{ ROSMAC.INC - Remote Operating System Machine Dependent Routines } { Modified for Kaypro and Z-clock by Norman Saunders - 5 Apr 85 } const { Machine specific constants } DataPort = $04; { Data port } StatusPort = $06; { Status port } RatePort = $00; { Data rate (bps) port } BasePort = $B0; { Base port for Z-Clock access} { StatusPort commands } RESCHN = $18; { reset channel } RESSTA = $10; { reset ext/status } WRREG1 = $00; { value to write to register 1 } WRREG3 = $C1; { 8 bits/char, rx enable } WRREG4 = $44; { 16x, 1 stop bit, no parity } DTROFF = $68; { dtr off, rts off } DTRON = $EA; { dtr on, 8 bits/char, tx enable, rts on } ONINS = $30; { error reset } { StatusPort status masks } DAV = $01; { data available } TRDY = $04; { transmit buffer empty } DCD = $08; { data carrier detect } PE = $10; { parity error } OE = $20; { overrun error } FE = $40; { framing error } ERR = $60; { parity, overrun and framing error } { Smartmodem result codes } OKAY = '0'; { Command executed with no errors } CONNECT300 = '1'; { Carrier detect at 300 bps } RING = '2'; { Ring signal detected } NOCARRIER = '3'; { Carrier lost or never heard } ERROR = '4'; { Error in command execution } CONNECT1200 = '5'; { Carrier detect at 1200 bps } { Rate setting commands } BD300 = 5; { 300 bps } BD1200 = 7; { 1200 bps } function mdcarck: boolean; { Check to see if carrier is present } begin port[StatusPort] := RESSTA; mdcarck := ((DCD and port[StatusPort]) <> 0) end; function mdinprdy: boolean; { Check for ready to input from modem } var bt: byte; begin if (DAV and port[StatusPort]) <> 0 then begin port[StatusPort] := 1; if (ERR and port[StatusPort]) <> 0 then begin port[StatusPort] := ONINS; bt := port[DataPort]; mdinprdy := FALSE end else mdinprdy := TRUE end else mdinprdy := FALSE end; function mdinp: byte; { Input a byte from modem - no wait - assumed ready } begin mdinp := port[DataPort] end; procedure mdout(b: byte); { Output a byte to modem - wait until ready } begin repeat until (TRDY and port[StatusPort]) <> 0; port[DataPort] := b end; procedure mdinit; { Initialize the sio channel and the Hayes Smartmodem 1200 } const sio_init: array[1..9] of byte = (RESCHN, 4, WRREG4, 1, WRREG1, 3, WRREG3, 5, DTROFF); var i: integer; mdm_attn : string[2]; mdm_init : string[41]; bt : byte; begin for i := 1 to 9 do port[StatusPort] := sio_init[i]; { initialize the SIO channel } port[StatusPort] := 5; { pull DTR high } port[StatusPort] := DTRON; mdm_attn := 'AT'; mdm_init := 'ATE0Q0V0M0X1 S0=0 S2=3 S4=255 S5=255'; port[RatePort] := BD1200; {set the 8116 to 1200 baud} delay (500); {let the modem settle for a bit} for i := 1 to 2 do begin bt := ord(mdm_attn[i]); {force the modem to 1200 baud} mdout(bt) end; bt := ord(CR); mdout(bt); delay (2000); {wait a sec...} for i := 1 to 41 do begin bt := ord(mdm_init[i]); {initialize the modem} mdout(bt) end; bt := ord(CR); mdout(bt); bt := mdinp; { clear any previous rings } bt := mdinp end; function mdring: boolean; { Determine if the phone is ringing } begin if mdinprdy then mdring := (RING = chr(mdinp)) else mdring := FALSE end; procedure mdhangup; { Hangup modem } var i : integer; mdm_hang : string[4]; bt : byte; begin repeat port[StatusPort] := 5; { setup to write register 5 } port[StatusPort] := DTROFF; { clear DTR, causing hangup } delay(2000); port[StatusPort] := 5; port[StatusPort] := DTRON; if mdcarck then begin mdm_hang := 'ATH0'; for i := 1 to 3 do begin bt := ord(ETX); mdout(bt) end; delay(1500); for i := 1 to 4 do begin bt := ord(mdm_hang[i]); mdout(bt) end; bt := ord(CR); mdout(bt) end; until not(mdcarck) end; procedure mdans; { Detect and set system to rate at which modem answered phone } var mdm_answ : string[3]; code : char; i : integer; bt : byte; begin repeat until mdinprdy; bt := mdinp; mdm_answ := 'ATA'; for i := 1 to 3 do begin bt := ord(mdm_answ[i]); mdout(bt) end; bt := ord(CR); mdout(bt); repeat until mdinprdy; code := chr(mdinp); if code = CONNECT1200 then begin port[RatePort] := BD1200; rate := 0.02075; delay(500); bt := mdinp; bt := mdinp end; if code = CONNECT300 then begin port[RatePort] := BD300; rate := 0.083; delay(500); bt := mdinp; bt := mdinp end; if code = NOCARRIER then mdhangup end; procedure GetTAD(var t: tad_array); { Return a 6 element byte array of the current system time in seconds, minutes, hours, day, month, and year. } var i : integer; Time : array [0..12] of byte; { Array filled in from Z-Clock } begin for i := 0 to 12 do { This section reads the Z-Clock } Time[i] := port[BasePort + i]; t[0] := Time[1] * 10 + Time[0]; if Time[5] < 4 then t[2] := Time[5] * 10 + Time[4] else if Time[5] >= 8 then t[2] := (Time[5] - 8) * 10 + Time[4] else t[2] := (Time[5] - 4) * 10 + Time[4]; t[1] := Time[3] * 10 + Time[2]; if Time[8] >= 4 then Time[8] := Time[8] - 4; t[3] := Time[8] * 10 + Time[7]; t[4] := Time[10] * 10 + Time[9]; t[5] := Time[12] * 10 + Time[11] end; procedure SetTAD(var t: tad_array); { Set the system time using a 6 element byte array } var i : integer; Time : array [0..12] of byte; { Array filled in from Z-Clock } begin Time[0] := 0; Time[1] := 0; Time[2] := t[1] mod 10; Time[3] := t[1] div 10; Time[4] := t[2] mod 10; Time[5] := t[2] div 10; Time[6] := 0; { Day of week computed in ROS } Time[7] := t[3] mod 10; Time[8] := t[3] div 10; Time[9] := t[4] mod 10; Time[10]:= t[4] div 10; Time[11]:= t[5] mod 10; Time[12]:= t[5] div 10; For i := 0 to 12 do port[BasePort + i] := Time[i] end;