686 lines
25 KiB
Plaintext
686 lines
25 KiB
Plaintext
<chapter id="otherdebug">
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<title>Other debugging techniques</title>
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<sect1 id="hardware-trace">
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<title>Doing A Hardware Trace</title>
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<para>
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The primary reason to do this is to reverse engineer a
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hardware device for which you don't have documentation, but
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can get to work under Wine.
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</para>
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<para>
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This lot is aimed at parallel port devices, and in particular
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parallel port scanners which are now so cheap they are
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virtually being given away. The problem is that few
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manufactures will release any programming information which
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prevents drivers being written for Sane, and the traditional
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technique of using DOSemu to produce the traces does not work
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as the scanners invariably only have drivers for Windows.
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</para>
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<para>
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Presuming that you have compiled and installed wine the first
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thing to do is is to enable direct hardware access to your
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parallel port. To do this edit <filename>config</filename>
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(usually in <filename>~/.wine/</filename>) and in the
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ports section add the following two lines
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</para>
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<programlisting>
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read=0x378,0x379,0x37a,0x37c,0x77a
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write=0x378,x379,0x37a,0x37c,0x77a
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</programlisting>
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<para>
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This adds the necessary access required for SPP/PS2/EPP/ECP
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parallel port on LPT1. You will need to adjust these number
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accordingly if your parallel port is on LPT2 or LPT0.
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</para>
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<para>
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When starting wine use the following command line, where
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<literal>XXXX</literal> is the program you need to run in
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order to access your scanner, and <literal>YYYY</literal> is
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the file your trace will be stored in:
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</para>
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<programlisting>
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WINEDEBUG=+io wine XXXX 2> >(sed 's/^[^:]*:io:[^ ]* //' > YYYY)
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</programlisting>
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<para>
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You will need large amounts of hard disk space (read hundreds
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of megabytes if you do a full page scan), and for reasonable
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performance a really fast processor and lots of RAM.
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</para>
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<para>
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You will need to postprocess the output into a more manageable
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format, using the <command>shrink</command> program. First
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you need to compile the source (which is located at the end of
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this section):
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<programlisting>
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cc shrink.c -o shrink
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</programlisting>
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</para>
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<para>
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Use the <command>shrink</command> program to reduce the
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physical size of the raw log as follows:
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</para>
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<programlisting>
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cat log | shrink > log2
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</programlisting>
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<para>
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The trace has the basic form of
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</para>
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<programlisting>
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XXXX > YY @ ZZZZ:ZZZZ
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</programlisting>
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<para>
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where <literal>XXXX</literal> is the port in hexadecimal being
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accessed, <literal>YY</literal> is the data written (or read)
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from the port, and <literal>ZZZZ:ZZZZ</literal> is the address
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in memory of the instruction that accessed the port. The
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direction of the arrow indicates whether the data was written
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or read from the port.
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</para>
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<programlisting>
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> data was written to the port
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< data was read from the port
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</programlisting>
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<para>
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My basic tip for interpreting these logs is to pay close
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attention to the addresses of the IO instructions. Their
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grouping and sometimes proximity should reveal the presence of
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subroutines in the driver. By studying the different versions
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you should be able to work them out. For example consider the
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following section of trace from my UMAX Astra 600P
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</para>
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<programlisting>
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0x378 > 55 @ 0297:01ec
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0x37a > 05 @ 0297:01f5
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0x379 < 8f @ 0297:01fa
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0x37a > 04 @ 0297:0211
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0x378 > aa @ 0297:01ec
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0x37a > 05 @ 0297:01f5
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0x379 < 8f @ 0297:01fa
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0x37a > 04 @ 0297:0211
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0x378 > 00 @ 0297:01ec
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0x37a > 05 @ 0297:01f5
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0x379 < 8f @ 0297:01fa
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0x37a > 04 @ 0297:0211
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0x378 > 00 @ 0297:01ec
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0x37a > 05 @ 0297:01f5
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0x379 < 8f @ 0297:01fa
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0x37a > 04 @ 0297:0211
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0x378 > 00 @ 0297:01ec
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0x37a > 05 @ 0297:01f5
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0x379 < 8f @ 0297:01fa
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0x37a > 04 @ 0297:0211
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0x378 > 00 @ 0297:01ec
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0x37a > 05 @ 0297:01f5
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0x379 < 8f @ 0297:01fa
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0x37a > 04 @ 0297:0211
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</programlisting>
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<para>
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As you can see there is a repeating structure starting at
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address <literal>0297:01ec</literal> that consists of four io
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accesses on the parallel port. Looking at it the first io
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access writes a changing byte to the data port the second
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always writes the byte <literal>0x05</literal> to the control
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port, then a value which always seems to
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<literal>0x8f</literal> is read from the status port at which
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point a byte <literal>0x04</literal> is written to the control
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port. By studying this and other sections of the trace we can
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write a C routine that emulates this, shown below with some
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macros to make reading/writing on the parallel port easier to
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read.
