[ planet-factor ]

Daniel Ehrenberg: Parsing with regular expressions and group capture

Though I'd rather avoid it, string parsing is a crucial part of programming. Since we're more than 60 years into the use of modern computers, it seems like we should have a pretty good handle on how to build abstractions over parsing. Indeed, there are tons of great tools out there, like GNU Yacc, Haskell's Parsec, newer Packrat-based parsers like Factor's EBNF syntax for PEGs, and a bunch of other high level parsing libraries. These libraries are relatively easy to use once you understand the underlying structure (each one parses a different subset of context-free grammars), because they expose the programmer to a tree-like view of the string.

However, these incur too much overhead to be used for certain domains, like the parsing that goes on in an HTTP server or client. They're really overkill when, as in the case of HTTP interchanges, what you're dealing with is a regular language and processing can be done on-line. (I'll get back later to what I mean by those two things.) The main tools that exist to deal with this are Lex and Ragel.

Ragel seems like a really interesting solution for this domain. The entire description of parsing is eventually put in one regular expression, which is compiled to a DFA, where states and transitions can be annotated by actions. Fine-grained control is given to limit non-determinism. But the user must be acutely aware of how regular expressions correspond to DFAs in order to use the abstraction. So it is somewhat leaky. Also, it's difficult to get a tree-like view on things: actions are used purely for their side effect.

So, here's an idea: let's find a middle ground. Let's try to use regular expressions, with all of their efficiency advantages, but get an abstract tree-like view of the grammar and an ability to use parsing actions like high-level abstractions allow. Ideally, the user won't have to know about the implementation beyond two simple facts: regular languages can't use general recursion, and nondeterminism should be minimized.

This isn't something that I've implemented, but I have a pretty good idea for the design of such as system, and I wanted to share it with you. First, a little background.

DFAs and regular expressions

Regular expressions in practice in parsing today

Group capture with regexes

Hierarchical parsing using group capture

REG: tag
chars = "&" entity:any* > ";" [[ entity lookup-entity ]]
    | any
string = "\"" str:chars > "\"" [[ str ]]
    | "'" str:chars > "'" [[ str ]]
xml-name = name-start-char name-char*
attribute = name:xml-name ws "=" ws str:string [[ name str 2array ]]
tag = "<" ws closer?:("/"?) name:xml-name attrs:(attribute*) ws contained?:("/"?) ws ">" [[ ... ]]

Conclusion

Sat, 10 May 2008 11:05:00

Slava Pestov: Garbage collection throughput improvements

The problem

Faster card scanning

u32 *quad_ptr;
u32 quad_mask = mask | (mask << 8) | (mask << 16) | (mask << 24);

for(quad_ptr = (u32 *)first_card; quad_ptr < (u32 *)last_card; quad_ptr++)
{
        if(*quad_ptr & quad_mask)
        {
                F_CARD *ptr = (F_CARD *)quad_ptr;
                
                int card;
                for(card = 0; card < 4; card++)
                {
                        if(ptr[card] & mask)
                        {
                                collect_card(&ptr[card],gen,here);
                                ptr[card] &= ~unmask;
                        }
                }
        }
}

Introducing card decks

Low-level optimizations

void copy_handle(CELL *handle)
{
        CELL pointer = *handle;

        if(!immediate_p(pointer) && should_copy(pointer))
                *handle = copy_object(pointer);
}

CELL collect_next(CELL scan)
{
        do_slots(scan,copy_handle);

        if(collecting_gen == TENURED)
                do_code_slots(scan);

        return scan + untagged_object_size(scan);
}

/* test if the pointer is in generation being collected, or a younger one. */
INLINE bool should_copy(CELL untagged)
{
        if(in_zone(newspace,untagged))
                return false;
        if(collecting_gen == TENURED)
                return true;
        else if(HAVE_AGING_P && collecting_gen == AGING)
                return !in_zone(&data_heap->generations[TENURED],untagged);
        else if(HAVE_NURSERY_P && collecting_gen == NURSERY)
                return in_zone(&nursery,untagged);
        else
        {
                critical_error("Bug in should_copy",untagged);
                return false;
        }
}

while(A)
{
        if(foo()) B else C;
}

if(foo)
{
        while(A) B;
}
else
{
        while(A) C;
}

CELL collect_next(CELL scan)
{
        CELL *obj = (CELL *)scan;
        CELL *end = (CELL *)(scan + binary_payload_start(scan));

        obj++;

        CELL newspace_start = newspace->start;
        CELL newspace_end = newspace->end;

        if(HAVE_NURSERY_P && collecting_gen == NURSERY)
        {
                CELL nursery_start = nursery.start;
                CELL nursery_end = nursery.end;

                for(; obj < end; obj++)
                {
                        CELL pointer = *obj;

                        if(!immediate_p(pointer)
                                && (pointer >= nursery_start && pointer < nursery_end))
                                *obj = copy_object(pointer);
                }
        }
        else if(HAVE_AGING_P && collecting_gen == AGING)
        {
                F_ZONE *tenured = &data_heap->generations[TENURED];

                CELL tenured_start = tenured->start;
                CELL tenured_end = tenured->end;

                for(; obj < end; obj++)
                {
                        CELL pointer = *obj;

                        if(!immediate_p(pointer)
                                && !(pointer >= newspace_start && pointer < newspace_end)
                                && !(pointer >= tenured_start && pointer < tenured_end))
                                *obj = copy_object(pointer);
                }
        }
        else if(collecting_gen == TENURED)
        {
                for(; obj < end; obj++)
                {
                        CELL pointer = *obj;

                        if(!immediate_p(pointer)
                                && !(pointer >= newspace_start && pointer < newspace_end))
                                *obj = copy_object(pointer);
                }

                do_code_slots(scan);
        }
        else
                critical_error("Bug in collect_next",0);

        return scan + untagged_object_size(scan);
}

Benchmarks

: garbage 1 2 3 3array ;

: garbage-loop 150000000 [ garbage drop ] times ;

[ garbage-loop ] time

: garbage 100 f <array> ;

: garbage-loop 15000000 [ garbage drop ] times ;

[ garbage-loop ] time

: garbage 100 f <array> ;

: garbage-loop 150 [ 10000 [ drop garbage ] map drop ] times ;

[ garbage-loop ] time

Looking ahead

Sat, 10 May 2008 00:33:00

Daniel Ehrenberg: Interval maps in Factor

Recently, I wrote a little library in Factor to get the script of a Unicode code point. It's in the Factor git repository in the vocab unicode.script. Initially, I relatively simple representation of the data: there was a byte array, where the index was the code point and the elements were bytes corresponding to scripts. (It's possible to use a byte array because there are only seventy-some scripts to care about.) Lookup consisted of char>num-table nth num>name-table nth. But this was pretty inefficient. The largest code point (that I wanted to represent here) was something around number 195,000, meaning that the byte array took up almost 200Kb. Even if I somehow got rid of that empty space (and I don't see an obvious way how, without a bunch of overhead), there are 100,000 code points whose script I wanted to encode.

