radix dec ; Code bank 0; Start address: 0; End address: 1023 org 0 ; Define start addresses for data regions shared___globals equ 32 __indf equ 0 __pcl equ 2 __status equ 3 __fsr equ 4 __c___byte equ 3 __c___bit equ 0 __z___byte equ 3 __z___bit equ 2 __rp0___byte equ 3 __rp0___bit equ 5 __rp1___byte equ 3 __rp1___bit equ 6 __irp___byte equ 3 __irp___bit equ 7 __pclath equ 10 __cb0___byte equ 10 __cb0___bit equ 3 __cb1___byte equ 10 __cb1___bit equ 4 ; # ############################################################################# ; # ; # Copyright (c) 2000-2004 by Wayne C. Gramlich and Bill Benson ; # All rights reserved. ; # ; # This is the code that implements the LED10 RoboBrick. Basically ; # it just waits for commands that come in at 2400 baud and responds ; # to them. See ; # ; # http://web.gramlich.net/projects/robobricks/led10/index.html ; # ; # for more details. ; # ; # ############################################################################# ; buffer = 'led10' ; line_number = 16 ; library _pic16f630 entered ; # Copyright (c) 2004 by Wayne C. Gramlich ; # All rights reserved. ; buffer = '_pic16f630' ; line_number = 5 ; processor pic16f630 ; line_number = 6 ; configure_address 0x2007 ; line_number = 7 ; configure_fill 0x0000 ; line_number = 8 ; configure_option bg: bg11 = 0x3000 ; line_number = 9 ; configure_option bg: bg10 = 0x2000 ; line_number = 10 ; configure_option bg: bg01 = 0x1000 ; line_number = 11 ; configure_option bg: bg00 = 0x0000 ; line_number = 12 ; configure_option cpd: on = 0x000 ; line_number = 13 ; configure_option cpd: off = 0x100 ; line_number = 14 ; configure_option cp: on = 0x00 ; line_number = 15 ; configure_option cp: off = 0x80 ; line_number = 16 ; configure_option boden: on = 0x40 ; line_number = 17 ; configure_option boden: off = 0x00 ; line_number = 18 ; configure_option mclre: on = 0x20 ; line_number = 19 ; configure_option mclre: off = 0x00 ; line_number = 20 ; configure_option pwrte: on = 0x00 ; line_number = 21 ; configure_option pwrte: off = 0x10 ; line_number = 22 ; configure_option wdte: on = 8 ; line_number = 23 ; configure_option wdte: off = 0 ; line_number = 24 ; configure_option fosc: rc_clk = 7 ; line_number = 25 ; configure_option fosc: rc_no_clk = 6 ; line_number = 26 ; configure_option fosc: int_clk = 5 ; line_number = 27 ; configure_option fosc: int_no_clk = 4 ; line_number = 28 ; configure_option fosc: ec = 3 ; line_number = 29 ; configure_option fosc: hs = 2 ; line_number = 30 ; configure_option fosc: xt = 1 ; line_number = 31 ; configure_option fosc: lp = 0 ; line_number = 32 ; code_bank 0x0 : 0x3ff ; line_number = 33 ; data_bank 0x0 : 0x7f ; line_number = 34 ; data_bank 0x80 : 0xff ; line_number = 35 ; shared_region 0x20 : 0x5f ; line_number = 36 ; interrupts_possible ; line_number = 37 ; osccal_register_symbol _osccal ; line_number = 38 ; osccal_at_address 0x3ff ; line_number = 39 ; packages pdip=14, soic=14, tssop=14 ; line_number = 40 ; pin vdd, power_supply ; line_number = 41 ; pin_bindings pdip=1, soic=1, tssop=1 ; line_number = 42 ; pin ra5_in, ra5_out, t1cki, osc1, clkin, ra5_unused ; line_number = 43 ; pin_bindings pdip=2, soic=2, tssop=2 ; line_number = 44 ; bind_to _porta@5 ; line_number = 45 ; or_if ra5_in _trisa 16 ; line_number = 46 ; or_if ra5_out _trisa 0 ; line_number = 47 ; pin ra4_in, ra4_out, t1g, osc2, clkout, ra4_unused ; line_number = 48 ; pin_bindings pdip=3, soic=3, tssop=3 ; line_number = 49 ; bind_to _porta@4 ; line_number = 50 ; or_if ra4_in _trisa 8 ; line_number = 51 ; or_if ra4_out _trisa 0 ; line_number = 52 ; pin ra3_in, mclr, vpp, ra3_unused ; line_number = 53 ; pin_bindings pdip=4, soic=4, tssop=4 ; line_number = 54 ; bind_to _porta@3 ; line_number = 55 ; or_if ra3_in _trisa 4 ; line_number = 56 ; pin rc5_in, rc5_out, rc5_unused ; line_number = 57 ; pin_bindings pdip=5, soic=5, tssop=5 ; line_number = 58 ; bind_to _portc@5 ; line_number = 59 ; or_if rc5_in _trisc 32 ; line_number = 60 ; or_if rc5_out _trisc 0 ; line_number = 61 ; pin rc4_in, rc4_out, rc4_unused ; line_number = 62 ; pin_bindings pdip=6, soic=6, tssop=6 ; line_number = 63 ; bind_to _portc@4 ; line_number = 64 ; or_if rc4_in _trisc 16 ; line_number = 65 ; or_if rc4_out _trisc 0 ; line_number = 66 ; pin rc3_in, rc3_out, r3_unused ; line_number = 67 ; pin_bindings pdip=7, soic=7, tssop=7 ; line_number = 68 ; bind_to _portc@3 ; line_number = 69 ; or_if rc3_in _trisc 8 ; line_number = 70 ; or_if rc3_out _trisc 0 ; line_number = 71 ; pin rc2_in, rc2_out, rc2_unused ; line_number = 72 ; pin_bindings pdip=8, soic=8, tssop=8 ; line_number = 73 ; bind_to _portc@2 ; line_number = 74 ; or_if rc2_in _trisc 4 ; line_number = 75 ; or_if rc2_out _trisc 0 ; line_number = 76 ; pin rc1_in, rc1_out, rc1_unused ; line_number = 77 ; pin_bindings pdip=9, soic=9, tssop=9 ; line_number = 78 ; bind_to _portc@1 ; line_number = 79 ; or_if rc1_in _trisc 2 ; line_number = 80 ; or_if rc1_out _trisc 0 ; line_number = 81 ; pin rc0_in, rc0_out, rc0_unused ; line_number = 82 ; pin_bindings pdip=10, soic=10, tssop=10 ; line_number = 83 ; bind_to _portc@0 ; line_number = 84 ; or_if rc0_in _trisc 1 ; line_number = 85 ; or_if rc0_out _trisc 0 ; line_number = 86 ; pin ra2_in, ra2_out, cout, t0cki, int, ra2_unused ; line_number = 87 ; pin_bindings pdip=11, soic=11, tssop=11 ; line_number = 88 ; bind_to _porta@2 ; line_number = 89 ; or_if ra2_in _trisa 4 ; line_number = 90 ; or_if ra2_out _trisa 0 ; line_number = 91 ; pin ra1_in, ra1_out, cin_minus, vref, icspclk, ra1_unused ; line_number = 92 ; pin_bindings pdip=12, soic=12, tssop=12 ; line_number = 93 ; bind_to _porta@1 ; line_number = 94 ; or_if ra1_in _trisa 2 ; line_number = 95 ; or_if ra1_out _trisa 0 ; line_number = 96 ; pin ra0_in, ra0_out, cin_plus, icspdat, ra0_unused ; line_number = 97 ; pin_bindings pdip=13, soic=13, tssop=13 ; line_number = 98 ; bind_to _porta@0 ; line_number = 99 ; or_if ra0_in _trisa 1 ; line_number = 100 ; or_if ra0_out _trisa 0 ; line_number = 101 ; pin vss, ground ; line_number = 102 ; pin_bindings pdip=14, soic=14, tssop=14 ; line_number = 107 ; library _pic16f630_676 entered ; # Copyright (c) 2004 by Wayne C. Gramlich ; # All rights reserved. ; # Shared register definitions for the PIC16F630 and PIC16F676. ; buffer = '_pic16f630_676' ; line_number = 7 ; register _indf = _indf equ 0 ; line_number = 9 ; register _tmr0 = _tmr0 equ 1 ; line_number = 11 ; register _pcl = _pcl equ 2 ; line_number = 13 ; register _status = _status equ 3 ; line_number = 14 ; bind _rp0 = _status@5 _rp0___byte equ _status _rp0___bit equ 5 ; line_number = 15 ; bind _to = _status@4 _to___byte equ _status _to___bit equ 4 ; line_number = 16 ; bind _pd = _status@3 _pd___byte equ _status _pd___bit equ 3 ; line_number = 17 ; bind _z = _status@2 _z___byte equ _status _z___bit equ 2 ; line_number = 18 ; bind _dc = _status@1 _dc___byte equ _status _dc___bit equ 1 ; line_number = 19 ; bind _c = _status@0 _c___byte equ _status _c___bit equ 0 ; line_number = 21 ; register _fsr = _fsr equ 4 ; line_number = 23 ; register _porta = _porta equ 5 ; line_number = 24 ; register _ra = _ra equ 5 ; line_number = 25 ; bind _ra5 = _porta@5 _ra5___byte equ _porta _ra5___bit equ 5 ; line_number = 26 ; bind _ra4 = _porta@4 _ra4___byte equ _porta _ra4___bit equ 4 ; line_number = 27 ; bind _ra3 = _porta@3 _ra3___byte equ _porta _ra3___bit equ 3 ; line_number = 28 ; bind _ra2 = _porta@2 _ra2___byte equ _porta _ra2___bit equ 2 ; line_number = 29 ; bind _ra1 = _porta@1 _ra1___byte equ _porta _ra1___bit equ 1 ; line_number = 30 ; bind _ra0 = _porta@0 _ra0___byte equ _porta _ra0___bit equ 0 ; line_number = 32 ; register _portc = _portc equ 7 ; line_number = 33 ; register _rc = _rc equ 7 ; line_number = 34 ; bind _rc5 = _portc@5 _rc5___byte equ _portc _rc5___bit equ 5 ; line_number = 35 ; bind _rc4 = _portc@4 _rc4___byte equ _portc _rc4___bit equ 4 ; line_number = 36 ; bind _rc3 = _portc@3 _rc3___byte equ _portc _rc3___bit equ 3 ; line_number = 37 ; bind _rc2 = _portc@2 _rc2___byte equ _portc _rc2___bit equ 2 ; line_number = 38 ; bind _rc1 = _portc@1 _rc1___byte equ _portc _rc1___bit equ 1 ; line_number = 39 ; bind _rc0 = _portc@0 _rc0___byte equ _portc _rc0___bit equ 0 ; line_number = 41 ; register _pclath = _pclath equ 10 ; line_number = 43 ; register _intcon = _intcon equ 11 ; line_number = 44 ; bind _gie = _intcon@7 _gie___byte equ _intcon _gie___bit equ 7 ; line_number = 45 ; bind _peie = _intcon@6 _peie___byte equ _intcon _peie___bit equ 6 ; line_number = 46 ; bind _t0ie = _intcon@5 _t0ie___byte equ _intcon _t0ie___bit equ 5 ; line_number = 47 ; bind _inte = _intcon@4 _inte___byte equ _intcon _inte___bit equ 4 ; line_number = 48 ; bind _raie = _intcon@3 _raie___byte equ _intcon _raie___bit equ 3 ; line_number = 49 ; bind _t0if = _intcon@2 _t0if___byte equ _intcon _t0if___bit equ 2 ; line_number = 50 ; bind _intf = _intcon@1 _intf___byte equ _intcon _intf___bit equ 1 ; line_number = 51 ; bind _raif = _intcon@0 _raif___byte equ _intcon _raif___bit equ 0 ; line_number = 53 ; register _pir1 = _pir1 equ 12 ; line_number = 54 ; bind _eeif = _pir1@7 _eeif___byte equ _pir1 _eeif___bit equ 7 ; line_number = 55 ; bind _cmif = _pir1@3 _cmif___byte equ _pir1 _cmif___bit equ 3 ; line_number = 56 ; bind _tmr1if = _pir1@0 _tmr1if___byte equ _pir1 _tmr1if___bit equ 0 ; line_number = 58 ; register _tmr1l = _tmr1l equ 14 ; line_number = 60 ; register _tmr1h = _tmr1h equ 15 ; line_number = 62 ; register _t1con = _t1con equ 16 ; line_number = 63 ; bind _t1ge = _t1con@6 _t1ge___byte equ _t1con _t1ge___bit equ 6 ; line_number = 64 ; bind _t1ckps1 = _t1con@5 _t1ckps1___byte equ _t1con _t1ckps1___bit equ 5 ; line_number = 65 ; bind _t1ckps0 = _t1con@4 _t1ckps0___byte equ _t1con _t1ckps0___bit equ 4 ; line_number = 66 ; bind _t1oscen = _t1con@3 _t1oscen___byte equ _t1con _t1oscen___bit equ 3 ; line_number = 67 ; bind _t1sync = _t1con@2 _t1sync___byte equ _t1con _t1sync___bit equ 2 ; line_number = 68 ; bind _tmr1cs = _t1con@1 _tmr1cs___byte equ _t1con _tmr1cs___bit equ 1 ; line_number = 69 ; bind _tmr1on = _t1con@0 _tmr1on___byte equ _t1con _tmr1on___bit equ 0 ; line_number = 71 ; register _cmcon = _cmcon equ 25 ; line_number = 72 ; bind _cout = _cmcon@6 _cout___byte equ _cmcon _cout___bit equ 6 ; line_number = 73 ; bind _cinv = _cmcon@4 _cinv___byte equ _cmcon _cinv___bit equ 4 ; line_number = 74 ; bind _cis = _cmcon@3 _cis___byte equ _cmcon _cis___bit equ 3 ; line_number = 75 ; bind _cm2 = _cmcon@2 _cm2___byte equ _cmcon _cm2___bit equ 2 ; line_number = 76 ; bind _cm1 = _cmcon@1 _cm1___byte equ _cmcon _cm1___bit equ 1 ; line_number = 77 ; bind _cm0 = _cmcon@0 _cm0___byte equ _cmcon _cm0___bit equ 0 ; # Data bank 1 (0x80-0xff): ; line_number = 81 ; register _option_reg = _option_reg equ 128 ; line_number = 82 ; bind _rapu = _option_reg@7 _rapu___byte equ _option_reg _rapu___bit equ 7 ; line_number = 83 ; bind _intedg = _option_reg@6 _intedg___byte equ _option_reg _intedg___bit equ 6 ; line_number = 84 ; bind _t0cs = _option_reg@5 _t0cs___byte equ _option_reg _t0cs___bit equ 5 ; line_number = 85 ; bind _t0se = _option_reg@4 _t0se___byte equ _option_reg _t0se___bit equ 4 ; line_number = 86 ; bind _psa = _option_reg@3 _psa___byte equ _option_reg _psa___bit equ 3 ; line_number = 87 ; bind _ps2 = _option_reg@2 _ps2___byte equ _option_reg _ps2___bit equ 2 ; line_number = 88 ; bind _ps1 = _option_reg@1 _ps1___byte equ _option_reg _ps1___bit equ 1 ; line_number = 89 ; bind _ps0 = _option_reg@0 _ps0___byte equ _option_reg _ps0___bit equ 0 ; line_number = 91 ; register _trisa = _trisa equ 133 ; line_number = 92 ; bind _trisa5 = _trisa@5 _trisa5___byte equ _trisa _trisa5___bit equ 5 ; line_number = 93 ; bind _trisa4 = _trisa@4 _trisa4___byte equ _trisa _trisa4___bit equ 4 ; line_number = 94 ; bind _trisa3 = _trisa@3 _trisa3___byte equ _trisa _trisa3___bit equ 3 ; line_number = 95 ; bind _trisa2 = _trisa@2 _trisa2___byte equ _trisa _trisa2___bit equ 2 ; line_number = 96 ; bind _trisa1 = _trisa@1 _trisa1___byte equ _trisa _trisa1___bit equ 1 ; line_number = 97 ; bind _trisa0 = _trisa@0 _trisa0___byte equ _trisa _trisa0___bit equ 0 ; line_number = 99 ; register _trisc = _trisc equ 135 ; line_number = 100 ; bind _trisc5 = _trisc@5 _trisc5___byte equ _trisc _trisc5___bit equ 5 ; line_number = 101 ; bind _trisc4 = _trisc@4 _trisc4___byte equ _trisc _trisc4___bit equ 4 ; line_number = 102 ; bind _trisc3 = _trisc@3 _trisc3___byte equ _trisc _trisc3___bit equ 3 ; line_number = 103 ; bind _trisc2 = _trisc@2 _trisc2___byte equ _trisc _trisc2___bit equ 2 ; line_number = 104 ; bind _trisc1 = _trisc@1 _trisc1___byte equ _trisc _trisc1___bit equ 1 ; line_number = 105 ; bind _trisc0 = _trisc@0 _trisc0___byte equ _trisc _trisc0___bit equ 0 ; line_number = 107 ; register _pie1 = _pie1 equ 140 ; line_number = 108 ; bind _eeie = _pie1@7 _eeie___byte equ _pie1 _eeie___bit equ 7 ; line_number = 109 ; bind _adie = _pie1@6 _adie___byte equ _pie1 _adie___bit equ 6 ; line_number = 110 ; bind _cmie = _pie1@3 _cmie___byte equ _pie1 _cmie___bit equ 3 ; line_number = 111 ; bind _tmr1ie = _pie1@0 _tmr1ie___byte equ _pie1 _tmr1ie___bit equ 0 ; line_number = 113 ; register _pcon = _pcon equ 142 ; line_number = 114 ; bind _por = _pcon@1 _por___byte equ _pcon _por___bit equ 1 ; line_number = 115 ; bind _bor = _pcon@0 _bor___byte equ _pcon _bor___bit equ 0 ; line_number = 117 ; register _osccal = _osccal equ 144 ; line_number = 118 ; bind _cal5 = _osccal@7 _cal5___byte equ _osccal _cal5___bit equ 7 ; line_number = 119 ; bind _cal4 = _osccal@6 _cal4___byte equ _osccal _cal4___bit equ 6 ; line_number = 120 ; bind _cal3 = _osccal@5 _cal3___byte equ _osccal _cal3___bit equ 5 ; line_number = 121 ; bind _cal2 = _osccal@4 _cal2___byte equ _osccal _cal2___bit equ 4 ; line_number = 122 ; bind _cal1 = _osccal@3 _cal1___byte equ _osccal _cal1___bit equ 3 ; line_number = 123 ; bind _cal0 = _osccal@2 _cal0___byte equ _osccal _cal0___bit equ 2 ; line_number = 124 ; constant _osccal_lsb = 4 _osccal_lsb equ 4 ; line_number = 126 ; register _wpua = _wpua equ 149 ; line_number = 127 ; bind _wpua5 = _wpua@5 _wpua5___byte equ _wpua _wpua5___bit equ 5 ; line_number = 128 ; bind _wpua4 = _wpua@4 _wpua4___byte equ _wpua _wpua4___bit equ 4 ; line_number = 129 ; bind _wpua2 = _wpua@2 _wpua2___byte equ _wpua _wpua2___bit equ 2 ; line_number = 130 ; bind _wpua1 = _wpua@1 _wpua1___byte equ _wpua _wpua1___bit equ 1 ; line_number = 131 ; bind _wpua0 = _wpua@0 _wpua0___byte equ _wpua _wpua0___bit equ 0 ; line_number = 133 ; register _ioca = _ioca equ 150 ; line_number = 134 ; bind _ioca5 = _ioca@5 _ioca5___byte equ _ioca _ioca5___bit equ 5 ; line_number = 135 ; bind _ioca4 = _ioca@4 _ioca4___byte equ _ioca _ioca4___bit equ 4 ; line_number = 136 ; bind _ioca3 = _ioca@3 _ioca3___byte equ _ioca _ioca3___bit equ 3 ; line_number = 137 ; bind _ioca2 = _ioca@2 _ioca2___byte equ _ioca _ioca2___bit equ 2 ; line_number = 138 ; bind _ioca1 = _ioca@1 _ioca1___byte equ _ioca _ioca1___bit equ 1 ; line_number = 139 ; bind _ioca0 = _ioca@0 _ioca0___byte equ _ioca _ioca0___bit equ 0 ; line_number = 141 ; register _vrcon = _vrcon equ 153 ; line_number = 142 ; bind _vren = _vrcon@7 _vren___byte equ _vrcon _vren___bit equ 7 ; line_number = 143 ; bind _vrr = _vrcon@5 _vrr___byte equ _vrcon _vrr___bit equ 5 ; line_number = 144 ; bind _vr3 = _vrcon@3 _vr3___byte equ _vrcon _vr3___bit equ 3 ; line_number = 145 ; bind _vr2 = _vrcon@2 _vr2___byte equ _vrcon _vr2___bit equ 2 ; line_number = 146 ; bind _vr1 = _vrcon@1 _vr1___byte equ _vrcon _vr1___bit equ 1 ; line_number = 147 ; bind _vr0 = _vrcon@0 _vr0___byte equ _vrcon _vr0___bit equ 0 ; line_number = 149 ; register _eedata = _eedata equ 154 ; line_number = 151 ; register _eeadr = _eeadr equ 155 ; line_number = 153 ; register _eecon1 = _eecon1 equ 156 ; line_number = 154 ; bind _wrerr = _eecon1@3 _wrerr___byte equ _eecon1 _wrerr___bit equ 3 ; line_number = 155 ; bind _wren = _eecon1@2 _wren___byte equ _eecon1 _wren___bit equ 2 ; line_number = 156 ; bind _wr = _eecon1@1 _wr___byte equ _eecon1 _wr___bit equ 1 ; line_number = 157 ; bind _rd = _eecon1@0 _rd___byte equ _eecon1 _rd___bit equ 0 ; line_number = 159 ; register _eecon2 = _eecon2 equ 157 ; buffer = '_pic16f630' ; line_number = 107 ; library _pic16f630_676 exited ; buffer = 'led10' ; line_number = 16 ; library _pic16f630 exited ; line_number = 17 ; library clock4mhz entered ; # Copyright (c) 2004 by Wayne C. Gramlich ; # All rights reserved. ; # This library defines the contstants {clock_rate}, {instruction_rate}, ; # and {clocks_per_instruction}. ; # Define processor constants: ; buffer = 'clock4mhz' ; line_number = 9 ; constant clock_rate = 4000000 clock_rate equ 4000000 ; line_number = 10 ; constant clocks_per_instruction = 4 clocks_per_instruction equ 4 ; line_number = 11 ; constant instruction_rate = clock_rate / clocks_per_instruction instruction_rate equ 1000000 ; buffer = 'led10' ; line_number = 17 ; library clock4mhz exited ; line_number = 18 ; library bit_bang entered ; # Copyright (c) 2004 by Wayne C. Gramlich ; # All rights reserved. ; # This library provides bit bang routines for sending and receiving ; # serial data at 2400 baud in 8N1 format (1 start bit, 8 data bits, ; # No parity bit, 1 stop stop bit.) ; # ; # This library requires that the pins {serial_in} and {serial_out} ; # be defined. In addition, the variable {instruction_rate} needs ; # to be defined. Lastly, there needs to be a {delay} procedure ; # with an "exact_delay delay_instructions" clause in it. The {delay} ; # routine should invoke "watch_dog_reset" so that the watch dog time ; # can be set. ; # Define some constants that we will be needing: ; buffer = 'bit_bang' ; line_number = 17 ; constant baud_rate = 2400 baud_rate equ 2400 ; line_number = 18 ; constant instructions_per_bit = instruction_rate / baud_rate instructions_per_bit equ 416 ; line_number = 19 ; constant delays_per_bit = 3 delays_per_bit equ 3 ; line_number = 20 ; constant instructions_per_delay = instructions_per_bit / delays_per_bit instructions_per_delay equ 138 ; line_number = 21 ; constant extra_instructions = 5 extra_instructions equ 5 ; line_number = 22 ; constant delay_instructions = instructions_per_delay - extra_instructions delay_instructions equ 133 ; # The {receiving} bit is sent when data is being received. ; # It gets cleared whenever data gets sent. It is used to ; # determine whether additional delay is needed to turn a ; # line around for slow interpretted chips like the Basic ; # Stamp 2 and the OOPIC. ; line_number = 30 ; global receiving bit receiving___byte equ shared___globals+63 receiving___bit equ 0 ; line_number = 31 ; global waiting bit waiting___byte equ shared___globals+63 waiting___bit equ 1 ; Delaying code generation for procedure byte_get ; Delaying code generation for procedure byte_put ; buffer = 'led10' ; line_number = 18 ; library bit_bang exited ; line_number = 20 ; package pdip ; line_number = 21 ; pin 1 = power_supply ; line_number = 22 ; pin 2 = ra5_out, name = led0 led0___byte equ _porta led0___bit equ 5 ; line_number = 23 ; pin 3 = ra4_out, name = led1 led1___byte equ _porta led1___bit equ 4 ; line_number = 24 ; pin 4 = ra3_in, name = serial_in serial_in___byte equ _porta serial_in___bit equ 3 ; line_number = 25 ; pin 5 = rc5_out, name = led2 led2___byte equ _portc led2___bit equ 5 ; line_number = 26 ; pin 6 = rc4_out, name = led3 led3___byte equ _portc led3___bit equ 4 ; line_number = 27 ; pin 7 = rc3_out, name = led4 led4___byte equ _portc led4___bit equ 3 ; line_number = 28 ; pin 8 = rc2_out, name = led5 led5___byte equ _portc led5___bit equ 2 ; line_number = 29 ; pin 9 = rc1_out, name = led6 led6___byte equ _portc led6___bit equ 1 ; line_number = 30 ; pin 10 = rc0_out, name = led7 led7___byte equ _portc led7___bit equ 0 ; line_number = 31 ; pin 11 = ra2_out, name = serial_out serial_out___byte equ _porta serial_out___bit equ 2 ; line_number = 32 ; pin 12 = ra1_out, name = led8 led8___byte equ _porta led8___bit equ 1 ; line_number = 33 ; pin 13 = ra0_out, name = led9 led9___byte equ _porta led9___bit equ 0 ; line_number = 34 ; pin 14 = ground ; line_number = 36 ; constant leds_count = 10 leds_count equ 10 ; line_number = 38 ; global leds_mask_low byte leds_mask_low equ shared___globals+4 ; line_number = 39 ; global leds_mask_high byte leds_mask_high equ shared___globals+5 ; line_number = 40 ; global blink_masks[leds_count] array[byte] blink_masks equ shared___globals+6 ; line_number = 41 ; global command_previous byte command_previous equ shared___globals+16 ; line_number = 42 ; global command_last byte command_last equ shared___globals+17 ; line_number = 43 ; global sent_previous byte sent_previous equ shared___globals+18 ; line_number = 44 ; global sent_last byte sent_last equ shared___globals+19 ; line_number = 46 ; procedure main main: ; Need to calibrate the oscillator call 1023 bsf __rp0___byte, __rp0___bit movwf _osccal ; Initialize some registers movlw 4 movwf _trisa clrf _trisc ; arguments_none ; line_number = 48 ; returns_nothing ; line_number = 50 ; local ledx byte main__ledx equ shared___globals+20 ; line_number = 51 ; local command byte main__command equ shared___globals+21 ; line_number = 52 ; local data byte main__data equ shared___globals+22 ; line_number = 53 ; local glitch byte main__glitch equ shared___globals+23 ; line_number = 54 ; local index byte main__index equ shared___globals+24 ; line_number = 55 ; local mask byte main__mask equ shared___globals+25 ; line_number = 56 ; local rate byte main__rate equ shared___globals+26 ; line_number = 57 ; local result byte main__result equ shared___globals+27 ; line_number = 58 ; local temp byte main__temp equ shared___globals+28 ; # Initialize blink_masks: ; before procedure statements delay=non-uniform, bit states=(data:X0=>X1 code:XX=>XX) ; line_number = 61 ; index := 0 movlw 0 bcf __rp0___byte, __rp0___bit movwf main__index ; line_number = 62 ; loop_exactly leds_count start main__1 equ shared___globals+34 movlw 10 movwf main__1 main__2: ; line_number = 63 ; blink_masks[index - 1] := 0xff ; index_fsr_first decf main__index,w addlw blink_masks movwf __fsr movlw 255 movwf __indf ; line_number = 64 ; index := index + 1 incf main__index,f ; line_number = 62 ; loop_exactly leds_count wrap-up decfsz main__1,f goto main__2 ; line_number = 62 ; loop_exactly leds_count done ; # Initialize remaining registers: ; line_number = 67 ; glitch := 0 movlw 0 movwf main__glitch ; line_number = 68 ; index := 0 movlw 0 movwf main__index ; line_number = 69 ; leds_mask_low := 0 movlw 0 movwf leds_mask_low ; line_number = 70 ; leds_mask_high := 0 movlw 0 movwf leds_mask_high ; # Process commands: ; line_number = 73 ; loop_forever start main__3: ; # Wait for command: ; line_number = 75 ; command := byte_get() call byte_get movwf main__command ; # Dispatch on command: ; line_number = 78 ; switch command >> 6 start movlw main__79>>8 movwf __pclath main__80 equ shared___globals+34 swapf main__command,w movwf main__80 rrf main__80,f rrf main__80,w andlw 3 addlw main__79 movwf __pcl ; page_group 4 main__79: goto main__75 goto main__76 goto main__77 goto main__78 ; line_number = 80 ; case 0 main__75: ; # (Command = 00xx xxxx): ; line_number = 82 ; if command@5 start main__select__4___byte equ main__command main__select__4___bit equ 5 ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code_size > 1 && false_code_size > 1 ; true_code_size=3 false_code_size=2 btfss main__select__4___byte, main__select__4___bit goto main__5 ; # Write Upper (Command = 001a bcde): ; line_number = 84 ; leds_mask_high := command & 0x1f movlw 31 andwf main__command,w movwf leds_mask_high goto main__6 main__5: ; # Write Lower (Command = 000a bcde): ; line_number = 87 ; leds_mask_low := command movf main__command,w movwf leds_mask_low main__6: ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=main__select__4 (data:X0=>X0 code:XX=>XX) ; line_number = 82 ; if command@5 done goto main__81 ; line_number = 89 ; case 1 main__76: ; # Bit commands:(Command = 01cc bbbb): ; line_number = 91 ; ledx := command & 0xf movlw 15 andwf main__command,w movwf main__ledx ; line_number = 92 ; data := leds_mask_low movf leds_mask_low,w movwf main__data ; line_number = 93 ; if ledx >= 5 start movlw 5 subwf main__ledx,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code.size = 0 && false_code.size > 1 ; bit_code_emit_helper1: body_code.size=4 true_test=true body_code.delay=0 (non-uniform delay) btfss __c___byte, __c___bit goto main__7 ; line_number = 94 ; ledx := ledx - 5 movlw 251 addwf main__ledx,f ; line_number = 95 ; data := leds_mask_high movf leds_mask_high,w movwf main__data ; Recombine size1 = 0 || size2 = 0 main__7: ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__c (data:X0=>X0 code:XX=>XX) ; line_number = 93 ; if ledx >= 5 done ; # Compute the mask: ; line_number = 98 ; mask := 1 movlw 1 movwf main__mask ; line_number = 99 ; while ledx != 0 start main__8: ; Left minus Right movf main__ledx,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true.size=0 && false.size>1 ; bit_code_emit_helper1: body_code.size=4 true_test=false body_code.delay=0 (non-uniform delay) btfsc __z___byte, __z___bit goto main__9 ; line_number = 100 ; mask := mask << 1 ; Assignment of variable to self (no code needed) rlf main__mask,f bcf main__mask, 0 ; line_number = 101 ; ledx := ledx - 1 decf main__ledx,f goto main__8 main__9: ; Recombine size1 = 0 || size2 = 0 ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; line_number = 99 ; while ledx != 0 done ; line_number = 103 ; ledx := command & 0xf movlw 15 andwf main__command,w movwf main__ledx ; line_number = 104 ; switch (command >> 4) & 3 start movlw main__14>>8 movwf __pclath main__15 equ shared___globals+34 swapf main__command,w andlw 3 addlw main__14 movwf __pcl ; page_group 4 main__14: goto main__10 goto main__11 goto main__12 goto main__13 ; line_number = 105 ; case 0 main__10: ; # Bit Clear (Command = 0100 bbbb): ; line_number = 107 ; data := data & (0xff ^ mask) movlw 255 xorwf main__mask,w andwf main__data,f goto main__16 ; line_number = 108 ; case 1 main__11: ; # Bit Set (Command = 0100 bbbb): ; line_number = 110 ; data := data | mask movf main__mask,w iorwf main__data,f goto main__16 ; line_number = 111 ; case 2 main__12: ; # Bit Toggle (Command = 0100 bbbb): ; line_number = 113 ; data := data ^ mask movf main__mask,w xorwf main__data,f goto main__16 ; line_number = 114 ; case 3 main__13: ; # Bit Read (Command = 0100 bbbb): ; line_number = 116 ; result := (mask_to_bit(blink_masks[ledx]) ^ 7) << 5 movf main__ledx,w addlw blink_masks movwf __fsr movf __indf,w call mask_to_bit xorlw 7 movwf main__result swapf main__result,f rlf main__result,f movlw 224 andwf main__result,f ; line_number = 117 ; if data & mask != 0 start ; Left minus Right movf main__data,w andwf main__mask,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code.size=0 && false_code.size=1 btfss __z___byte, __z___bit ; line_number = 118 ; result := result + 1 incf main__result,f ; Recombine size1 = 0 || size2 = 0 ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; line_number = 117 ; if data & mask != 0 done ; line_number = 119 ; call byte_put(result) movf main__result,w call byte_put main__16: ; switch end:(data:X0=>X0 code:XX=>XX) ; line_number = 104 ; switch (command >> 4) & 3 done ; # Stuff the data back: ; line_number = 122 ; if ledx < 5 start movlw 5 subwf main__ledx,w ; line_number = 125 ; leds_mask_high := data movf main__data,w ; line_number = 123 ; leds_mask_low := data ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_size=1 && false_size=1 ; SUBCASE: Double test; true, then false btfsc __c___byte, __c___bit movwf leds_mask_high btfss __c___byte, __c___bit movwf leds_mask_low ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__c (data:X0=>X0 code:XX=>XX) ; line_number = 122 ; if ledx < 5 done goto main__81 ; line_number = 126 ; case 2 main__77: ; # Do nothing (Command = 10xx xxx): ; line_number = 128 ; switch (command >> 4) & 3 start movlw main__59>>8 movwf __pclath main__60 equ shared___globals+34 swapf main__command,w andlw 3 addlw main__59 movwf __pcl ; page_group 4 main__59: goto main__55 goto main__56 goto main__57 goto main__58 ; line_number = 129 ; case 0 main__55: ; # Command = 1000 xxxx: ; line_number = 131 ; switch (command >> 2) & 3 start movlw main__28>>8 movwf __pclath main__29 equ shared___globals+34 rrf main__command,w movwf main__29 rrf main__29,w andlw 3 addlw main__28 movwf __pcl ; page_group 4 main__28: goto main__26 goto main__27 goto main__27 goto main__27 ; line_number = 132 ; case 0 main__26: ; # Command = 1000 00xx: ; line_number = 134 ; switch command & 3 start movlw main__24>>8 movwf __pclath movlw 3 andwf main__command,w addlw main__24 movwf __pcl ; page_group 4 main__24: goto main__20 goto main__21 goto main__22 goto main__23 ; line_number = 135 ; case 0 main__20: ; # Read All (Command = 1000 0000): ; line_number = 137 ; call byte_put(leds_mask_high) movf leds_mask_high,w call byte_put ; line_number = 138 ; call byte_put(leds_mask_low) movf leds_mask_low,w call byte_put goto main__25 ; line_number = 139 ; case 1 main__21: ; # Read Lower (Command = 1000 0001): ; line_number = 141 ; call byte_put(leds_mask_low) movf leds_mask_low,w call byte_put ; # xx = 10: read-all, lower, upper; ; # blink rate; inc/dec leds;pwr mode goto main__25 ; line_number = 144 ; case 2 main__22: ; # Read Upper (Command = 1000 0010): ; line_number = 146 ; call byte_put(leds_mask_high) movf leds_mask_high,w call byte_put goto main__25 ; line_number = 148 ; case 3 main__23: ; # Blink Rate Set (Command = 1000 0011): ; line_number = 150 ; command := byte_get() call byte_get movwf main__command ; line_number = 151 ; ledx := command & 0xf movlw 15 andwf main__command,w movwf main__ledx ; line_number = 152 ; if ledx >= 10 start movlw 10 subwf main__ledx,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code.size = 0 && false_code.size > 1 ; bit_code_emit_helper1: body_code.size=2 true_test=true body_code.delay=0 (non-uniform delay) btfss __c___byte, __c___bit goto main__17 ; line_number = 153 ; ledx := 0 movlw 0 movwf main__ledx ; Recombine size1 = 0 || size2 = 0 main__17: ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__c (data:X0=>X0 code:XX=>XX) ; line_number = 152 ; if ledx >= 10 done ; line_number = 154 ; blink_masks[ledx] := bit_to_mask[command >> 5] ; right_temporary_first main__18 equ shared___globals+34 main__19 equ shared___globals+35 swapf main__command,w movwf main__19 rrf main__19,w andlw 7 call bit_to_mask movwf main__18 movf main__ledx,w addlw blink_masks movwf __fsr movf main__18,w movwf __indf main__25: ; switch end:(data:X0=>X0 code:XX=>XX) ; line_number = 134 ; switch command & 3 done goto main__30 ; line_number = 155 ; case 1, 2, 3 main__27: ; line_number = 156 ; do_nothing main__30: ; switch end:(data:X0=>X? code:XX=>XX) ; line_number = 131 ; switch (command >> 2) & 3 done goto main__61 ; line_number = 157 ; case 1 main__56: ; # Increment LED's (Command = 1001 bbbb): ; line_number = 159 ; ledx := command & 0xf movlw 15 andwf main__command,w movwf main__ledx ; line_number = 160 ; mask := 1 movlw 1 movwf main__mask ; line_number = 161 ; if ledx < 5 start movlw 5 subwf main__ledx,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code_size > 1 && false_code_size > 1 ; true_code_size=11 false_code_size=14 btfss __c___byte, __c___bit goto main__37 ; line_number = 170 ; ledx := ledx - 5 movlw 251 addwf main__ledx,f ; line_number = 171 ; while ledx != 0 start main__31: ; Left minus Right movf main__ledx,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true.size=0 && false.size>1 ; bit_code_emit_helper1: body_code.size=4 true_test=false body_code.delay=0 (non-uniform delay) btfsc __z___byte, __z___bit goto main__32 ; line_number = 172 ; mask := mask << 1 ; Assignment of variable to self (no code needed) rlf main__mask,f bcf main__mask, 0 ; line_number = 173 ; ledx := ledx - 1 decf main__ledx,f goto main__31 main__32: ; Recombine size1 = 0 || size2 = 0 ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; line_number = 171 ; while ledx != 0 done ; line_number = 174 ; leds_mask_high := leds_mask_high + mask movf main__mask,w addwf leds_mask_high,f goto main__38 main__37: ; line_number = 162 ; while ledx != 0 start main__33: ; Left minus Right movf main__ledx,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true.size=0 && false.size>1 ; bit_code_emit_helper1: body_code.size=4 true_test=false body_code.delay=0 (non-uniform delay) btfsc __z___byte, __z___bit goto main__34 ; line_number = 163 ; mask := mask << 1 ; Assignment of variable to self (no code needed) rlf main__mask,f bcf main__mask, 0 ; line_number = 164 ; ledx := ledx - 1 decf main__ledx,f goto main__33 main__34: ; Recombine size1 = 0 || size2 = 0 ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; line_number = 162 ; while ledx != 0 done ; line_number = 165 ; leds_mask_low := leds_mask_low + mask movf main__mask,w addwf leds_mask_low,f ; line_number = 166 ; if leds_mask_low@5 start main__select__35___byte equ leds_mask_low main__select__35___bit equ 5 ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code.size = 0 && false_code.size > 1 ; bit_code_emit_helper1: body_code.size=3 true_test=true body_code.delay=0 (non-uniform delay) btfss main__select__35___byte, main__select__35___bit goto main__36 ; line_number = 167 ; leds_mask_low := leds_mask_low & 0x1f movlw 31 andwf leds_mask_low,f ; line_number = 168 ; leds_mask_high := leds_mask_high + 1 incf leds_mask_high,f ; Recombine size1 = 0 || size2 = 0 main__36: ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=main__select__35 (data:X0=>X0 code:XX=>XX) ; line_number = 166 ; if leds_mask_low@5 done main__38: ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__c (data:X0=>X0 code:XX=>XX) ; line_number = 161 ; if ledx < 5 done ; line_number = 175 ; leds_mask_high := leds_mask_high & 0x1f movlw 31 andwf leds_mask_high,f goto main__61 ; line_number = 176 ; case 2 main__57: ; # Decrement LED's (Command = 1010 bbbb): ; line_number = 178 ; ledx := command & 0xf movlw 15 andwf main__command,w movwf main__ledx ; line_number = 179 ; mask := 1 movlw 1 movwf main__mask ; line_number = 180 ; if ledx < 5 start movlw 5 subwf main__ledx,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code_size > 1 && false_code_size > 1 ; true_code_size=11 false_code_size=14 btfss __c___byte, __c___bit goto main__45 ; line_number = 189 ; ledx := ledx - 5 movlw 251 addwf main__ledx,f ; line_number = 190 ; while ledx != 0 start main__39: ; Left minus Right movf