source: buchla-68k/orig/GEMDOS/DIAMELST.S@ cbc2fcf

Last change on this file since cbc2fcf was 3ae31e9, checked in by Thomas Lopatic <thomas@…>, 7 years ago

Imported original source code.

  • Property mode set to 100755
File size: 24.6 KB
Line 
1******************************************************************************
2*
3* diamelst.s -- startup code for the C runtime library, aesbind, vdibind
4* Version 3 -- 1988-05-03 -- D.N. Lynx Crowe
5*
6* "It's not a diamond, it's a Diamel!", and this isn't Gem, either...
7* it just looks a lot like it.
8*
9* Adds __cmdsz and __cmdln for access to raw command tail
10*
11* IMPORTANT: SEE THE DESCRIPTION OF THE "STACK" VARIABLE, BELOW.
12*
13* This is the startup code for any application running on the Atari ST.
14* This includes gemlib, vdi, and the aes bindings.
15*
16* Look carefully at the comments below; they will determine the nature
17* of this startup code (stack size, AES & VDI usage, etc.).
18*
19* This must be the first object file in a LINK command. When the
20* operating system gives it control, our process has ALL of memory
21* allocated to it, and our stack pointer is at the top.
22* This code (conditionally) gives some of that memory back
23* to the operating system, places its stack pointer at the top
24* of the memory it still owns, sets up some global variables,
25* and calls __main, the run-time library startup routine (which
26* parses the command line into argc/argv, opens stdin and stdout,
27* etc., before calling the programmer's _main).
28*
29* This object file also includes __exit, which is the procedure the
30* runtime library calls to exit back to the operating system.
31* As a new feature with this release, the argument passed to __exit
32* is NOT ignored; it is passed to the operating system using the Pterm
33* function call, which returns it as the value of the Pexec() call
34* which invoked this process.
35*
36******************************************************************************
37
38STACK=4 * CHANGE THIS VARIABLE TO CHOOSE A MEMORY MODEL
39
40MINSTACK=4096 * minimum stack+heap size. (used if __STKSIZ undefined)
41
42* NOTE: STACK was =-8192
43
44******************************************************************************
45*
46* STACK variable summary:
47*
48* -1=keep all available memory
49* 0=keep MINSTACK bytes
50* 1=keep 1/4 of free memory
51* 2=keep 2/4
52* 3=keep 3/4
53* 4=use _STKSIZ: keep (if >0) or give up (if <0) _STKSIZ bytes.
54* other=keep that many bytes (positive) or give back that many (negative)
55*
56******************************************************************************
57*
58* CONFIGURING THIS STARTUP FILE
59*
60* There are several memory models which this startup file will
61* assemble for, selected by the assembly variable STACK.
62*
63* When your process gets control, it owns its basepage, its text
64* (program) segment, its data segment, its bss segment (uninitialized
65* data), and all the "free memory" from there to the top of the TPA.
66* A process can choose to keep all that free memory for its stack
67* (used by function calls and local variables) and heap (used by
68* malloc()), or it can return some or all of that space to the
69* operating system.
70*
71* The memory between the top of your bss segment and your stack pointer
72* is used both for a heap and for the stack. The line between heap
73* and stack is called the "break". When malloc() uses up all the
74* memory below the break, it calls _brk() (in this file) to move the
75* break up. If the break gets too close to the stack, _brk() returns
76* an error code, and malloc() will return NULL because it couldn't
77* satisfy the request. If the stack actually overflows the break,
78* _brk() prints an error message and exits, returning 1 to its parent.
79*
80* If you are using the AES or VDI, you must return at least a little of
81* the free memory to the operating system, because they need it.
82* About 8K should be enough. The AES uses this memory for blt buffers,
83* and the VDI uses it for virtual workstation data.
84* Also, if your program uses the Pexec() call, you will need to return
85* some space to make room for the child process.
86*
87* It is usually a good idea to keep only as much memory as you will
88* use, because some programs depend on processes returning some
89* memory to the operating system.
90*
91*************************************************************************
92*
93* Here are the memory models you can set up with the STACK variable:
94*
95* STACK
96* value Meaning
97* ------ ---------------------------------------------------------
98* -1 Keep all the memory for this process. Return NONE of it
99* to the operating system. This model gives you the most
100* memory.