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</para>
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<programlisting>
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#define r_dtr(x) inb(x)
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#define r_str(x) inb(x+1)
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#define r_ctr(x) inb(x+2)
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#define w_dtr(x,y) outb(y, x)
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#define w_str(x,y) outb(y, x+1)
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#define w_ctr(x,y) outb(y, x+2)
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/* Seems to be sending a command byte to the scanner */
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int udpp_put(int udpp_base, unsigned char command)
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{
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int loop, value;
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w_dtr(udpp_base, command);
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w_ctr(udpp_base, 0x05);
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for (loop=0; loop < 10; loop++)
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if ((value = r_str(udpp_base)) & 0x80)
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{
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w_ctr(udpp_base, 0x04);
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return value & 0xf8;
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}
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return (value & 0xf8) | 0x01;
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}
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</programlisting>
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<para>
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For the UMAX Astra 600P only seven such routines exist (well
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14 really, seven for SPP and seven for EPP). Whether you
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choose to disassemble the driver at this point to verify the
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routines is your own choice. If you do, the address from the
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trace should help in locating them in the disassembly.
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</para>
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<para>
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You will probably then find it useful to write a script/perl/C
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program to analyse the logfile and decode them futher as this
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can reveal higher level grouping of the low level routines.
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For example from the logs from my UMAX Astra 600P when decoded
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further reveal (this is a small snippet)
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</para>
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<programlisting>
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start:
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put: 55 8f
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put: aa 8f
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put: 00 8f
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put: 00 8f
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put: 00 8f
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put: c2 8f
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wait: ff
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get: af,87
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wait: ff
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get: af,87
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end: cc
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start:
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put: 55 8f
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put: aa 8f
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put: 00 8f
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put: 03 8f
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put: 05 8f
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put: 84 8f
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wait: ff
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</programlisting>
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<para>
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From this it is easy to see that <varname>put</varname>
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routine is often grouped together in five successive calls
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sending information to the scanner. Once these are understood
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it should be possible to process the logs further to show the
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higher level routines in an easy to see format. Once the
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highest level format that you can derive from this process is
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understood, you then need to produce a series of scans varying
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only one parameter between them, so you can discover how to
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set the various parameters for the scanner.
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</para>
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<para>
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The following is the <filename>shrink.c</filename> program:
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<programlisting>
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/* Copyright David Campbell <campbell@torque.net> */
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#include <stdio.h>
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#include <string.h>
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int main (void)
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{
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char buff[256], lastline[256] = "";
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int count = 0;
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while (!feof (stdin))
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{
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fgets (buff, sizeof (buff), stdin);
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if (strcmp (buff, lastline))
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{
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if (count > 1)
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printf ("# Last line repeated %i times #\n", count);
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printf ("%s", buff);
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strcpy (lastline, buff);
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count = 1;
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}
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else count++;
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}
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return 0;
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}
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</programlisting>
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</para>
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</sect1>
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<sect1 id="undoc-func">
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<title>Understanding undocumented APIs</title>
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<para>
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Some background: On the i386 class of machines, stack entries are
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usually dword (4 bytes) in size, little-endian. The stack grows
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downward in memory. The stack pointer, maintained in the
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<literal>esp</literal> register, points to the last valid entry;
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thus, the operation of pushing a value onto the stack involves
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decrementing <literal>esp</literal> and then moving the value into
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the memory pointed to by <literal>esp</literal>
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(i.e., <literal>push p</literal> in assembly resembles
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<literal>*(--esp) = p;</literal> in C). Removing (popping)
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values off the stack is the reverse (i.e., <literal>pop p</literal>
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corresponds to <literal>p = *(esp++);</literal> in C).