But we can do better than taking up 100Kb. The thing about this data is that scripts are in a bunch of contiguous ranges. That is, two characters that are next to each other in code point order are very likely to have the same script. The file in the Unicode Character Database encoding this information actually uses special syntax to denote a range, rather than write out each one individually. So what if we store these intervals directly rather than store each element of the intervals?

A data structure to hold intervals with O(log n) lookup and insertion has already been developed: interval trees. They're described in Chapter 14 of Introduction to Algorithms starting on page 311, but I won't describe them here. At first, I tried to implement these, but I realized that, for my purposes, they're overkill. They're really easy to get wrong: if you implement them on top of another kind of balanced binary tree, you have to make sure that balancing preserves certain invariants about annotations on the tree. Still, if you need fast insertion and deletion, they make the most sense.

A much simpler solution is to just have a sorted array of intervals, each associated with a value. The right interval, and then the corresponding value, can be found by simple binary search. I don't even need to know how to do binary search, because it's already in the Factor library! This is efficient as long as the interval map is constructed all at once, which it is in this case. By a high constant factor, this is also more space-efficient than using binary trees. The whole solution takes less than 30 lines of code.

(Note: the intervals here are closed and must be disjoint. <=> must be defined on them. They don't use the intervals in math.intervals to save space, and since they're overkill. Interval maps don't follow the assoc protocol because intervals aren't discrete, eg floats are acceptable as keys.)

First, the tuples we'll be using: an interval-map is the whole associative structure, containing a single slot for the underlying array.

TUPLE: interval-map array ;

TUPLE: interval-node from to value ;

: find-interval ( key interval-map -- i )
    [ from>> <=> ] binsearch ;

: interval-contains? ( object interval-node -- ? )
    [ from>> ] [ to>> ] bi between? ;

: fixup-value ( value ? -- value/f ? )
    [ drop f f ] unless* ;

: interval-at* ( key map -- value ? )
    array>> [ find-interval ] 2keep swapd nth
    [ nip value>> ] [ interval-contains? ] 2bi
    fixup-value ;

: interval-at ( key map -- value ) interval-at* drop ;
: interval-key? ( key map -- ? ) interval-at* nip ;

: all-intervals ( sequence -- intervals )
    [ >r dup number? [ dup 2array ] when r> ] assoc-map
    { } assoc-like ;

: >intervals ( specification -- intervals )
    [ >r first2 r> interval-node boa ] { } assoc>map ;

: disjoint? ( node1 node2 -- ? )
    [ to>> ] [ from>> ] bi* < ;

: ensure-disjoint ( intervals -- intervals )
    dup [ disjoint? ] monotonic?
    [ "Intervals are not disjoint" throw ] unless ;

: <interval-map> ( specification -- map )
    all-intervals [ [ first second ] compare ] sort
    >intervals ensure-disjoint >tuple-array
    interval-map boa ;

Wed, 7 May 2008 21:50:00

Slava Pestov: I/O changes, and process pipeline support

I made some improvements to the I/O system today.

Default stream variables

• with-input-stream
• with-output-stream
• with-input-stream*
• with-output-stream*

"foo.txt" utf8 [
    "blah.txt" utf8 [
        ... read from the first file, write to the second file,
        using read and write ...
    ] with-file-writer
] with-file-reader

"foo.txt" utf8 <file-reader> [
    "blah.txt" utf8 <file-writer> [
        <duplex-stream> [
            ...
        ] with-stream
    ] with-disposal
] with-disposal

Pipes

• <pipe> creates a new pipe and wraps a pair of streams around it. The streams are packaged into a single duplex stream; any data written to the stream can be read back from the same stream (presumably, in a different thread). This is actually implemented with native pipes on Unix and Windows.
• The run-pipeline word takes a sequence of quotations or launch descriptors, and runs them all in parallel with input wired up as if it were a Unix shell pipe. For example,
  

  { "cat foo.txt" "grep x" "sort" "uniq" } run-pipeline

  
  Corresponds to the following shell command:
  

  cat foo.txt | grep x | sort | uniq

  
  In addition, being able to place process objects and quotations in the pipeline gives you a lot of expressive power.

Appending process output to files

<process>
    "do-stuff" >>command
    "log.txt" <appender> >>stderr
run-process

do-stuff 2>> do-stuff.txt

USING: system alien.c-types kernel unix math sequences
qualified io.unix.backend io.nonblocking ;
IN: io.unix.pipes
QUALIFIED: io.pipes

M: unix io.pipes:(pipe) ( -- pair )
    2 "int" <c-array>
    dup pipe io-error
    2 c-int-array> first2
    [ [ init-handle ] bi@ ] [ io.pipes:pipe boa ] 2bi ;

USING: alien alien.c-types arrays destructors io io.windows libc
windows.types math.bitfields windows.kernel32 windows namespaces
kernel sequences windows.errors assocs math.parser system random
combinators accessors io.pipes io.nonblocking ;
IN: io.windows.nt.pipes

: create-named-pipe ( name -- handle )
    { PIPE_ACCESS_INBOUND FILE_FLAG_OVERLAPPED } flags
    PIPE_TYPE_BYTE
    1
    4096
    4096
    0
    security-attributes-inherit
    CreateNamedPipe
    dup win32-error=0/f
    dup add-completion
    f <win32-file> ;

: open-other-end ( name -- handle )
    GENERIC_WRITE
    { FILE_SHARE_READ FILE_SHARE_WRITE } flags
    security-attributes-inherit
    OPEN_EXISTING
    FILE_FLAG_OVERLAPPED
    f
    CreateFile
    dup win32-error=0/f
    dup add-completion
    f <win32-file> ;

: unique-pipe-name ( -- string )
    [
        "\\\\.\\pipe\\factor-" %
        pipe counter #
        "-" %
        32 random-bits #
        "-" %
        millis #
    ] "" make ;

M: winnt (pipe) ( -- pipe )
    [
        unique-pipe-name
        [ create-named-pipe dup close-later ]
        [ open-other-end dup close-later ]
        bi pipe boa
    ] with-destructors ;

Mon, 5 May 2008 18:02:00

Daniel Ehrenberg: A couple GC algorithms in more detail

In previous posts on garbage collection, I've given a pretty cursory overview as to how things actually work. In this post, I hope to give a somewhat more specific explanation of two incremental (and potentially concurrent or parallel, but we'll ignore that for now) GC algorithms: Yuasa's snapshot-at-the-beginning incremental mark-sweep collector, and the MC² algorithm. Yuasa's collector is very widely used, for example in Java 5 when an incremental collector is requested. MC² is a more recent algorithm designed to reduce the fragmentation that mark-sweep creates, and appears to get great performance, though it isn't used much yet. In their practical implementation, both collectors are generational.

