROR:

                (void)inflateEnd(&strm);

                return ret;

            }

</b></pre>

The output of <tt>inflate()</tt> is handled identically to that of <tt>deflate()</tt>.

<pre><b>

            have = CHUNK - strm.avail_out;

            if (fwrite(out, 1, have, dest) != have || ferror(dest)) {

                (void)inflateEnd(&strm);

                return Z_ERRNO;

            }

</b></pre>

The inner <tt>do</tt>-loop ends when <tt>inflate()</tt> has no more output as indicated

by not filling the output buffer, just as for <tt>deflate()</tt>.  In this case, we cannot

assert that <tt>strm.avail_in</tt> will be zero, since the deflate stream may end before the file

does.

<pre><b>

        } while (strm.avail_out == 0);

</b></pre><!-- -->

The outer <tt>do</tt>-loop ends when <tt>inflate()</tt> reports that it has reached the

end of the input <em>zlib</em> stream, has completed the decompression and integrity

check, and has provided all of the output.  This is indicated by the <tt>inflate()</tt>

return value <tt>Z_STREAM_END</tt>.  The inner loop is guaranteed to leave <tt>ret</tt>

equal to <tt>Z_STREAM_END</tt> if the last chunk of the input file read contained the end

of the <em>zlib</em> stream.  So if the return value is not <tt>Z_STREAM_END</tt>, the

loop continues to read more input.

<pre><b>

        /* done when inflate() says it's done */

    } while (ret != Z_STREAM_END);

</b></pre><!-- -->

At this point, decompression successfully completed, or we broke out of the loop due to no

more data being available from the input file.  If the last <tt>inflate()</tt> return value

is not <tt>Z_STREAM_END</tt>, then the <em>zlib</em> stream was incomplete and a data error

is returned.  Otherwise, we return with a happy return value.  Of course, <tt>inflateEnd()</tt>

is called first to avoid a memory leak.

<pre><b>

    /* clean up and return */

    (void)inflateEnd(&strm);

    return ret == Z_STREAM_END ? Z_OK : Z_DATA_ERROR;

}

</b></pre><!-- -->

That ends the routines that directly use <em>zlib</em>.  The following routines make this

a command-line program by running data through the above routines from <tt>stdin</tt> to

<tt>stdout</tt>, and handling any errors reported by <tt>def()</tt> or <tt>inf()</tt>.

<p>

<tt>zerr()</tt> is used to interpret the possible error codes from <tt>def()</tt>

and <tt>inf()</tt>, as detailed in their comments above, and print out an error message.

Note that these are only a subset of the possible return values from <tt>deflate()</tt>

and <tt>inflate()</tt>.

<pre><b>

/* report a zlib or i/o error */

void zerr(int ret)

{

    fputs("zpipe: ", stderr);

    switch (ret) {

    case Z_ERRNO:

        if (ferror(stdin))

            fputs("error reading stdin\n", stderr);

        if (ferror(stdout))

            fputs("error writing stdout\n", stderr);

        break;

    case Z_STREAM_ERROR:

        fputs("invalid compression level\n", stderr);

        break;

    case Z_DATA_ERROR:

        fputs("invalid or incomplete deflate data\n", stderr);

        break;

    case Z_MEM_ERROR:

        fputs("out of memory\n", stderr);

        break;

    case Z_VERSION_ERROR:

        fputs("zlib version mismatch!\n", stderr);

    }

}

</b></pre><!-- -->

Here is the <tt>main()</tt> routine used to test <tt>def()</tt> and <tt>inf()</tt>.  The

<tt>zpipe</tt> command is simply a compression pipe from <tt>stdin</tt> to <tt>stdout</tt>, if

no arguments are given, or it is a decompression pipe if <tt>zpipe -d</tt> is used.  If any other

arguments are provided, no compression or decompression is performed.  Instead a usage

message is displayed.  Examples are <tt>zpipe < foo.txt > foo.txt.z</tt> to compress, and

<tt>zpipe -d < foo.txt.z > foo.txt</tt> to decompress.

<pre><b>

/* compress or decompress from stdin to stdout */

int main(int argc, char **argv)

{

    int ret;

    /* do compression if no arguments */

    if (argc == 1) {

        ret = def(stdin, stdout, Z_DEFAULT_COMPRESSION);

        if (ret != Z_OK)

            zerr(ret);

        return ret;

    }

    /* do decompression if -d specified */

    else if (argc == 2 && strcmp(argv[1], "-d") == 0) {

        ret = inf(stdin, stdout);

        if (ret != Z_OK)

            zerr(ret);

        return ret;

    }

    /* otherwise, report usage */

    else {

        fputs("zpipe usage: zpipe [-d] < source > dest\n", stderr);

        return 1;

    }

}

</b></pre>

<hr>

<i>Copyright (c) 2004 by Mark Adler<br>Last modified 13 November 2004</i>

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