101*
102* WARNING: IF YOU REQUEST ALL OF MEMORY (with STACK = -1),
103* YOU MUST NOT USE THE AES, THE VDI, OR THE BIOS PEXEC()
104* FUNCTION. PEXEC WILL RETURN A CORRECT ERROR CODE (-39,
105* ENSMEM), BUT IT WILL ALSO BREAK THE MEMORY MANAGEMENT SYSTEM.
106*
107* 0 Return all but a minimal amount (MINSTACK) of the free
108* space to the operating system. This is a good idea if
109* you know you won't be using malloc() much, or if you
110* will be using Pexec() and your program doesn't need much
111* stack space. Remember, though, that some library functions,
112* especially fopen(), use malloc() and will use your heap
113* space.
114*
115* 1 Keep 1/4 of the free space. This is a good model if
116* you will be using malloc() a lot, but also want to use
117* Pexec() to spawn subprocesses.
118*
119* 2 Keep 2/4 (1/2) of the free space. This is good if you
120* use malloc() a lot, but don't want to be too much of a
121* memory hog.
122*
123* 3 Keep 3/4 of the free space. This is a good choice for
124* programs which use the AES or VDI, because it gives you plenty
125* of room for using malloc(), but leaves enough for the
126* AES and VDI to allocate their buffers, too.
127*
128* 4 This is a special value which means "Keep the number of
129* bytes in the LONG global variable __STKSIZ." You must declare
130* a variable in your program called "_STKSIZ" and initialize
131* it to the number of bytes you want for your stack and heap.
132* If __STKSIZ is negative, it means "Keep all BUT the number
133* of bytes in __STKSIZ." As a safeguard, if __STKSIZ is
134* undefined, you will get MINSTACK bytes of stack/heap.
135*
136* An example using __STKSIZ in C is:
137*
138* /* outside all function blocks */
139*
140* unsigned long _STKSIZ = 32767; /* 32K stack+heap */
141* or
142* unsigned long _STKSIZ = -8192; /* keep all but 8K */
143*
144* Note that in C, all variables get an underscore stuck on
145* the front, so you just use one underscore in your program.
146* Note also that it has to be all upper-case.
147*
148* Any other POSITIVE value of STACK will be taken as the number of
149* bytes you want to KEEP for your stack and heap.
150*
151* Any other NEGATIVE value of STACK will be taken as the number of
152* bytes you want to give back to the operating system.
153*
154* Note that if you give back less than 512 bytes, you still shouldn't
155* use Pexec(), and if you give back less than (about) 4K, you shouldn't
156* use the AES or VDI.
157*
158* In all cases, a minimum stack size is enforced. This minimum is
159* set by the variable MINSTACK in this assembly file. This value
160* should be at least 256 bytes, but should be more like 4K. If
161* the stack size from the STACK model you choose or the _STKSIZ
162* variable in your program is less than MINSTACK, you'll get
163* MINSTACK bytes. If there aren't MINSTACK bytes free past the end
164* of your BSS, the program will abort with an error message.
165*
166*************************************************************************
167
168FUDGE=512 * minimum space to leave ABOVE our stack
169
170* BASEPAGE ADDRESSES:
171p_lowtpa=$0 * Low TPA address (basepage address)
172p_hitpa=$4 * High TPA address (and initial stack pointer)
173p_tbase=$8 * ptr to Code segment start
174p_tlen=$c * Code segment length
175p_dbase=$10 * ptr to Data segment start
176p_dlen=$14 * Data segment length
177p_bbase=$18 * ptr to Bss segment start
178p_blen=$1c * Bss segment length
179p_dta=$20 * ptr to process's initial DTA
180p_parent=$24 * ptr to process's parent's basepage
181p_reserved=$28 * reserved pointer
182p_env=$2c * ptr to environment string for process
183p_cmdlin=$80 * Command line image
184
185*
186* CONTROL VARIABLES (used in stack computations)
187*
188* GOTSTACK: a boolean which is set TRUE if STACK in [-1..4], meaning "don't
189* assemble the code keeping or returning STACK bytes."
190*
191* DOSHRINK: a boolean which is set FALSE if STACK is -1, meaning "don't
192* shrink any memory back to the operating system."