main__ledx,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true.size=0 && false.size>1 ; bit_code_emit_helper1: body_code.size=4 true_test=false body_code.delay=0 (non-uniform delay) btfsc __z___byte, __z___bit goto main__40 ; line_number = 191 ; mask := mask << 1 ; Assignment of variable to self (no code needed) rlf main__mask,f bcf main__mask, 0 ; line_number = 192 ; ledx := ledx -1 decf main__ledx,f goto main__39 main__40: ; Recombine size1 = 0 || size2 = 0 ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; line_number = 190 ; while ledx != 0 done ; line_number = 193 ; leds_mask_high := leds_mask_high - mask movf main__mask,w subwf leds_mask_high,f goto main__46 main__45: ; line_number = 181 ; while ledx != 0 start main__41: ; Left minus Right movf main__ledx,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true.size=0 && false.size>1 ; bit_code_emit_helper1: body_code.size=4 true_test=false body_code.delay=0 (non-uniform delay) btfsc __z___byte, __z___bit goto main__42 ; line_number = 182 ; mask := mask << 1 ; Assignment of variable to self (no code needed) rlf main__mask,f bcf main__mask, 0 ; line_number = 183 ; ledx := ledx -1 decf main__ledx,f goto main__41 main__42: ; Recombine size1 = 0 || size2 = 0 ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; line_number = 181 ; while ledx != 0 done ; line_number = 184 ; leds_mask_low := leds_mask_low - mask movf main__mask,w subwf leds_mask_low,f ; line_number = 185 ; if leds_mask_low@5 start main__select__43___byte equ leds_mask_low main__select__43___bit equ 5 ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code.size = 0 && false_code.size > 1 ; bit_code_emit_helper1: body_code.size=3 true_test=true body_code.delay=0 (non-uniform delay) btfss main__select__43___byte, main__select__43___bit goto main__44 ; line_number = 186 ; leds_mask_low := leds_mask_low & 0x1f movlw 31 andwf leds_mask_low,f ; line_number = 187 ; leds_mask_high := leds_mask_high - 1 decf leds_mask_high,f ; Recombine size1 = 0 || size2 = 0 main__44: ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=main__select__43 (data:X0=>X0 code:XX=>XX) ; line_number = 185 ; if leds_mask_low@5 done main__46: ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__c (data:X0=>X0 code:XX=>XX) ; line_number = 180 ; if ledx < 5 done ; line_number = 194 ; leds_mask_high := leds_mask_high & 0x1f movlw 31 andwf leds_mask_high,f goto main__61 ; line_number = 195 ; case 3 main__58: ; # Power Level Set (Command = 1011 llll): ; line_number = 197 ; ledx := command & 0xf movlw 15 andwf main__command,w movwf main__ledx ; line_number = 198 ; mask := 0 movlw 0 movwf main__mask ; line_number = 199 ; if ledx <= 5 start movlw 5 subwf main__ledx,w btfsc __z___byte, __z___bit bcf __c___byte, __c___bit ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code_size > 1 && false_code_size > 1 ; true_code_size=15 false_code_size=12 btfss __c___byte, __c___bit goto main__53 ; line_number = 206 ; ledx := ledx - 5 movlw 251 addwf main__ledx,f ; line_number = 207 ; while ledx != 0 start main__47: ; Left minus Right movf main__ledx,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true.size=0 && false.size>1 ; bit_code_emit_helper1: body_code.size=6 true_test=false body_code.delay=0 (non-uniform delay) btfsc __z___byte, __z___bit goto main__49 ; line_number = 208 ; mask := mask << 1 | 1 main__48 equ shared___globals+34 rlf main__mask,w andlw 254 iorlw 1 movwf main__mask ; line_number = 209 ; ledx := ledx - 1 decf main__ledx,f goto main__47 main__49: ; Recombine size1 = 0 || size2 = 0 ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; line_number = 207 ; while ledx != 0 done ; line_number = 210 ; leds_mask_low := 0x1f movlw 31 movwf leds_mask_low ; line_number = 211 ; leds_mask_high := mask & 0x1f movlw 31 andwf main__mask,w goto main__54 main__53: ; line_number = 200 ; while ledx != 0 start main__50: ; Left minus Right movf main__ledx,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true.size=0 && false.size>1 ; bit_code_emit_helper1: body_code.size=6 true_test=false body_code.delay=0 (non-uniform delay) btfsc __z___byte, __z___bit goto main__52 ; line_number = 201 ; mask := (mask << 1) | 1 main__51 equ shared___globals+34 rlf main__mask,w andlw 254 iorlw 1 movwf main__mask ; line_number = 202 ; ledx := ledx - 1 decf main__ledx,f goto main__50 main__52: ; Recombine size1 = 0 || size2 = 0 ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; line_number = 200 ; while ledx != 0 done ; line_number = 203 ; leds_mask_low := mask movf main__mask,w movwf leds_mask_low ; line_number = 204 ; leds_mask_high := 0 movlw 0 main__54: ; code.delay=4294967295 back_code.delay=4294967295 movwf leds_mask_high ; <=bit_code_emit@symbol; sym=__c (data:X0=>X0 code:XX=>XX) ; line_number = 199 ; if ledx <= 5 done main__61: ; switch end:(data:X0=>X? code:XX=>XX) ; line_number = 128 ; switch (command >> 4) & 3 done goto main__81 ; line_number = 212 ; case 3 main__78: ; # (Command = 11xx xxxx): ; line_number = 214 ; if (command >> 3) & 7 = 7 start ; Left minus Right main__73 equ shared___globals+34 rrf main__command,w movwf main__73 rrf main__73,f rrf main__73,w andlw 7 addlw 249 ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code.size = 0 && false_code.size > 1 ; bit_code_emit_helper1: body_code.size=21 true_test=true body_code.delay=0 (non-uniform delay) btfss __z___byte, __z___bit goto main__74 ; # Command = 1111 1xxx: ; line_number = 216 ; switch command & 7 start movlw main__71>>8 movwf __pclath movlw 7 andwf main__command,w addlw main__71 movwf __pcl ; page_group 8 main__71: goto main__63 goto main__64 goto main__65 goto main__66 goto main__67 goto main__68 goto main__69 goto main__70 ; line_number = 217 ; case 0 main__63: ; This case body wants this bit set bsf __rp0___byte, __rp0___bit ; # Clock Decrement (Command = 1111 1000): ; line_number = 219 ; _osccal := _osccal - _osccal_lsb movlw 252 addwf _osccal,f goto main__72 ; line_number = 220 ; case 1 main__64: ; This case body wants this bit set bsf __rp0___byte, __rp0___bit ; # Clock Increment (Command = 1111 1001): ; line_number = 222 ; _osccal := _osccal + _osccal_lsb movlw 4 addwf _osccal,f goto main__72 ; line_number = 223 ; case 2 main__65: ; This case body wants this bit set bsf __rp0___byte, __rp0___bit ; # Clock Read (Command = 1111 1010): ; line_number = 225 ; call byte_put(_osccal) movf _osccal,w bcf __rp0___byte, __rp0___bit call byte_put goto main__72 ; line_number = 226 ; case 3 main__66: ; # Clock Pulse (Command = 1111 1011): ; line_number = 228 ; call byte_put(0) movlw 0 call byte_put goto main__72 ; line_number = 229 ; case 4 main__67: ; # ID Next (Command = 1111 1100): ; line_number = 231 ; temp := 0 movlw 0 movwf main__temp ; line_number = 232 ; if index < id.size start movlw 47 subwf main__index,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true.size=0 && false.size>1 ; bit_code_emit_helper1: body_code.size=4 true_test=false