Yuasa's mark-sweep collector

Making this work

Conservativeness

MC²

MC

New modifications

Sat, 3 May 2008 00:51:00

Slava Pestov: USA Zip code database

Recently someone posted a freely available Zip code database on reddit. The database is in CSV format.

Phil Dawes contributed a CSV parser to Factor a few days ago, and I thought this would be the perfect use-case to test out the parser.

I added the library to extra/usa-cities. It begins with the usual boilerplate:

USING: io.files io.encodings.ascii sequences sequences.lib
math.parser combinators kernel memoize csv symbols inspector
words accessors math.order sorting ;
IN: usa-cities

SINGLETONS: AK AL AR AS AZ CA CO CT DC DE FL GA HI IA ID IL IN
KS KY LA MA MD ME MI MN MO MS MT NC ND NE NH NJ NM NV NY OH OK
OR PA PR RI SC SD TN TX UT VA VI VT WA WI WV WY ;

: states ( -- seq )
    {
        AK AL AR AS AZ CA CO CT DC DE FL GA HI IA ID IL IN KS KY
        LA MA MD ME MI MN MO MS MT NC ND NE NH NJ NM NV NY OH OK
        OR PA PR RI SC SD TN TX UT VA VI VT WA WI WV WY
    } ; inline

ERROR: no-such-state name ;

M: no-such-state summary drop "No such state" ;

MEMO: string>state ( string -- state )
    dup states [ word-name = ] with find nip
    [ ] [ no-such-state ] ?if ;

TUPLE: city
first-zip name state latitude longitude gmt-offset dst-offset ;

MEMO: cities ( -- seq )
    "resource:extra/usa-cities/zipcode.csv" ascii <file-reader>
    csv rest-slice [
        7 firstn {
            [ string>number ]
            [ ]
            [ string>state ]
            [ string>number ]
            [ string>number ]
            [ string>number ]
            [ string>number ]
        } spread city boa
    ] map ;

• We begin by opening a stream for reading from the CSV file with ASCII encoding.
• The csv word reads CSV data from a stream.
• The first line of the file consists of column headings and not actual data, so we ignore it by using the non-copying variant of rest, rest-slice (recall that the primary sequence type in Factor is an array, so removing the first element makes a copy; a slice is a virtual sequence presenting a view of a subsequence of an array).
• The spread combinator takes a sequence of quotations, Q1,...,QN, and n values from the stack, X1,...XN, and outputs Q1[X1],...,QN[XN]. In this case we're taking the first 7 elements of each row of CSV data (each row has exactly 7 columns so in effect we're pushing every element of the sequence on the stack), then using spread to convert some columns from their initial text format into something more useful to us; a state singleton or a number.
• Finally, we use city boa to construct a city tuple "by order of arguments"; this slurps the 7 stack values and stores them into a new instance of city (note that the definition of the city type has exactly 7 slots and they are defined in the same order as the columns of the file).
• Finally, we map over the sequence of rows to perform the above steps on each row of the file. The result is a sequence of city instances.

MEMO: cities-named ( name -- cities )
    cities [ name>> = ] with filter ;

MEMO: cities-named-in ( name state -- cities )
    cities [
        tuck [ name>> = ] [ state>> = ] 2bi* and
    ] with with filter ;

: find-zip-code ( code -- city )
    cities [ first-zip>> <=> ] binsearch* ;

( scratchpad ) 55406 find-zip-code .
T{ city f 55406 "Minneapolis" MN 44.938615 -93.22082 -6 1 }

( scratchpad ) 90210 find-zip-code .
T{ city f 90210 "Beverly Hills" CA 34.088808 -118.40612 -8 1 }

( scratchpad ) "Minneapolis" cities-named [ state>> ] map prune .
V{ NC MN KS }

( scratchpad ) "Austin" TX cities-named-in [ first-zip>> ] map [ infimum . ] [ supremum . ] bi
73301
78972

Tue, 29 Apr 2008 21:45:00

Slava Pestov: An addendum to "The new HTTP server, part 2"

If you run the web app presented in the last blog post verbatim, you will get a "500 Internal server error" with no further indication of what's going wrong. This is because the code I presented has a minor omission.

The opaque error message is intentional: if your web app crashes, you don't necessarily want to expose internal details to every user that comes along (one famous case was reddit.com, which leaked a portion of their Python codebase inside a stack trace at some point). However, if you set the development-mode global variable to a true value, the behavior of the HTTP server changes in two respects:

• If an error occurs, the error page contains the error message as well as the full stack trace.
• Every request begins by calling refresh-all, thus interactive testing of web app changes becomes very straightforward.

"counter.db" sqlite-db [ init-sessions-table ] with-db

Tue, 29 Apr 2008 17:45:00

Slava Pestov: Write once, run anywhere

Apple finally released Java 6 for Mac OS X, about a year late, and it only runs on 64-bit Intel Macs. It also requires Leopard, which isn't such a big deal because anyone can upgrade. I sold my G5 but a lot of people out there still use PowerPC Macs and I guess they're just screwed. It's a shame too because Java 6 is the first release that's starting to approach true usability for desktop applications.

Tue, 29 Apr 2008 17:25:00

Daniel Ehrenberg: Potential ideas to explore

I haven't written in a while, and it's a little hard to get started back up, so here are just a bunch of random ideas in my head that I'd like to share with you guys. Sorry if it's a little incoherent...

Possible extensions to Inverse

Constraint solving

1. Initialize a logic variable X as unbound
2. Unify X with the information, "the first element is what's second from the top of the stack (at runtime)". Now it's known that X is a sequence of length at least 1.
3. Unify X with the information, "the second element is what's on the top of the stack (at runtime)". Now it's know that X is a sequence of length at least two.
4. From the information we have about X, produce a canonical representation, since the inverted quotation is over: an array of the minimum possible length.