193*
194gotstack .equ 0 * set to 1 if STACK in [-1..4]
195doshrink .equ 1 * default is 1; set to 0 if STACK = -1
196
197* GEMDOS functions:
198cconws=$09 * Cconws(string): write to console
199mshrink=$4a * Mshrink(newsize): shrink a block to a new size
200pterm=$4c * Pterm(code): exit, return code to parent
201
202.globl __start
203.globl __main
204.globl __exit
205.globl _brk
206.globl __break
207.globl ___cpmrv
208.globl __base
209.globl __sovf
210.globl _crystal
211.globl _ctrl_cnts
212
213.globl __cmdsz * Command line length in __cmdln
214.globl __cmdln * Command line image before __main gets it
215
216 .text
217*
218* Must be first object file in link statement
219*
220
221__start:
222 move.l sp,a1 * save our initial sp (used by ABORT)
223 move.l 4(sp),a0 * a0 = basepage address
224 move.l a0,__base * base = a0
225 move.l p_bbase(a0),d0 * d0 = bss seg start
226 add.l p_blen(a0),d0 * d0 += bss length (d0 now = start of heap)
227 move.l d0,__break * __break = first byte of heap
228
229*************************************************************************
230* *
231* Compute stack size based on MINSTACK, p_hitpa(a0), STACK, *
232* and __STKSIZ, as appropriate. Place the SP where you want *
233* your stack to be. Note that a0 == __base, d0 == __break *
234* *
235* At most one of the STACK code fragments will be assembled. *
236* If none of them are, then `gotstack' will still be 0, and *
237* the final block, saving STACK bytes, is used. Finally, if *
238* STACK wasn't -1 (meaning don't shrink at all), DOSHRINK *
239* gets control. See doshrink for more. *
240* *
241*************************************************************************
242
243*************************************************************************
244* STACK = -1: keep all of memory *
245*************************************************************************
246
247 .ifeq STACK+1 * if (STACK == -1)
248gotstack .equ 1
249doshrink .equ 0 * this PREVENTS doshrink from assembling.
250 move.l p_hitpa(a0),sp * place stack at top of tpa.
251 move.l d0,d1 * check against MINSTACK
252 add.l #MINSTACK,d1 * d1 = __break + MINSTACK;
253 cmp.l sp,d1 * if (sp < __break + MINSTACK)
254 bhi abort * goto abort;
255 .endc * (this falls through to the __main call)
256
257*************************************************************************
258* STACK = 0: keep only MINSTACK bytes *
259*************************************************************************
260
261 .ifeq STACK
262gotstack .equ 1
263 move.l #MINSTACK,sp * sp = __break+MINSTACK;
264 add.l d0,sp
265 .endc * (this falls through to doshrink)
266
267*************************************************************************
268* STACK = 1: keep 1/4 of available memory *
269*************************************************************************
270
271 .ifeq STACK-1
272gotstack .equ 1 * /* keep 1/4 of available RAM */
273 move.l p_hitpa(a0),d1 * d1 = p_hitpa;
274 sub.l d0,d1 * d1 -= __break; /* d1 = free ram size */
275 lsr.l #2,d1 * d1 /= 4;
276 add.l d0,d1 * d1 += __break; /* d1 = new sp */
277 move.l d1,sp * sp = d1;
278 .endc * } (this falls through to doshrink)
279
280*************************************************************************
281* STACK = 2: keep 2/4 of available memory *
282*************************************************************************
283
284 .ifeq STACK-2 * if (STACK == 2) { /* keep 1/2 */
285gotstack .equ 1
286 move.l p_hitpa(a0),d1 * d1 = p_hitpa;
287 sub.l d0,d1 * d1 -= __break; /* d1 = free ram size */
288 lsr.l #1,d1 * d1 /= 2;
289 add.l d0,d1 * d1 += __break; /* d1 = new sp */
290 move.l d1,sp * sp = d1;
291 .endc * this falls through to doshrink
292
293*************************************************************************
294* STACK = 3: keep 3/4 of available memory *
295*************************************************************************
296
297 .ifeq STACK-3 * if (STACK == 3) { /* keep 3/4 */
298gotstack .equ 1
299 move.l p_hitpa(a0),d1 * d1 = p_hitpa;
300 sub.l d0,d1 * d1 -= __break; /* d1 = free ram size */
301 lsr.l #2,d1 * d1 /= 4;
302 move.l d1,d2 * d2 = d1
303 add.l d2,d1 * d1 += d2;
304 add.l d2,d1 * d1 += d2; /* now d1 = 3*(d1/4) */
305 add.l d0,d1 * d1 += __break; /* d1 = new sp */
306 move.l d1,sp * sp = d1;
307 .endc * this falls through to doshrink
308
309*************************************************************************
310* STACK = 4: keep or give up __STKSIZ bytes of memory. *
311*************************************************************************
312
313 .ifeq STACK-4 * if (STACK == 4) { /* keep __STKSIZ */
314 .globl __STKSIZ * global variable holding stack size
315gotstack .equ 1
316 move.l #__STKSIZ,a1 * Check to see if __STKSIZ was undefined.