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</para>
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<para>
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In the <literal>stdcall</literal> calling convention, arguments are
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pushed onto the stack right-to-left. For example, the C call
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<function>myfunction(40, 20, 70, 30);</function> is expressed in
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Intel assembly as:
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<screen>
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push 30
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push 70
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push 20
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push 40
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call myfunction
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</screen>
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The called function is responsible for removing the arguments
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off the stack. Thus, before the call to myfunction, the
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stack would look like:
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<screen>
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[local variable or temporary]
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[local variable or temporary]
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30
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70
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20
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esp -> 40
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</screen>
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After the call returns, it should look like:
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<screen>
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[local variable or temporary]
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esp -> [local variable or temporary]
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</screen>
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</para>
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<para>
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To restore the stack to this state, the called function must know how
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many arguments to remove (which is the number of arguments it takes).
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This is a problem if the function is undocumented.
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</para>
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<para>
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One way to attempt to document the number of arguments each function
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takes is to create a wrapper around that function that detects the
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stack offset. Essentially, each wrapper assumes that the function will
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take a large number of arguments. The wrapper copies each of these
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arguments into its stack, calls the actual function, and then calculates
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the number of arguments by checking esp before and after the call.
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</para>
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<para>
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The main problem with this scheme is that the function must actually
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be called from another program. Many of these functions are seldom
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used. An attempt was made to aggressively query each function in a
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given library (<filename>ntdll.dll</filename>) by passing 64 arguments,
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all 0, to each function. Unfortunately, Windows NT quickly goes to a
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blue screen of death, even if the program is run from a
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non-administrator account.
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</para>
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<para>
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Another method that has been much more successful is to attempt to
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figure out how many arguments each function is removing from the
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stack. This instruction, <literal>ret hhll</literal> (where
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<symbol>hhll</symbol> is the number of bytes to remove, i.e. the
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number of arguments times 4), contains the bytes
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<literal>0xc2 ll hh</literal> in memory. It is a reasonable
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assumption that few, if any, functions take more than 16 arguments;
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therefore, simply searching for
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<literal>hh == 0 && ll < 0x40</literal> starting from the
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address of a function yields the correct number of arguments most
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of the time.
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</para>
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<para>
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Of course, this is not without errors. <literal>ret 00ll</literal>
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is not the only instruction that can have the byte sequence
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<literal>0xc2 ll 0x0</literal>; for example,
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<literal>push 0x000040c2</literal> has the byte sequence
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<literal>0x68 0xc2 0x40 0x0 0x0</literal>, which matches
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the above. Properly, the utility should look for this sequence
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only on an instruction boundary; unfortunately, finding
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instruction boundaries on an i386 requires implementing a full
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disassembler -- quite a daunting task. Besides, the probability
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of having such a byte sequence that is not the actual return
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instruction is fairly low.
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</para>
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<para>
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Much more troublesome is the non-linear flow of a function. For
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example, consider the following two functions:
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<screen>
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somefunction1:
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jmp somefunction1_impl
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somefunction2:
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ret 0004
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somefunction1_impl:
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ret 0008
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</screen>
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In this case, we would incorrectly detect both
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<function>somefunction1</function> and
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<function>somefunction2</function> as taking only a single
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argument, whereas <function>somefunction1</function> really
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takes two arguments.
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</para>
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<para>
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With these limitations in mind, it is possible to implement
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more stubs
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in Wine and, eventually, the functions themselves.
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</para>
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</sect1>
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<sect1>
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<title>How to do regression testing using CVS</title>
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<para>
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A problem that can happen sometimes is 'it used to work
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before, now it doesn't anymore...'. Here is a step by step
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procedure to try to pinpoint when the problem occurred. This
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is <emphasis>NOT</emphasis> for casual users.