body_code.delay=0 (non-uniform delay) btfsc __c___byte, __c___bit goto main__62 ; line_number = 233 ; temp := id[index] movf main__index,w call id movwf main__temp ; line_number = 234 ; index := index + 1 incf main__index,f main__62: ; Recombine size1 = 0 || size2 = 0 ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__c (data:X0=>X0 code:XX=>XX) ; line_number = 232 ; if index < id.size done ; line_number = 235 ; call byte_put(temp) movf main__temp,w call byte_put goto main__72 ; line_number = 236 ; case 5 main__68: ; # ID Reset (Command = 1111 1101): ; line_number = 238 ; index := 0 movlw 0 movwf main__index goto main__72 ; line_number = 239 ; case 6 main__69: ; # Glitch Read (Command = 1111 1110): ; line_number = 241 ; call byte_put(glitch) movf main__glitch,w call byte_put ; line_number = 242 ; glitch := 0 movlw 0 movwf main__glitch goto main__72 ; line_number = 243 ; case 7 main__70: ; # Glitch (Command = 1111 1111): ; line_number = 245 ; if glitch != 0xff start ; Left minus Right incf main__glitch,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code.size=0 && false_code.size=1 btfss __z___byte, __z___bit ; line_number = 246 ; glitch := glitch + 1 incf main__glitch,f ; Recombine size1 = 0 || size2 = 0 ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; line_number = 245 ; if glitch != 0xff done main__72: ; switch end:(data:X0=>X? code:XX=>XX) ; line_number = 216 ; switch command & 7 done ; Recombine size1 = 0 || size2 = 0 main__74: ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X? code:XX=>XX) ; line_number = 214 ; if (command >> 3) & 7 = 7 done main__81: ; switch end:(data:X0=>X? code:XX=>XX) ; line_number = 78 ; switch command >> 6 done ; line_number = 73 ; loop_forever wrap-up ; Need to adjust code banks to match front of loop bcf __rp0___byte, __rp0___bit goto main__3 ; line_number = 73 ; loop_forever done ; delay after procedure statements=non-uniform ; line_number = 249 ; procedure mask_to_bit mask_to_bit: ; Last argument is sitting in W; save into argument variable movwf mask_to_bit__mask ; delay=4294967295 ; line_number = 250 ; argument mask byte mask_to_bit__mask equ shared___globals+30 ; line_number = 251 ; returns byte ; line_number = 253 ; local bit byte mask_to_bit__bit equ shared___globals+29 ; before procedure statements delay=non-uniform, bit states=(data:X0=>X0 code:XX=>XX) ; line_number = 255 ; if mask = 0xff start ; Left minus Right incf mask_to_bit__mask,w ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: True.size=1 False.size=0 btfsc __z___byte, __z___bit ; line_number = 256 ; return 7 start ; line_number = 256 retlw 7 ; line_number = 256 ; return 7 done ; Recombine size1 = 0 || size2 = 0 ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=__z (data:XX=>XX code:XX=>XX) ; line_number = 255 ; if mask = 0xff done ; line_number = 257 ; bit := 0 movlw 0 movwf mask_to_bit__bit ; line_number = 258 ; mask := mask | 0x80 bsf mask_to_bit__mask, 7 ; line_number = 259 ; while !(mask@0) start mask_to_bit__1: mask_to_bit__select__2___byte equ mask_to_bit__mask mask_to_bit__select__2___bit equ 0 ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true.size=0 && false.size>1 ; bit_code_emit_helper1: body_code.size=4 true_test=false body_code.delay=0 (non-uniform delay) btfsc mask_to_bit__select__2___byte, mask_to_bit__select__2___bit goto mask_to_bit__3 ; line_number = 260 ; mask := mask >> 1 ; Assignment of variable to self (no code needed) rrf mask_to_bit__mask,f bcf mask_to_bit__mask, 7 ; line_number = 261 ; bit := bit + 1 incf mask_to_bit__bit,f goto mask_to_bit__1 mask_to_bit__3: ; Recombine size1 = 0 || size2 = 0 ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=mask_to_bit__select__2 (data:X0=>X0 code:XX=>XX) ; line_number = 259 ; while !(mask@0) done ; line_number = 262 ; return bit start ; line_number = 262 movf mask_to_bit__bit,w return ; line_number = 262 ; return bit done ; delay after procedure statements=non-uniform ; line_number = 265 ; procedure delay delay: ; arguments_none ; line_number = 267 ; returns_nothing ; line_number = 268 ; exact_delay delay_instructions ; # This procedure delays 1/3 of a bit. ; line_number = 272 ; local blink byte delay__blink equ shared___globals+31 ; line_number = 273 ; local high byte delay__high equ shared___globals+32 ; line_number = 274 ; local low byte delay__low equ shared___globals+33 ; # This procedure is called 7200 times a second. We want to ; # slow the fastest blink rate down to something more manageable, ; # like 4 times a second. ; # Kick the dog: ; before procedure statements delay=0, bit states=(data:X0=>X0 code:XX=>XX) ; line_number = 281 ; watch_dog_reset done ; Delay at watch_dog_reset is 0 clrwdt ; # Slow the blink rate down: ; line_number = 284 ; low := low + 1 ; Delay at assignment is 1 incf delay__low,f ; line_number = 285 ; if _z start ; Delay at if is 2 ; (after recombine) true_delay=13, false_delay=0 uniform_delay=true ; CASE: true_code.size = 0 && false_code.size > 1 ; bit_code_emit_helper1: body_code.size=15 true_test=true body_code.delay=13 (uniform delay) btfsc _z___byte, _z___bit goto delay__5 ; Delay 12 cycles ; Delay loop takes 3 * 4 = 12 cycles movlw 3 delay__7: addlw 255 btfss __z___byte, __z___bit goto delay__7 goto delay__6 delay__5: ; line_number = 286 ; high := high + 1 ; Delay at assignment is 0 incf delay__high,f ; # 7200/256 ~= 28; for fastest blink rate: ; # 28/7 = 4 => 4 blinks a second, or ; # 28/4 = 7 => 7 blinks a second ; line_number = 290 ; if high > 2 start ; Delay at if is 1 movlw 2 subwf delay__high,w btfsc __z___byte, __z___bit bcf __c___byte, __c___bit ; (after recombine) true_delay=5, false_delay=0 uniform_delay=true ; CASE: true_code.size = 0 && false_code.size > 1 ; bit_code_emit_helper1: body_code.size=5 true_test=true body_code.delay=5 (uniform delay) btfsc __c___byte, __c___bit goto delay__1 ; Delay 4 cycles goto delay__3 delay__3: goto delay__4 delay__4: goto delay__2 delay__1: ; line_number = 291 ; high := 0 ; Delay at assignment is 0 movlw 0 movwf delay__high ; line_number = 292 ; blink := blink + 1 ; Delay at assignment is 2 incf delay__blink,f ; # We never let the blink mask go to all zeros because the way ; # we indicate that an LED is to stay on always is that we set ; # its blink mask to all one's. If the blink variable ever goes ; # to all zeros, there would be a small glitch for LED's that ; # are supposed to be always on. Hence we skip over a value of 0. ; line_number = 299 ; if _z start ; Delay at if is 3 ; (after recombine) true_delay=1, false_delay=0 uniform_delay=true ; CASE: True.size=1 False.size=0 btfsc _z___byte, _z___bit ; line_number = 300 ; blink := blink + 1 ; Delay at assignment is 0 incf delay__blink,f ; code.delay=5 back_code.delay=0 ; <=bit_code_emit@symbol; sym=_z (data:X0=>X0 code:XX=>XX) ; if final true delay=1 false delay=0 code delay=5 ; line_number = 299 ; if _z done delay__2: ; code.delay=13 