317 beq keepmin * if it's zero, keep the minimum stack.
318*
319 move.l (a1),d1
320 bmi giveback * if (__STKSIZ < 0) goto giveback;
321*
322 add.l d0,d1 * d1 = __base+__STKSIZ; /* new sp */
323 bra gotd1
324
325keepmin: * __STKSIZ was undefined; keep minimum.
326 move.l #MINSTACK,d1
327 add.l d0,d1 * d1 = __base + MINSTACK;
328 bra gotd1 * goto gotd1;
329
330giveback:
331 add.l p_hitpa(a0),d1 * d1 += hitpa;
332
333gotd1: move.l d1,sp * gotd1: sp = d1;
334 .endc
335
336*************************************************************************
337* STACK is something else: keep (if STACK>0) or give *
338* back (if STACK<0) STACK bytes *
339*************************************************************************
340
341 .ifeq gotstack * it's a constant stack value (+ or -)
342
343 move.l #STACK,d1 * /* if neg, give back STACK bytes */
344 bmi giveback * if (STACK < 0) goto giveback;
345*
346 add.l d0,d1 * d1 = __STKSIZ + __base; /* new sp */
347 bra gotd1 * goto gotd1;
348
349giveback: * giveback:
350 add.l p_hitpa(a0),d1 * d1 += hitpa; /* d1 = new sp */
351gotd1: * gotd1:
352 move.l d1,sp * sp = d1;
353 .endc
354
355*************************************************************************
356* *
357* DOSHRINK: take SP as a requested stack pointer. Place it *
358* between (__break+MINSTACK) and (p_hitpa(a0)-FUDGE). If we can't, *
359* abort. Otherwise, we return the remaining memory back to the o.s. *
360* The reason we always shrink by at least FUDGE bytes is to work around *
361* a BUG in the XBIOS Malloc() routine: when there are fewer than 512 *
362* bytes in the largest free block, attempting a Pexec() breaks the *
363* memory management system. Since all models except -1 permit Pexec() *
364* calls, we have to make sure they don't break, even if the Pexec() *
365* fails. Thus, FUDGE must be at least 512. *
366* *
367*************************************************************************
368*
369* PSEUDOCODE:
370* doshrink(sp)
371* {
372* /* if too low, bump it up */
373* if (sp < (__break + MINSTACK))
374* sp = (__break + MINSTACK);
375*
376* /* if too high, bump it down */
377* if (sp > (hitpa - FUDGE)) {
378* sp = (hitpa - FUDGE);
379*
380* /* if now too low, there's not enough memory */
381* if (sp < (__break + MINSTACK))
382* goto abort;
383* }
384* Mshrink(0,__base,(sp - __base));
385* }
386*
387*************************************************************************
388
389 .ifne doshrink * assemble this only if STACK != -1
390 move.l d0,d1 * d1 = __break;
391 add.l #MINSTACK,d1 * d1 += MINSTACK;
392 cmp.l d1,sp * if ((__break+MINSTACK) < sp)
393 bhi minok * goto minok;
394 move.l d1,sp * else sp = (__break+MINSTACK)
395minok: * minok:
396 move.l p_hitpa(a0),d2 * d2 = hitpa;
397 sub.l #FUDGE,d2 * d2 -= FUDGE;
398 cmp.l d2,sp * if ((hitpa - FUDGE) > sp)
399 bcs maxok * goto maxok;
400* * else {
401 move.l d2,sp * sp = (hitpa - FUDGE);
402 cmp.l d1,d2 * if ((__break+MINSTACK) > (hitpa-FUDGE))
403 bcs abort * goto abort; /* BAD NEWS */
404* * }
405maxok:
406
407*************************************************************************
408* STACK LOCATION HAS BEEN DETERMINED. Return unused memory to the o.s. *
409*************************************************************************
410
411 move.l sp,d1 * d1 = sp;
412 and.l #-2,d1 * /* ensure d1 is even */
413 move.l d1,sp * sp = d1;
414 sub.l a0,d1 * d1 -= __base; /* d1 == size to keep */
415
416 move.l d1,-(sp) * push the size to keep
417 move.l a0,-(sp) * and start of this block (our basepage)
418 clr.w -(sp) * and a junk word
419 move #mshrink,-(sp) * and the function code