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</para>
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<orderedlist>
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<listitem>
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<para>
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Get the <quote>full CVS</quote> archive from winehq. This
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archive is the CVS tree but with the tags controlling the
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versioning system. It's a big file (> 40 meg) with a name
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like full-cvs-<last update date> (it's more than 100mb
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when uncompressed, you can't very well do this with
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small, old computers or slow Internet connections).
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</para>
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</listitem>
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<listitem>
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<para>
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untar it into a repository directory:
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<screen>
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cd /home/gerard
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tar -zxf full-cvs-2003-08-18.tar.gz
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mv wine repository
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</screen>
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</para>
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</listitem>
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<listitem>
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<para>
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extract a new destination directory. This directory must
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not be in a subdirectory of the repository else
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<command>cvs</command> will think it's part of the
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repository and deny you an extraction in the repository:
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<screen>
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cd /home/gerard
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mv wine wine_current (-> this protects your current wine sandbox, if any)
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export CVSROOT=/home/gerard/repository
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cvs -d $CVSROOT checkout wine
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</screen>
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</para>
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<para>
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Note that it's not possible to do a checkout at a given
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date; you always do the checkout for the last date where
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the full-cvs-xxx snapshot was generated.
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</para>
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<para>
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Note also that it is possible to do all this with a direct
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CVS connection, of course. The full CVS file method is less
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painful for the WineHQ CVS server and probably a bit faster
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if you don't have a very good net connection.
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</para>
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</listitem>
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<listitem>
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<para>
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you will have now in the <filename>~/wine</filename>
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directory an image of the CVS tree, on the client side.
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Now update this image to the date you want:
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<screen>
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cd /home/gerard/wine
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cvs update -PAd -D "2004-08-23 CDT"
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</screen>
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</para>
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<para>
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The date format is <literal>YYYY-MM-DD HH:MM:SS</literal>.
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Using the CST date format ensure that you will be able to
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extract patches in a way that will be compatible with the
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wine-cvs archive
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<ulink url="http://www.winehq.org/hypermail/wine-cvs">
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http://www.winehq.org/hypermail/wine-cvs</ulink>
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</para>
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<para>
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Many messages will inform you that more recent files have
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been deleted to set back the client cvs tree to the date
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you asked, for example:
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<screen>
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cvs update: tsx11/ts_xf86dga2.c is no longer in the repository
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</screen>
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</para>
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<para>
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<command>cvs update</command> is not limited to upgrade to
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a <emphasis>newer</emphasis> version as I have believed for
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far too long :-(
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</para>
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</listitem>
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<listitem>
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<para>
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Now proceed as for a normal update:
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</para>
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<screen>
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./configure
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make depend && make
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</screen>
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<para>
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|
If any non-programmer reads this, the fastest method to
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get at the point where the problem occurred is to use a
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binary search, that is, if the problem occurred in 1999,
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|
start at mid-year, then is the problem is already here,
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|
back to 1st April, if not, to 1st October, and so on.
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|
</para>
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<para>
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If you have lot of hard disk free space (a full compile
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|
currently takes 400 Mb), copy the oldest known working
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|
version before updating it, it will save time if you need
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to go back. (it's better to <command>make
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distclean</command> before going back in time, so you
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have to make everything if you don't backup the older
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version)
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</para>
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<para>
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When you have found the day where the problem happened,
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continue the search using the wine-cvs archive (sorted by
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date) and a more precise cvs update including hour,
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minute, second:
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<screen>
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cvs update -PAd -D "2004-08-23 15:17:25 CDT"
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</screen>
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This will allow you to find easily the exact patch that
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did it.