The Harmony Project

Backtracking

Garbage collection research ideas

• Figure out how efficient garbage collection on Non-Uniform Memory Access systems can work. The problem (if it is a problem) is that plain old garbage collection on multiprocessor NUMA systems isn't as fast as it could be, because a chunk of memory allocated for a thread may be far away from where it's used. One way to ensure locality is to give each processor (at least) its own heap, where the heap is guaranteed to be stored in the closest memory. But if data needs to be shared between processors, this can be too limiting. A piece of data can be kept on the RAM closest the processor which made the allocating call, but maybe it'd be beneficial to collect data on which processor is using which data, and dynamically move data around to different places in RAM to put it closest to where it's used. A related issue is maximizing locality when actually performing the tracing in the GC, which I have no ideas about.


• Run a real benchmark comparing several GC algorithms. Probably the most annoying thing for programming language implementors trying to pick a good GC algorithm is that there's no comprehensive benchmark to refer to. No one really knows which algorithm is the fastest, so there are two strategies remaining: pick the one that sounds the fastest, or do trial and error among just a few. Each paper about a new algorithm reports speed improvements—over significantly older algorithms. It'd be a big project, but I think it's possible to make a good benchmark suite and test how long it takes for these algorithms to run, in terms of absolute throughput and pause length and frequency, given different allocation strategies. If it's possible, it'd be nice to know what kind of GC performs best given a particular memory use pattern.


• Garbage collector implementation in proof-carrying code. There are a couple invariants that garbage collectors have, that must be preserved. For example, the user can't be exposed to any forwarding pointers, and a new garbage collection can't be started when forwarding pointers exist. The idea of proof-carrying code (an explicit proof, which is type-checked to be accurate, is given with the code) isn't new; it's mostly been used to prove memory consistency safety given untrusted code. But maybe it could be used to prove that a GC implementation is correct.

Ragel-style state machines in Factor

Tue, 29 Apr 2008 15:48:00

Slava Pestov: The new HTTP server, part 2

It's been a month and a half since the first part of this series. Why the long delay? I've been busy with other things. I implemented inheritance, various compiler optimizations, and many other things. In the last couple of weeks I've been working on the web framework again, tying up some loose ends and porting more existing web applications over (namely, the pastebin and planet factor).

In this entry I will talk about session management. Session management was one of the first things I implemented in the new framework when I started working on it, but recently I gave the code an overhaul.

Session management

• For GET and HEAD requests, a cookie is used. The cookie's value is a randomly-generated session ID.
• For POST requests, the form must define a hidden field with the session ID. The value of the cookie is ignored to thwart cross-site scripting attacks.

USING: math kernel accessors http.server http.server.actions
http.server.sessions http.server.templating.fhtml locals ;
IN: webapps.counter

SYMBOL: count

:: <counter-action> ( quot -- action )
    <action> [
        count quot schange
        "" f <standard-redirect>
    ] >>display ;

: <dec-action> ( -- action )
    <action> [ count [ 1- ] schange f ] >>display ;

: <counter-action> ( -- action )
    <action> [
        "resource:extra/webapps/counter/counter.fhtml" <fhtml>
    ] >>display ;

: <counter-app> ( -- responder )
    counter-app new-dispatcher
        [ 1+ ] <counter-action> "inc" add-responder
        [ 1- ] <counter-action> "dec" add-responder
        <display-action> "" add-responder
    <sessions> ;

<% USING: io math.parser http.server.sessions webapps.counter ; %>

<html>
    <body>
        <h1><% count sget number>string write %></h1>

        <a href="inc">++</a>
        <a href="dec">--</a>
    </body>
</html>

<counter-app> "test.db" sqlite-db <db-persistence> main-responder set
8888 httpd

Virtual hosting

<vhost-dispatcher>
    <online-store> "store.acme.com" add-responder
    <support-site> "support.acme.com" add-responder
    <main-site> "acme.com" add-responder
<boilerplate>
    "acme-site.xml" >>template
acme-db <db-persistence>
<sessions> main-responder set

Cookies

( scratchpad ) "http://www.google.com" http-get-stream drop cookies>> first describe
cookie instance
"delegate"  f
"name"      "pref"
"value"     "ID=c0f4c074cd87502e:TM=1209466656:LM=1209466656:S=_6gGEKtuTgP..."
"path"      "/"
"domain"    ".google.com"
"expires"   T{ timestamp f 2010 4 29 10 57 36 ~duration~ }
"max-age"   f
"http-only" f

Tue, 29 Apr 2008 03:04:00

Doug Coleman: Word renaming (part 2)

Here are the word names that have changed:

• find* -> find-from
• find-last* -> find-last-from
• index* -> index-from
• last-index* -> last-index-from
• subset -> filter

• 1 tail -> rest
• 1 tail-slice -> rest-slice
• swap compose -> prepose

• reverse stack effect of assoc-diff, diff
• before? after? before=? after=? are now generic
• min, max can compare more objects than before, such as timestamps
  
• between? can compare more objects
  
• <=> returns symbols
  

Mon, 28 Apr 2008 10:49:00

Slava Pestov: Performance improvements

Over the last three days I spent some time improving Factor's compiler. I made the following improvements:

• Partial dispatch is performed on integer arithmetic operations. Previously, Factor's compiler would convert generic arithmetic to machine arithmetic when it knew the exact types involved; so if you had two floats on the stack, + would become float+, and if you had two fixnums it would become fixnum+ or fixnum+fast, depending on whether interval inference determined if the overflow check was needed or not. While this worked well in many cases there were a lot of instances where the compiler could only infer you were dealing with integers, but not fixnums in particular; either because interval inference was not smart enough, or because the values really could be out of bounds for a fixnum. Now, if it knows that both inputs are integers, it compiles a call to a special word which still performs a dispatch, but with only two possibilities. This is a win, because a conditional is faster than a jump table as used in the generic +. It is an even bigger win if one of the inputs is known to be a fixnum, because then the two jump table dispatches are replaced by a single conditional.
• Improved overflow check elimination. First, there is an enabling optimization. Suppose we have a positive integer on the stack. Then, the following two are equivalent:
  

  4096 mod
  4095 bitand

  
  The optimizer now recognizes the case where mod is applied with a power of two to a positive integer, and converts it to a bitwise and. For the rem word an even more general optimization is possible; we only have to assume the first input is an integer and the second is a power of two.
  