420 trap #1 * Mshrink(0,__base,(sp-base))
421 add.l #12,sp * clean the stack after ourselves
422 .endc
423
424*************************************************************************
425* *
426* Finally, the stack is set up. Now call _main(cmdline, length). *
427* *
428*************************************************************************
429
430 move.l __base,a0 * set up _main(cmdline,length)
431 lea.l p_cmdlin(a0),a2 * a2 now points to command line
432 move.b (a2)+,d0 * d0 = length; a2++;
433 ext.w d0 * extend byte count into d0.w
434 move.w d0,-(a7) * push length
435 move.l a2,-(a7) * Push commnd
436*
437 move.w d0,__cmdsz * Save length
438 lea.l __cmdln,a1 * Setup move to address
439 bra LynxL1 * Enter the loop
440*
441LynxL2: move.b (a2)+,(a1)+ * Move a byte
442*
443LynxL1: dbf d0,LynxL2 * Loop until they're moved
444*
445 clr.l a6 * Clear frame pointer
446 jsr __main * call main routine NEVER RETURNS
447
448***********************************************************************
449*
450* _exit(code) Terminate process, return code to the parent.
451*
452***********************************************************************
453
454__exit:
455 tst.l (a7)+ * drop return PC off the stack, leaving code
456 move.w #pterm,-(a7) * push function number
457 trap #1 * and trap.
458
459*
460* abort: used if the stack setup above fails. Restores the initial sp,
461* prints a message, and quits with the error ENSMEM.
462*
463abort: * print an abortive message and quit
464 move.l a1,sp * restore initial sp
465 pea.l abortmsg * push string address
466 move.w #cconws,-(a7) * and function code
467 trap #1 * and trap to print message
468 addq.l #6,a7 * clean off stack
469 move.w #-39,-(a7) * push error number -39: ENSMEM
470 jsr __exit * and exit with it.
471*
472* brk() -- set system break
473*
474_brk:
475 cmp.l __break,sp * compare current break with current stack
476 bcs __sovf * actual stack overflow!
477*
478 movea.l 4(sp),a0 * get new break
479 move.l a0,d0 * compare with stack, including 256-byte
480 adda.l #$100,a0 * chicken factor
481 cmpa.l a0,sp * if (sp < a0+256)
482 bcs badbrk * bad break;
483*
484 move.l d0,__break * OK break: save the break
485 clr.l d0 * Set OK return
486 rts * return
487
488badbrk:
489 move.l #-1,d0 * Load return reg
490 rts * Return
491*
492*
493.globl ___BDOS
494___BDOS:
495 link a6,#0 * link
496 move.w 8(sp),d0 * Load func code
497 move.l 10(sp),d1 * Load Paramter
498 trap #2 * Enter BDOS
499 cmpa.l __break,sp * Check for stack ovf
500 bcs __sovf * overflow! print msg and abort
501*
502 unlk a6 * no error; return
503 rts * Back to caller
504
505*
506* stack overflow! This external is called by salloc in gemlib as well as above
507*
508__sovf:
509 move.l #ovf,-(sp) * push message address
510 move.w #cconws,-(sp) * push fn code
511 trap #1 * Issue message
512
513 move.w #1,-(a7) * push return code (1)
514 move.w #pterm,d0 * push function code (Pterm)
515 trap #1 * call Pterm(1) (never returns)
516
517*
518* Block Fill function:
519*
520* blkfill(dest,char,cnt);
521*
522* BYTE *dest; * -> area to be filled
523* BYTE char; * = char to fill
524* WORD cnt; * = # bytes to fill
525*
526 .globl _blkfill
527_blkfill:
528 move.l 4(a7),a0 * -> Output area
529 move.w 8(a7),d1 * = output char
530 move.w 10(a7),d0 * = output count
531 ext.l d0 * make it long
532 subq.l #1,d0 * decrement
533 ble filldone * Done if le
534*
535fillit: move.b d1,(a0)+ * move a byte
536 dbra d0,fillit * Continue
537*
538filldone: clr.l d0 * always return 0
539 rts *
540
541*
542* Index function to find out if a particular character is in a string.