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</para>
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</listitem>
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<listitem>
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<para>
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|
If you find the patch that is the cause of the problem,
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you have almost won; report about it to
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<ulink url="http://bugs.winehq.org/">Wine Bugzilla</ulink>
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|
or subscribe to wine-devel and post it there. There is a
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|
chance that the author will jump in to suggest a fix; or
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|
there is always the possibility to look hard at the patch
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|
until it is coerced to reveal where is the bug :-)
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</para>
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</listitem>
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</orderedlist>
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</sect1>
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<sect1>
|
|
<title>Which code has been tested?</title>
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|
<para>
|
|
Deciding what code should be tested next can be a difficult
|
|
decision. And in any given project, there is always code that
|
|
isn't tested where bugs could be lurking. This section goes
|
|
over how to identify these sections using a tool called gcov.
|
|
</para>
|
|
<para>
|
|
To use gcov on wine, do the following:
|
|
</para>
|
|
<orderedlist>
|
|
<listitem>
|
|
<para>
|
|
In order to activate code coverage in the wine source code,
|
|
when running <command>make</command> set
|
|
<literal>CFLAGS</literal> like so <command>make
|
|
CFLAGS="-fprofile-arcs -ftest-coverage"</command>. Note that
|
|
this can be done at any directory level. Since compile
|
|
and run time are significantly increased by these flags, you
|
|
may want to only use these flags inside a given dll directory.
|
|
</para>
|
|
</listitem>
|
|
<listitem>
|
|
<para>
|
|
Run any application or test suite.
|
|
</para>
|
|
</listitem>
|
|
<listitem>
|
|
<para>
|
|
Run gcov on the file which you would like to know more
|
|
about code coverage.
|
|
</para>
|
|
</listitem>
|
|
</orderedlist>
|
|
<para>
|
|
The following is an example situation when using gcov to
|
|
determine the coverage of a file could be helpful. We'll use
|
|
the <filename>dlls/lzexpand/lzexpand_main.c.</filename> file.
|
|
At one time the code in this file was not fully tested (as it
|
|
may still be). For example at the time of this writing, the
|
|
function <function>LZOpenFileA</function> had the following
|
|
lines in it:
|
|
<screen>
|
|
if ((mode&~0x70)!=OF_READ)
|
|
return fd;
|
|
if (fd==HFILE_ERROR)
|
|
return HFILE_ERROR;
|
|
cfd=LZInit(fd);
|
|
if ((INT)cfd <= 0) return fd;
|
|
return cfd;
|
|
</screen>
|
|
Currently there are a few tests written to test this function;
|
|
however, these tests don't check that everything is correct.
|
|
For instance, <constant>HFILE_ERROR</constant> may be the wrong
|
|
error code to return. Using gcov and directed tests, we can
|
|
validate the correctness of this line of code. First, we see
|
|
what has been tested already by running gcov on the file.
|
|
To do this, do the following:
|
|
<screen>
|
|
cvs checkout wine
|
|
mkdir build
|
|
cd build
|
|
../wine/configure
|
|
make depend && make CFLAGS="-fprofile-arcs -ftest-coverage"
|
|
cd dlls/lxexpand/tests
|
|
make test
|
|
cd ..
|
|
gcov ../../../wine/dlls/lzexpand/lzexpand_main.c
|
|
0.00% of 3 lines executed in file ../../../wine/include/wine/unicode.h
|
|
Creating unicode.h.gcov.
|
|
0.00% of 4 lines executed in file /usr/include/ctype.h
|
|
Creating ctype.h.gcov.
|
|
0.00% of 6 lines executed in file /usr/include/bits/string2.h
|
|
Creating string2.h.gcov.
|
|
100.00% of 3 lines executed in file ../../../wine/include/winbase.h
|
|
Creating winbase.h.gcov.
|
|
50.83% of 240 lines executed in file ../../../wine/dlls/lzexpand/lzexpand_main.c
|
|
Creating lzexpand_main.c.gcov.
|
|
less lzexpand_main.c.gcov
|
|
</screen>
|
|
Note that there is more output, but only output of gcov is
|
|
shown. The output file
|
|
<filename>lzexpand_main.c.gcov</filename> looks like this.