  While on a modern CPU, this is not a big in itself for mod (it is for rem, which is more expensive), it does enable the following optimization. Note that the following two expressions are equivalent:
  

  4095 bitand
  16777215 bitand 4095 bitand

  
  That is, if you mask off the first n bits, then the first m bits, and m<n, you get the same result as masking off the first m bits. This might seem trivial and useless and first, but then you realize that a truncating conversion of a positive bignum to a fixnum is simply masking off bits! So the following two are equivalent:
  

  4095 bitand
  >fixnum 4095 bitand

  
  But of course, both inputs to the latter bitand are fixnums now, and can be converted to:
  

  4095 bitand
  >fixnum 4095 fixnum-bitand

  
  It gets even better. Consider the following piece of code from project-euler.150:
  

  : next ( t -- new-t s )
      615949 * 797807 + 20 2^ rem dup 19 2^ - ;

  
  Constant folding gives us:
  

  : next ( t -- new-t s )
      615949 * 797807 + 1048576 rem dup 524288 - ;

  
  The above optimization, together with an overflow removal on the -, gives us:
  

  : next ( t -- new-t s )
      15949 * 797807 + >fixnum 1048575 fixnum-bitand dup 524288 fixnum-fast ;

  
  There is an existing optimization takes advantage of these identities:
  

  * >fixnum == [ >fixnum ] bi@ fixnum*fast
  + >fixnum == [ >fixnum ] bi@ fixnum+fast

  
  By applying the above, the compiler converts this code to:
  

  : next ( t -- new-t s )
      >fixnum 15949 fixnum*fast 797807 fixnum+fast 1048575 fixnum-bitand dup 524288 fixnum-fast ;

  
  All generic arithmetic and overflow checks have been removed, because of a single rem in the middle of the calculation!
  
  In project-euler.150, this word was actually used inside a loop, where it was iteratively applied to a starting generator value. With the new modular arithmetic optimization, Factor's existing interval inference code managed to infer the result of the word is always in the interval (-2^20,2^20), and since the initial value is 0, even the call to >fixnum was optimized away.
• I improved Factor's type inference algorithm to better deal with local recursive code blocks. While type inference worked okay with loops, it didn't fare so well with binary recursive functions because it wasn't able to obtain any information about return values of the recursive calls. Everybody's favorite binary recursive benchmark, fibonacci, was one example of this situation. Solving this required a bit of thought.
  
  Previously, type inference for recursive functions was done in a pretty ad-hoc manner. Factor's type inference is only used for optimization so it is okay if it is conservative. It worked pretty well, however today I decided to add better support for recursion, and I also found a bug where it would infer invalid types, so I decided to redo it a little.
  
  Type inference of recursive functions is now an iterative process, where you begin by assuming the recursive calls take the top type as inputs and the bottom type as outputs, then you infer the type of the body under these assumptions, then apply the resulting types to the recursive calls, then infer again, and so on, until a fixed point is reached. There are smarter ways of doing this with other type systems however in Factor, the type functions of some words are pretty complex. For example, the output type of + depends on not only the types of its inputs, but the interval ranges they lie in, so I'm not sure if there's any other solution.
  
  With this out of the way, there is one major remaining limitation in Factor's type inference, and that is it only works within words. It does not attempt to infer types across word boundaries. In practice this means many optimizations only kick in if a lot of words are inlined, which is not practical in some cases due to code size explosion. My next project in this area is to cache type signatures for words and use this information when inferring types of callers.
• I improved performance of inline object allocation. In the VM, the structure holding the allocation pointer is now stored directly in a global variable, instead of a pointer to it being stored in the global variable. This is one less indirection for inline allocators. Another improvement is that the heap exhaustion check is done in the allocator itself, so a call into the VM is avoided if the heap is not full. This saves a subroutine call in the common case of course, but also some saving and restoring of registers.

planets :: Ptr Double
planets = unsafePerformIO $ mallocBytes (7 * nbodies * 8) -- sizeOf double = 8

Sat, 19 Apr 2008 04:56:00

Slava Pestov: My top 8 shell commands

I wrote a short Factor script to check my bash history and tally up the most frequently occurring commands.

    git
    ./factor
    bf
    cdf
    ls
    cd
    fc
    push

• cdf is aliased to cd ~/factor
• bf is aliased to ./factor -i=boot.x86.32.image
• push is aliased to git push origin master
• fc is alised to ssh factorcode.org

Sat, 19 Apr 2008 03:52:00

Doug Coleman: Word renaming

Several words have been renamed and moved around to make Factor more consistent:

• new -> new-sequence
• construct-empty -> new
• construct-boa -> boa
• diff -> assoc-diff
• union -> assoc-union
• intersect -> assoc-intersect
• seq-diff -> diff
• seq-intersect -> intersect

Mon, 14 Apr 2008 12:25:00

Doug Coleman: Adding a new primitive

I added two primitives to the Factor VM to allow setting and unsetting of environment variables. It's not that hard to do, but you have to edit several C files in the VM and a couple .factor files in the core.  Really they should not be primitives, so eventually they will be moved into the core.

The primitives that I added are defined as follows:

IN: system
PRIMITIVE: set-os-env ( value key -- )
PRIMITIVE: unset-os-env ( key -- )

DEFINE_PRIMITIVE(set_os_env)
{
 F_CHAR *key = unbox_u16_string();
 REGISTER_C_STRING(key);
 F_CHAR *value = unbox_u16_string();
 UNREGISTER_C_STRING(key);
 if(!SetEnvironmentVariable(key, value))
     general_error(ERROR_IO, tag_object(get_error_message()), F, NULL);
}

F_FASTCALL primitive_set_os_env_impl(void);

F_FASTCALL void primitive_set_os_env(CELL word, F_STACK_FRAME *callstack_top) {
    save_callstack_top(callstack_top);
    primitive_set_os_env_impl();
}
INLINE void primitive_set_os_env_impl(void)

\ set-os-env { string string } { } <effect> set-primitive-effect

Sun, 13 Apr 2008 14:20:00

Slava Pestov: Multi-touch gestures in the Factor UI

Recently I acquired a MacBook Pro. The new models come with a multi-touch keypad and I've found it extremely useful in Safari to be able to go back, go forward and zoom with the mouse. However, I missed the ability to do this in other applications, especially the Factor UI. The Factor UI already supports vertical and horizontal scrolling gestures, and I wanted to be able to use the other gestures as well.

Apparently, Apple's official stance is that no multitouch API will be made public until 10.6. I was slightly discouraged by this but some more Googling turned up a blog post by Elliott Harris detailing the undocumented API for receiving these events.

While normally I shy away from relying on undocumented functionality in this case the API is dead-simple and it is almost an oversight on Apple's part not to document it. And if they break it, well, it will be easy to update Factor too.