543*
544 .globl _index
545 .globl _strchr
546_index:
547_strchr:
548 move.l 4(a7),a0 * a0 -> String
549 move.w 8(a7),d0 * D0 = desired character
550*
551xindex: tst.b (a0) * EOS?
552 bne notend * No, continue to look
553*
554 clr.l d0 * Not found
555 rts * Quit
556*
557notend: cmp.b (a0)+,d0 * check for character
558 bne xindex *
559*
560 move.l a0,d0 * Found it
561 subq.l #1,d0 * set return pointer
562 rts
563
564*
565* For GEMAES calls from AESBIND.ARC or cryslib.o
566*
567_crystal:
568 move.l 4(a7),d1
569 move.w #200,d0
570 trap #2
571 rts
572
573*
574* Data area
575*
576 .data
577 .globl ___pname * Program Name
578 .globl ___tname * Terminal Name
579 .globl ___lname * List device name
580 .globl ___xeof * ^Z byte
581*
582ovf: .dc.b 'Stack Overflow',13,10,0 * Overflow message
583*
584___pname: .dc.b 'Diamel',0 * Program name
585___tname: .dc.b 'CON:',0 * Console name
586___lname: .dc.b 'LST:',0 * List device name
587___xeof: .dc.b $1a * Control-Z
588*
589abortmsg: .dc.b 'Cannot initialize stack',13,10,0 * abort message
590
591**********************************************************************
592*
593* BSS AREA
594**********************************************************************
595 .bss
596 .even
597__base: .ds.l 1 * -> Base Page
598__break: .ds.l 1 * Break location
599___cpmrv: .ds.w 1 * Last CP/M return val
600*
601__cmdsz: .ds.w 1 * Length of command line in __cmdln
602__cmdln: .ds.w 128 * Command line image before __main gets it
603*
604* control array for vdibind
605*
606 .data
607 .even
608_ctrl_cnts: * Application Manager
609 .dc.b 0, 1, 0 * func 010
610 .dc.b 2, 1, 1 * func 011
611 .dc.b 2, 1, 1 * func 012
612 .dc.b 0, 1, 1 * func 013
613 .dc.b 2, 1, 1 * func 014
614 .dc.b 1, 1, 1 * func 015
615 .dc.b 0, 0, 0 * func 016
616 .dc.b 0, 0, 0 * func 017
617 .dc.b 0, 0, 0 * func 008
618 .dc.b 0, 1, 0 * func 019
619* Event Manager
620 .dc.b 0, 1, 0 * func 020
621 .dc.b 3, 5, 0 * func 021
622 .dc.b 5, 5, 0 * func 022
623 .dc.b 0, 1, 1 * func 023
624 .dc.b 2, 1, 0 * func 024
625 .dc.b 16, 7, 1 * func 025
626 .dc.b 2, 1, 0 * func 026
627 .dc.b 0, 0, 0 * func 027
628 .dc.b 0, 0, 0 * func 028
629 .dc.b 0, 0, 0 * func 009
630* Menu Manager
631 .dc.b 1, 1, 1 * func 030
632 .dc.b 2, 1, 1 * func 031
633 .dc.b 2, 1, 1 * func 032
634 .dc.b 2, 1, 1 * func 033
635 .dc.b 1, 1, 2 * func 034
636 .dc.b 1, 1, 1 * func 005
637 .dc.b 0, 0, 0 * func 006
638 .dc.b 0, 0, 0 * func 007
639 .dc.b 0, 0, 0 * func 008
640 .dc.b 0, 0, 0 * func 009
641* Object Manager
642 .dc.b 2, 1, 1 * func 040
643 .dc.b 1, 1, 1 * func 041
644 .dc.b 6, 1, 1 * func 042
645 .dc.b 4, 1, 1 * func 043