|
|
<screen>
|
|
9: 545: if ((mode&~0x70)!=OF_READ)
|
|
6: 546: return fd;
|
|
3: 547: if (fd==HFILE_ERROR)
|
|
#####: 548: return HFILE_ERROR;
|
|
3: 549: cfd=LZInit(fd);
|
|
3: 550: if ((INT)cfd <= 0) return fd;
|
|
3: 551: return cfd;
|
|
</screen>
|
|
<command>gcov</command> output consists of three components:
|
|
the number of times a line was run, the line number, and the
|
|
actual text of the line. Note: If a line is optimized out by
|
|
the compiler, it will appear as if it was never run. The line
|
|
of code which returns <constant>HFILE_ERROR</constant> is
|
|
never executed (and it is highly unlikely that it is optimized
|
|
out), so we don't know if it is correct. In order to validate
|
|
this line, there are two parts of this process. First we must
|
|
write the test. Please see <xref linkend="testing"> to
|
|
learn more about writing tests. We insert the following lines
|
|
into a test case:
|
|
<screen>
|
|
INT file;
|
|
|
|
/* Check for nonexistent file */
|
|
file = LZOpenFile("badfilename_", &test, OF_READ);
|
|
ok(file == LZERROR_BADINHANDLE,
|
|
"LZOpenFile succeeded on nonexistent file\n");
|
|
LZClose(file);
|
|
</screen>
|
|
Once we add in this test case, we now want to know if the line
|
|
in question is run by this test and works as expected. You
|
|
should be in the same directory as you left off in the previous
|
|
command example. The only difference is that we have to remove
|
|
the <filename>*.da</filename> files in order to start the
|
|
count over (if we leave the files than the number of times the
|
|
line is run is just added, e.g. line 545 below would be run 19 times)
|
|
and we remove the <filename>*.gcov</filename> files because
|
|
they are out of date and need to be recreated.
|
|
</para>
|
|
<screen>
|
|
rm *.da *.gcov
|
|
cd tests
|
|
make
|
|
make test
|
|
cd ..
|
|
gcov ../../../wine/dlls/lzexpand/lzexpand_main.c
|
|
0.00% of 3 lines executed in file ../../../wine/include/wine/unicode.h
|
|
Creating unicode.h.gcov.
|
|
0.00% of 4 lines executed in file /usr/include/ctype.h
|
|
Creating ctype.h.gcov.
|
|
0.00% of 6 lines executed in file /usr/include/bits/string2.h
|
|
Creating string2.h.gcov.
|
|
100.00% of 3 lines executed in file ../../../wine/include/winbase.h
|
|
Creating winbase.h.gcov.
|
|
51.67% of 240 lines executed in file ../../../wine/dlls/lzexpand/lzexpand_main.c
|
|
Creating lzexpand_main.c.gcov.
|
|
less lzexpand_main.c.gcov
|
|
</screen>
|
|
<para>
|
|
Note that there is more output, but only output of gcov is
|
|
shown. The output file
|
|
<filename>lzexpand_main.c.gcov</filename> looks like this.
|
|
</para>
|
|
<screen>
|
|
10: 545: if ((mode&~0x70)!=OF_READ)
|
|
6: 546: return fd;
|
|
4: 547: if (fd==HFILE_ERROR)
|
|
1: 548: return HFILE_ERROR;
|
|
3: 549: cfd=LZInit(fd);
|
|
3: 550: if ((INT)cfd <= 0) return fd;
|
|
3: 551: return cfd;
|
|
</screen>
|
|
<para>
|
|
Based on gcov, we now know that
|
|
<constant>HFILE_ERROR</constant> is returned once. And since
|
|
all of our other tests have remain unchanged, we can assume
|
|
that the one time it is returned is to satisfy the one case we
|
|
added where we check for it. Thus we have validated a line of
|
|
code. While this is a cursory example, it demostrates the
|
|
potential usefulness of this tool.
|
|
</para>
|
|
<para>
|
|
For a further in depth description of gcov, the official gcc
|
|
compiler suite page for gcov is <ulink
|
|
url="http://gcc.gnu.org/onlinedocs/gcc-3.2.3/gcc/Gcov.html">
|
|
http://gcc.gnu.org/onlinedocs/gcc-3.2.3/gcc/Gcov.html</ulink>.
|
|
There is also an excellent article written by Steve Best for
|
|
Linux Magazine which describes and illustrates this process
|
|
very well at
|
|
<ulink url="http://www.linux-mag.com/2003-07/compile_01.html">
|
|
http://www.linux-mag.com/2003-07/compile_01.html</ulink>.
|
|
</para>
|
|
</sect1>
|
|
|
|
</chapter>
|
|
|
|
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