acme/ACME_Lib/cbm/kernal.a

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;ACME 0.95
!ifdef lib_cbm_kernal_a !eof
lib_cbm_kernal_a = 1
; Taken from the web.
; Sorry, I can't give credit because I don't have the URL anymore.
; There are alternative names for some calls.
!address {
; for additional c128 calls, see <cbm/c128/kernal.a>
k_cint = $ff81
k_ioinit = $ff84
; cbm-ii rom starts here:
k_ramtas = $ff87
k_restor = $ff8a
k_vector = $ff8d
k_setmsg = $ff90
k_secnd = $ff93
k_tksa = $ff96
k_memtop = $ff99
k_membot = $ff9c
k_key = $ff9f
k_settmo = $ffa2
k_iecin = $ffa5:k_acptr = $ffa5
k_iecout = $ffa8:k_ciout = $ffa8
k_untalk = $ffab:k_untlk = $ffab
k_unlisten = $ffae:k_unlsn = $ffae
k_listen = $ffb1:k_listn = $ffb1
k_talk = $ffb4
k_readss = $ffb7
k_setlfs = $ffba ; set file parameters (A = logical file number, X = device, Y = secondary address)
k_setnam = $ffbd ; set file name (A = length, YYXX = pointer)
; pet rom starts here:
; i/o calls: these may set C on error. in that case, A holds error code, see <cbm/ioerror.a> for the actual values.
k_open = $ffc0 ; open channel/file (call setlfs/setnam before!)
k_close = $ffc3:k_close_A = $ffc3 ; close channel/file (A = logical file number)
k_chkin = $ffc6:k_chkin_X = $ffc6 ; set input channel (X = logical file number)
k_chkout = $ffc9:k_chkout_X = $ffc9:k_ckout = $ffc9 ; set output channel (X = logical file number)
k_clrchn = $ffcc:k_clrch = $ffcc ; restore default input/output channels
k_chrin = $ffcf:k_basin = $ffcf ; read byte from current input channel (not the same as $ffe4, see note* below)
; A is result byte
; X is preserved
; Y gets clobbered by tape access (preserved by disk access)
k_chrout = $ffd2:k_basout = $ffd2:k_bsout = $ffd2 ; send byte to current output channel
; A/X/Y are preserved
k_load = $ffd5:k_load_AXY = $ffd5 ; load file to memory, or verify (call setlfs/setnam before!)
; A: zero means LOAD, nonzero means VERIFY
; YYXX is desired load address (only used if secondary address == 0), returns end address plus 1
k_save = $ffd8:k_save_AXY = $ffd8 ; save memory to file (call setlfs/setnam before!)
; A is zp address of start ptr(!)
; YYXX is end address plus 1
k_settim = $ffdb ; set time
k_rdtim = $ffde ; read time
k_stop = $ffe1 ; check STOP key
k_getin = $ffe4:k_get = $ffe4 ; get input byte (not the same as $ffcf, see note* below)
; A is result byte
; X is preserved
; Y gets clobbered by tape access (preserved by disk access)
k_clall = $ffe7
k_udtim = $ffea
; pet rom stops here!?
k_scrorg = $ffed ; returns screen size (X = number of columns, Y = number of lines)
; CAUTION: the c128 uses a new format:
; c128: X/Y now return maximum values in current window (so 0..39/0..24 instead of 40/25).
; c128: A returns max column on current screen (39 or 79)
k_plot = $fff0:k_plot_CXY = $fff0 ; get/set cursor (X is line, Y is column)
; C = 0: set cursor position.
; C = 1: read cursor position.
k_iobase = $fff3 ; returns first i/o address (i.e. memory limit) in YYXX
; cbm-ii: $dc00
; vic20: $9110
; c64: $d000
; 264: $fd00
; c128: $d000
}
;note*
; the difference between CHRIN and GETIN depends on the current input device:
; input device 0 (keyboard): CHRIN reads from screen, GETIN reads from keyboard buffer
; (the same difference as between INPUT and GET in basic)
; input device 2 (rs232): CHRIN does some error handling, GETIN may just return zero on error.
; roughly speaking, CHRIN returns a "processed" byte while GETIN returns a "raw" byte.
; for devices on the IEC bus there should be no difference between the two calls.
; when reading from the console (keyboard/screen), a zero byte means "no data".
; do not expect a valid Z flag in this case! some devices may clobber the Z flag.