646 .dc.b 1, 3, 1 * func 044
647 .dc.b 2, 1, 1 * func 045
648 .dc.b 4, 2, 1 * func 046
649 .dc.b 8, 1, 1 * func 047
650 .dc.b 0, 0, 0 * func 048
651 .dc.b 0, 0, 0 * func 049
652* Form Manager
653 .dc.b 1, 1, 1 * func 050
654 .dc.b 9, 1, 1 * func 051
655 .dc.b 1, 1, 1 * func 002
656 .dc.b 1, 1, 0 * func 003
657 .dc.b 0, 5, 1 * func 004
658 .dc.b 0, 0, 0 * func 005
659 .dc.b 0, 0, 0 * func 006
660 .dc.b 0, 0, 0 * func 007
661 .dc.b 0, 0, 0 * func 008
662 .dc.b 0, 0, 0 * func 009
663* Dialog Manager
664 .dc.b 0, 0, 0 * func 060
665 .dc.b 0, 0, 0 * func 061
666 .dc.b 0, 0, 0 * func 062
667 .dc.b 0, 0, 0 * func 003
668 .dc.b 0, 0, 0 * func 004
669 .dc.b 0, 0, 0 * func 005
670 .dc.b 0, 0, 0 * func 006
671 .dc.b 0, 0, 0 * func 007
672 .dc.b 0, 0, 0 * func 008
673 .dc.b 0, 0, 0 * func 009
674* Graphics Manager
675 .dc.b 4, 3, 0 * func 070
676 .dc.b 8, 3, 0 * func 071
677 .dc.b 6, 1, 0 * func 072
678 .dc.b 8, 1, 0 * func 073
679 .dc.b 8, 1, 0 * func 074
680 .dc.b 4, 1, 1 * func 075
681 .dc.b 3, 1, 1 * func 076
682 .dc.b 0, 5, 0 * func 077
683 .dc.b 1, 1, 1 * func 078
684 .dc.b 0, 5, 0 * func 009
685* Scrap Manager
686 .dc.b 0, 1, 1 * func 080
687 .dc.b 0, 1, 1 * func 081
688 .dc.b 0, 0, 0 * func 082
689 .dc.b 0, 0, 0 * func 083
690 .dc.b 0, 0, 0 * func 084
691 .dc.b 0, 0, 0 * func 005
692 .dc.b 0, 0, 0 * func 006
693 .dc.b 0, 0, 0 * func 007
694 .dc.b 0, 0, 0 * func 008
695 .dc.b 0, 0, 0 * func 009
696* fseler Manager
697 .dc.b 0, 2, 2 * func 090
698 .dc.b 0, 0, 0 * func 091
699 .dc.b 0, 0, 0 * func 092
700 .dc.b 0, 0, 0 * func 003
701 .dc.b 0, 0, 0 * func 004
702 .dc.b 0, 0, 0 * func 005
703 .dc.b 0, 0, 0 * func 006
704 .dc.b 0, 0, 0 * func 007
705 .dc.b 0, 0, 0 * func 008
706 .dc.b 0, 0, 0 * func 009
707* Window Manager
708 .dc.b 5, 1, 0 * func 100
709 .dc.b 5, 1, 0 * func 101
710 .dc.b 1, 1, 0 * func 102
711 .dc.b 1, 1, 0 * func 103
712 .dc.b 2, 5, 0 * func 104
713 .dc.b 6, 1, 0 * func 105
714 .dc.b 2, 1, 0 * func 106
715 .dc.b 1, 1, 0 * func 107
716 .dc.b 6, 5, 0 * func 108
717 .dc.b 0, 0, 0 * func 009
718* Resource Manger
719 .dc.b 0, 1, 1 * func 110
720 .dc.b 0, 1, 0 * func 111
721 .dc.b 2, 1, 0 * func 112
722 .dc.b 2, 1, 1 * func 113
723 .dc.b 1, 1, 1 * func 114
724 .dc.b 0, 0, 0 * func 115
725 .dc.b 0, 0, 0 * func 006
726 .dc.b 0, 0, 0 * func 007
727 .dc.b 0, 0, 0 * func 008
728 .dc.b 0, 0, 0 * func 009
729* Shell Manager
730 .dc.b 0, 1, 2 * func 120
731 .dc.b 3, 1, 2 * func 121
732 .dc.b 1, 1, 1 * func 122
733 .dc.b 1, 1, 1 * func 123
734 .dc.b 0, 1, 1 * func 124
735 .dc.b 0, 1, 2 * func 125
736
737 .end
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