Here are the changes I had to make. First, I added some new UI gestures to extra/ui/gestures/gestures.factor; these are cross-platform and theoretically the Windows and X11 UI backends could produce them too, perhaps as a result of button presses on those "Internet" keyboards:

TUPLE: left-action ;        C: <left-action> left-action
TUPLE: right-action ;       C: <right-action> right-action
TUPLE: up-action ;          C: <up-action> up-action
TUPLE: down-action ;        C: <down-action> down-action

TUPLE: zoom-in-action ;  C: <zoom-in-action> zoom-in-action
TUPLE: zoom-out-action ; C: <zoom-out-action> zoom-out-action

{ "magnifyWithEvent:" "void" { "id" "SEL" "id" }
    [
        nip
        dup -> deltaZ sgn {
            {  1 [ T{ zoom-in-action } send-action$ ] }
            { -1 [ T{ zoom-out-action } send-action$ ] }
            {  0 [ 2drop ] }
        } case
    ]
}

{ "swipeWithEvent:" "void" { "id" "SEL" "id" }
    [
        nip
        dup -> deltaX sgn {
            {  1 [ T{ left-action } send-action$ ] }
            { -1 [ T{ right-action } send-action$ ] }
            {  0
                [
                    dup -> deltaY sgn {
                        {  1 [ T{ up-action } send-action$ ] }
                        { -1 [ T{ down-action } send-action$ ] }
                        {  0 [ 2drop ] }
                    } case
                ]
            }
        } case
    ]
}

browser-gadget "multi-touch" f {
    { T{ left-action } com-back }
    { T{ right-action } com-forward }
} define-command-map

inspector-gadget "multi-touch" f {
    { T{ left-action } &back }
} define-command-map

workspace "multi-touch" f {
    { T{ zoom-out-action } com-listener }
    { T{ up-action } refresh-all }
} define-command-map

• In the browser tool, swipe left/right navigate the help history.
• In the inspector, swipe left goes back.
• In any tool, a pinch (zoom out) closes the current tool, leaving only the listener visible. A swipe up reloads any changed source files (I'm not sure if I like this yet).

Fri, 11 Apr 2008 23:34:00

Slava Pestov: Improvements to io.monitors; faster refresh-all

Factor's io.monitors library previously supported Mac OS X, Windows and Linux. Now it also supports BSD, but in a much more restricted fashion than the other platforms. Basically you cannot monitor directories, just individual files. This is because kqueue() only provides very limited functionality in this regard. However, having something is better than nothing, and the functionality provided on BSDs is still useful for monitoring log files and such.

On Linux, inotify doesn't directly support monitoring recursive directory hierarchies so Factor's monitors didn't support recursive monitoring, but a mailing list post by Robert Love discusses how to solve this issue in user-space. I used his solution to implement recursive monitors on Linux.

Another oddity relating to inotify is that if you add the same directory twice to the same inotify, you get the same watch ID both times, and events are only reported once. This means that the previous implementation where there was one global inotify instance shared by all monitors wasn't really as general as one would hope, because you couldn't run two programs that monitor overlapping portions of the file system. I thought of several possible fixes but in the end just changed the monitors API to accommodate this case. All monitor operations must now be wrapped in a with-monitors combinator. On Linux, it creates an inotify instance and stores it in a dynamically-scoped variable, so that subsequent calls to <monitor use this inotify. Independent inotifies in different threads don't interact at all. On Mac OS X, BSD and WIndows, with-monitors just calls the quotation without doing any special setup.

Another issue I fixed was that on Mac OS X, monitors would only work when used from the UI because no run loop was running otherwise. I made a run loop run all of the time and this allows monitors to work in the terminal listener.

Now that monitors are working better, I was able to use them to make refresh-all. This word finds all changed source files in the vocabulary roots and reloads them. It does this by comparing cached CRC32 checksums with the actual checksum of the file. Previously it would also compare modification times, but I took that code out because filesystem meta-data queries got moved out of the VM and into the native I/O code, which isn't available during bootstrap. A side-effect of this is that refresh-all became much slower, because it had to read all files. Using monitors I was able to make this faster than it has ever been. A thread waiting on a monitor is started on startup. Then, the source tree only has to be checksummed in its entirety the first time refresh-all is used in a session. Subsequently, only files for which the monitor reported changes have to be scanned. So refresh-all runs instantly if there are no changes, and so on.

Fri, 11 Apr 2008 13:19:00

Slava Pestov: The golden rule of writing comments

This is something I've wanted to say for a while, and I think many (most?) programmers don't realize it:

Never comment out code.

Comments are for natural-language descriptions of code, or pseudocode maybe.

If you comment out some code, then the parser isn't checking the syntax, the compiler isn't checking semantics, and the unit tests are not unit testing it.

So the code may as well not work. Why have non-working code in your program, especially if it's not called anywhere?

But perhaps the code is there so that you can see the what the program used to do. In that case, just fire up your favorite graphical GIT/SVN/P4/whatever frontend and check out an older revision.

Tue, 8 Apr 2008 20:36:00

Slava Pestov: Multi-methods and hooks

For a while now Factor has had 'hooks', which are generic words dispatching on a dynamically scoped variable. Hooks can be used with variables which are essentially global: the current OS, current CPU, UI backend, etc -- or variables which are truly context-specific, such as the current database connection.

I added support for hooks to the extra/multi-methods library, which is going in the core soon. While doing this I was able to significantly generalize the concept. Suppose we want to define a piece of functionality which depends on both the operating system and processor type.

We can begin with defining an ordinary generic word:

GENERIC: cache-size ( -- l1 l2 )

METHOD: cache-size { { os linux } } ... read something from /proc ... ;

METHOD: cache-size { { os macosx } { cpu ppc } } ... ;

METHOD: cache-size { { os macosx } { cpu x86.32 } } ... ;

METHOD: cache-size { { os macosx } { cpu x86.64 } } ... ;

METHOD: cache-size { { cpu arm } } ... ;

Tue, 8 Apr 2008 20:14:00

Phil Dawes: Digging into Factor’s compiler

I wrote this post partly as an advocacy piece and partly to put down a bunch of things I’ve learnt about the factor compiler over the last few weeks. I should point out that I’m no expert in this area and so there are probably inaccuracies and omissions - hopefully Slava or one of the factor gurus will point them out. With that in mind, check this out!:

Factor has an optimising compiler which generates machine code as you type code into the REPL. If you have gdb on your system you can see this in action by firing up factor and using the tools.disassembler vocab:

( scratchpad ) : hello "hello" print ;           ! defines the word hello
( scratchpad ) USING: tools.disassembler ;
( scratchpad ) \ hello disassemble

Using host libthread_db library “/lib/tls/i686/cmov/libthread_db.so.1″.
[Thread debugging using libthread_db enabled]
[New Thread -1213614400 (LWP 25688)]
0xffffe410 in __kernel_vsyscall ()
Dump of assembler code from 0xb0f694b0 to 0xb0f694c7:
0xb0f694b0: mov    $0xb0f694b0,%ecx
0xb0f694b5: mov    0xb0f694e4,%ebx
0xb0f694bb: mov    %ebx,0×4(%esi)
0xb0f694be: add    $0×4,%esi
0xb0f694c1: jmp    0xb123e7d0
…
End of assembler dump.

This is very cool in itself, but for me the real beauty of the factor compiler is the very modular design, composed of small pieces that you can pull apart and tinker with in isolation. This makes the compiler accessible to people both as a learning tool and for those wanting to generate highly optimized code for tight loops.

The three stages of the compiler are

1. Parsing the code and generating a ‘dataflow’ abstract syntax tree. (Also called ‘IR’ - intermediate representation)
2. Optimizing the dataflow tree
3. Generating machine code from the dataflow tree

I’ll dig into each of these steps in order:

Stage 1: Parsing factor code to dataflow IR

The first step parses factor code into a dataflow datastructure. You can run and inspect the results of this yourself using the dataflow word:

USE: inference
[ "hello" print ] dataflow pprint

=> T{
    #push
    T{
        node
        f
        f
        f
        V{ T{ value f “hello” 673850 f } }
        f
        f
        f
        f
        f
        f
        T{
            #call
            T{
                node
                f
                print
                V{ T{ value f “hello” 673850 f } }
                V{ }
                f
                f
                f
                f
                f
                f
                T{
                    #return
                    T{ node f f V{ } f f f f f f f f f }
                }
                f
            }
        }
        f
    }
}

Obviously inspecting this datastructure manually is pretty cumbersome, so fortunately there’s some dataflow inspection functionality in the ‘optimizer.debugger’ vocab. The dataflow>quot word renders the dataflow structure back into quotations (code blocks) that you can print and inspect. I use it here to define some words for dataflow pretty-printing:

USE: optimizer.debugger
: print-dataflow f dataflow>quot pprint nl ;
: print-annotated-dataflow t dataflow>quot pprint nl ;

So now we can turn quotations into dataflow graphs and back again:

[ "hello" print ] dataflow print-dataflow
=> [ “hello” print ]

(N.B. there are already words in the optimizer.debugger vocab for displaying optimized dataflows, but for this post I wanted to be able to print dataflows prior to optimisation)

This also works for pre-defined words using ‘word-dataflow’ :

: print-hello "hello" print ;
USE: generator
\ print-hello word-dataflow print-dataflow
=> [ “hello” print ]

In most cases the output quotation will be the same as the input quotation, however there are a couple of expansions that happen at this stage. The first is that words marked ‘inline’ are inlined directly into the dataflow:

: inlinedword "this" "is" "an" "inlined" "word" ; inline
[ inlinedword ] dataflow print-dataflow
=> [ “this” “is” “an” “inlined” “word” ]

Also any compiler-transforms (macros) are evaluated at this stage.

USE shuffle
[ 1 2 2 ndup ] dataflow print-dataflow      ! ndup is a macro
=> [ 1 2 2 drop 2 drop >r dup r> swap 2 drop >r dup r> swap ]

Stage 2: Dataflow Optimisation

Here’s where the fun starts. You can get a feel for how this stage works by looking at ‘optimizer.factor’. Here it is in its entirety:

! Copyright (C) 2006, 2008 Slava Pestov.
! See http://factorcode.org/license.txt for BSD license.
USING: kernel namespaces optimizer.backend optimizer.def-use
optimizer.known-words optimizer.math optimizer.control
optimizer.inlining inference.class ;
IN: optimizer

: optimize-1 ( node -- newnode ? )
    [
        H{ } clone class-substitutions set
        H{ } clone literal-substitutions set
        H{ } clone value-substitutions set
        dup compute-def-use
        kill-values
        dup detect-loops
        dup infer-classes
        optimizer-changed off
        optimize-nodes
        optimizer-changed get
    ] with-scope ;

: optimize ( node -- newnode )
    optimize-1 [ optimize ] when ;

‘optimize’ iteratively calls ‘optimize-1′ until nothing changes in the output graph - i.e. that it has reached a fixed point and no more optimizations can be performed. If you dig into the words used by optimize-1 (try executing them individually and inspecting the dataflow result) you’ll find that optimize-1 performs a number of inferences and optimizations:

• It tracks the types (classes) of stack elements created within the code block
• It inlines specific generic word implementations (methods) when it can deduce the class instance on the stack
• It prunes unused literals and flushable words. (this is actually more useful than it sounds, since other optimisations can generate unused code)
• It performs branch analysis, marking tail calls in loops and pruning branches that can’t be executed
• It evaluates ‘foldable’ words at compile time if the values of arguments are known
• It executes any custom inference code attached to words, allowing words to evaluate their results at compile time if inputs are known

Examples:

evaluating foldable words at compile time

‘+’ is a foldable word (see help for ‘+’), so the optimizer evaluates it at compile time if the values of both arguments are known. Here’s the dataflow before and after optimization:

[ 2 3 + ] dataflow print-dataflow            ! before optimization
=> [ 2 3 + ]

[ 2 3 + ] dataflow optimize print-dataflow   ! after optimization
=> [ 5 ]

type inference and inlining generic word implementations

To illustrate this we first create two tuples (classes) with constructors, and a generic word

TUPLE: classa ;
C: <classa> classa
TUPLE: classb ;
C: <classb> classb 

GENERIC: dosomething ( obj -- val )

Now we create an implementation of the generic word specialised for each class:

M: classa dosomething drop "something for class a" ;
M: classb dosomething drop "something for class b" ;

Finally, some code which calls ‘dosomething’ with an instance of ‘classa’ on the stack, before and after optimization:

[ <classa> dosomething ] dataflow print-dataflow            ! before optimization
=> [  classa drop  classa 2 <tuple -boa> dosomething ]

[ <classa> dosomething ] dataflow optimize print-dataflow    ! after optimization
=> [  classa 2 <tuple -boa> drop “something for class a” ]

It’s a little messy because of the inlined tuple creation, but you can see that prior to optimization ‘dosomething’ is a word call in the dataflow, and afterwards the optimizer has inlined the implementation of ‘dosomething’ specialized on ‘classa’. (if you look you can also see an example of pruning literals here, as the first dataflow has resulted in a superflous ‘\ classa drop’).

This is easier to see if I cheat a bit and use factor’s ‘declare’ word, which declares that elements on the top of the stack are instances of specific classes. So this quotation assumes that top stack element before it is called is of type ‘classa’:

[ { classa } declare dosomething ] dataflow optimize print-dataflow
=> [ drop “something for class a” ]

N.B. you wouldn’t normally use ‘declare’ in user code, but it could be really handy for optimizing performance sensitive tight loops where the results of an external word call are known to the programmer but not the compiler.

conditional folding

The compiler optimizes out conditional branches when it can deduce the outcome of the conditional at compile time:

[ 1 0 =  [ "do if true" ] [ "do if false" ] if ] dataflow optimize print-dataflow
=> [ “do if false” ]

1 isn’t equal to 0 so it optimizes this whole block into the contents of the false quotation.
This is a simple example, but it turns out to be really cool in performance sensitive code (e.g. tight loops) because you can use a generic library function whose behaviour depends on a conditional, specialize it with a hardcoded ‘f’ and the compiler will optimize the conditional branch right out of the resulting code. You get the elegance of the generic combinator with the speed of a hand coded loop.

Stage 3: Machine Code Generation

Code generation is implemented by the ‘generate’ word. This iterates through the nodes calling ‘generate-node’ on each.

: generate-nodes ( node -- )
    [ node@ generate-node ] iterate-nodes end-basic-block ;

: generate ( node word label -- )
    [
        init-generate-nodes
        [ generate-nodes ] with-node-iterator
    ] with-generator ;

‘generate-node’ is a generic word with specialized implementations for each type of dataflow node.

As described in this post from Slava’s excellent Factor blog there are a number of dataflow node types, the important ones being:

* #push - push literals on the data stack
* #shuffle - permute the elements of the data or call stack
* #call - call a word
* #label - an inlined recursive block (loop, etc)
* #if - conditional with two child nodes
* #dispatch - jump table with multiple nodes; jumps to the node indexed by a number on the data stack

The generate-node implementations invoke lower level words in the ‘architecture’ vocabulary, which in turn are generic words that write out small pieces of machine code specialized for each CPU architecture.

The machine code generation code is particularly cool and easy to follow because factor has an assembler DSL for each cpu architecture it supports. The assembler words match the commands and registers of the target cpu architecture and evaluate to their corresponding machine code.

You can even try this out in the REPL using ‘make’ to collect the results into an array. I’m on x86 so I load the cpu.x86.assembler vocabulary:

USE: cpu.x86.assembler

[ EAX 35 MOV ] { } make .   ! postfix assembler evaluates to machine code!

=> { 184 35 0 0 0 }

The assembler DSLs make code generation easy to follow because you can see the assembler in the generation code and then check it against the disassembled machine code using the ‘disassemble’ word we used at the start of the post. When following the code it helps to know which registers are used for what purpose. I found this information in assembler files in the factor VM source - I’m an x86 so for me the declares are in the ‘cpu-x86.32.S’ file:

#define ARG0 %eax
#define ARG1 %edx
#define XT_REG %ecx
#define STACK_REG %esp
#define DS_REG %esi
#define RETURN_REG %eax

#define CELL_SIZE 4

#define PUSH_NONVOLATILE 
	push %ebx ; 
	push %ebp

#define POP_NONVOLATILE 
	pop %ebp ; 
	pop %ebx

register CELL ds asm("esi");
register CELL rs asm("edi");

So lets check this against some generated code for a really basic word that just pops the number 42 on the stack:

: myfunc 42 ;
 myfunc disassemble
=>
Using host libthread_db library “/lib/tls/i686/cmov/libthread_db.so.1″.
[Thread debugging using libthread_db enabled]
[New Thread -1213696320 (LWP 32499)]
0xffffe410 in __kernel_vsyscall ()
Dump of assembler code from 0xb136b230 to 0xb136b247:
0xb136b230: mov    $0xb136b230,%ecx
0xb136b235: mov    $0×150,%ebx
0xb136b23a: mov    %ebx,0×4(%esi)
0xb136b23d: add    $0×4,%esi
0xb136b240: ret 

The first assembler line puts the address of the word into the XT_REG, which is %ecx. For some reason the start of each function puts it’s address into this register - not quite sure why.
The second line puts the number 42 into the ebx register. Note that factor uses the first 3 bits of a value (’cell’) to store its type (called a tag - see layouts.h). In this case it’s a fixnum which is 000. 42 shifted left 3 bits is 336, which in hex is 0×150.
The third line puts the number onto the stack, and the forth updates the stack pointer to point to the new top of the stack.

code generation optimizations

Factor has another couple of tricks up its sleeve during the code generation stages:

optimizing shuffle words

The first is that stack shuffle words (e.g. dup, swap, tuck etc..) don’t get translated into machine code. Instead the compiler has a compile time ‘phantom stack’ which records the positions of items in the stack. When it generates the machine code values are accessed from the stack out of order (the runtime stack is after all a random access piece of memory). This makes stack shuffling words and the retain stack effectively ‘free’ within a code block. A #merge node in the dataflow signifies a code boundary (usually before a subroutine call) which causes the compiler to output instructions which synchronise the physical runtime stack with its phantom stack.

word intrinsics

The second trick is word ‘intrinsics’. Word intrinsics are essentially blocks of open-coded assembler that are output in place of a subroutine call. They are associated with the word via a ‘word-property’, which is a nifty feature of factor that allows meta information to be attached to each word. For example the ‘fixnum+fast’ word has intrinsics which you can see using ‘word-prop’:

 fixnum+fast "intrinsics" word-prop pprint
=>
{
    {
        [ “x” operand “y” operand ADD ]
        H{
            { +output+ { “x” } }
            { +input+ { { f “x” } { [ small-tagged? ] “y” } } }
        }
    }
    {
        [ “x” operand “y” operand ADD ]
        H{
            { +output+ { “x” } }
            { +input+ { { f “x” } { f “y” } } }
        }
    }
}

This tells the compiler to inline the x86 ADD instruction instead of making a subroutine call to the implementation of fixnum+fast. You can add assembler intrinsics to existing words with ‘define-intrinsics’; Here’s a description from the help for the define-intrinsics word:

Defines a set of assembly intrinsics for the word. When a call to the word is being compiled, each intrinsic is tested in turn; the first applicable one will be called to generate machine code. If no suitable intrinsic is found, a simple call to the word is compiled instead.

What I particularly like about this feature is that it neatly provides the ability to specialize a highly optimized implementation for a particular hardware set, and then fall back gracefully on other architectures.

–

That concludes my ad-hoc tour of the factor compiler. I’ve skipped over a number of things and no doubt there are bits I haven’t discovered yet and some inaccuracies, but I hope I’ve supplied enough information to spark interest in this excellent compiler.

As I mentioned in a previous post I got interested in factor as a direct result of tinkering with jonesforth, which takes you through the entire forth bootstrap process starting with raw assembly. I’ve been delighted to find that factor retains a lot of the ‘right-down-to-the-metal’ accessibility of its low level cousin.

Tue, 8 Apr 2008 08:27:16