back_code.delay=0 ; <=bit_code_emit@symbol; sym=__c (data:X0=>X0 code:XX=>XX) ; Uniform delay broke in relation_code_emit ; if final true delay=5 false delay=0 code delay=13 ; line_number = 290 ; if high > 2 done delay__6: ; code.delay=18 back_code.delay=0 ; <=bit_code_emit@symbol; sym=_z (data:X0=>X0 code:XX=>XX) ; if final true delay=13 false delay=0 code delay=18 ; line_number = 285 ; if _z done ; line_number = 302 ; if leds_mask_low@0 start ; Delay at if is 18 delay__select__8___byte equ leds_mask_low delay__select__8___bit equ 0 ; (after recombine) true_delay=6, false_delay=1 uniform_delay=true ; CASE: true.size>1 false.size=1; no GOTO's btfss delay__select__8___byte, delay__select__8___bit goto delay__9 ; # led0 := 0 ; line_number = 304 ; if blink & blink_masks[0] != 0 start ; Delay at if is 0 ; Left minus Right movf blink_masks,w andwf delay__blink,w ; (after recombine) true_delay=1, false_delay=1 uniform_delay=true ; CASE: true_size=1 && false_size=1 ; SUBCASE: Double test; true, then false btfsc __z___byte, __z___bit ; line_number = 307 ; led0 := 1 ; Delay at assignment is 0 bsf led0___byte, led0___bit btfss __z___byte, __z___bit ; line_number = 305 ; led0 := 0 ; Delay at assignment is 0 bcf led0___byte, led0___bit ; code.delay=6 back_code.delay=0 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; Uniform delay broke in relation_code_emit ; if final true delay=1 false delay=1 code delay=6 ; line_number = 304 ; if blink & blink_masks[0] != 0 done goto delay__10 delay__9: ; line_number = 309 ; led0 := 1 ; Delay at assignment is 0 bsf led0___byte, led0___bit ; Delay 6 cycles goto delay__11 delay__11: goto delay__12 delay__12: goto delay__13 delay__13: delay__10: ; code.delay=28 back_code.delay=0 ; <=bit_code_emit@symbol; sym=delay__select__8 (data:X0=>X0 code:XX=>XX) ; if final true delay=6 false delay=1 code delay=28 ; line_number = 302 ; if leds_mask_low@0 done ; line_number = 311 ; if leds_mask_low@1 start ; Delay at if is 28 delay__select__14___byte equ leds_mask_low delay__select__14___bit equ 1 ; (after recombine) true_delay=6, false_delay=1 uniform_delay=true ; CASE: true.size>1 false.size=1; no GOTO's btfss delay__select__14___byte, delay__select__14___bit goto delay__15 ; line_number = 312 ; if blink & blink_masks[1] != 0 start ; Delay at if is 0 ; Left minus Right movf blink_masks+1,w andwf delay__blink,w ; (after recombine) true_delay=1, false_delay=1 uniform_delay=true ; CASE: true_size=1 && false_size=1 ; SUBCASE: Double test; true, then false btfsc __z___byte, __z___bit ; line_number = 315 ; led1 := 1 ; Delay at assignment is 0 bsf led1___byte, led1___bit btfss __z___byte, __z___bit ; line_number = 313 ; led1 := 0 ; Delay at assignment is 0 bcf led1___byte, led1___bit ; code.delay=6 back_code.delay=0 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; Uniform delay broke in relation_code_emit ; if final true delay=1 false delay=1 code delay=6 ; line_number = 312 ; if blink & blink_masks[1] != 0 done goto delay__16 delay__15: ; line_number = 317 ; led1 := 1 ; Delay at assignment is 0 bsf led1___byte, led1___bit ; Delay 6 cycles goto delay__17 delay__17: goto delay__18 delay__18: goto delay__19 delay__19: delay__16: ; code.delay=38 back_code.delay=0 ; <=bit_code_emit@symbol; sym=delay__select__14 (data:X0=>X0 code:XX=>XX) ; if final true delay=6 false delay=1 code delay=38 ; line_number = 311 ; if leds_mask_low@1 done ; line_number = 319 ; if leds_mask_low@2 start ; Delay at if is 38 delay__select__20___byte equ leds_mask_low delay__select__20___bit equ 2 ; (after recombine) true_delay=6, false_delay=1 uniform_delay=true ; CASE: true.size>1 false.size=1; no GOTO's btfss delay__select__20___byte, delay__select__20___bit goto delay__21 ; line_number = 320 ; if blink & blink_masks[2] != 0 start ; Delay at if is 0 ; Left minus Right movf blink_masks+2,w andwf delay__blink,w ; (after recombine) true_delay=1, false_delay=1 uniform_delay=true ; CASE: true_size=1 && false_size=1 ; SUBCASE: Double test; true, then false btfsc __z___byte, __z___bit ; line_number = 323 ; led2 := 1 ; Delay at assignment is 0 bsf led2___byte, led2___bit btfss __z___byte, __z___bit ; line_number = 321 ; led2 := 0 ; Delay at assignment is 0 bcf led2___byte, led2___bit ; code.delay=6 back_code.delay=0 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; Uniform delay broke in relation_code_emit ; if final true delay=1 false delay=1 code delay=6 ; line_number = 320 ; if blink & blink_masks[2] != 0 done goto delay__22 delay__21: ; line_number = 325 ; led2 := 1 ; Delay at assignment is 0 bsf led2___byte, led2___bit ; Delay 6 cycles goto delay__23 delay__23: goto delay__24 delay__24: goto delay__25 delay__25: delay__22: ; code.delay=48 back_code.delay=0 ; <=bit_code_emit@symbol; sym=delay__select__20 (data:X0=>X0 code:XX=>XX) ; if final true delay=6 false delay=1 code delay=48 ; line_number = 319 ; if leds_mask_low@2 done ; line_number = 327 ; if leds_mask_low@3 start ; Delay at if is 48 delay__select__26___byte equ leds_mask_low delay__select__26___bit equ 3 ; (after recombine) true_delay=6, false_delay=1 uniform_delay=true ; CASE: true.size>1 false.size=1; no GOTO's btfss delay__select__26___byte, delay__select__26___bit goto delay__27 ; line_number = 328 ; if blink & blink_masks[3] != 0 start ; Delay at if is 0 ; Left minus Right movf blink_masks+3,w andwf delay__blink,w ; (after recombine) true_delay=1, false_delay=1 uniform_delay=true ; CASE: true_size=1 && false_size=1 ; SUBCASE: Double test; true, then false btfsc __z___byte, __z___bit ; line_number = 331 ; led3 := 1 ; Delay at assignment is 0 bsf led3___byte, led3___bit btfss __z___byte, __z___bit ; line_number = 329 ; led3 := 0 ; Delay at assignment is 0 bcf led3___byte, led3___bit ; code.delay=6 back_code.delay=0 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; Uniform delay broke in relation_code_emit ; if final true delay=1 false delay=1 code delay=6 ; line_number = 328 ; if blink & blink_masks[3] != 0 done goto delay__28 delay__27: ; line_number = 333 ; led3 := 1 ; Delay at assignment is 0 bsf led3___byte, led3___bit ; Delay 6 cycles goto delay__29 delay__29: goto delay__30 delay__30: goto delay__31 delay__31: delay__28: ; code.delay=58 back_code.delay=0 ; <=bit_code_emit@symbol; sym=delay__select__26 (data:X0=>X0 code:XX=>XX) ; if final true delay=6 false delay=1 code delay=58 ; line_number = 327 ; if leds_mask_low@3 done ; line_number = 335 ; if leds_mask_low@4 start ; Delay at if is 58 delay__select__32___byte equ leds_mask_low delay__select__32___bit equ 4 ; (after recombine) true_delay=6, false_delay=1 uniform_delay=true ; CASE: true.size>1 false.size=1; no GOTO's btfss delay__select__32___byte, delay__select__32___bit goto delay__33 ; line_number = 336 ; if blink & blink_masks[4] != 0 start ; Delay at if is 0 ; Left minus Right movf blink_masks+4,w andwf delay__blink,w ; (after recombine) true_delay=1, false_delay=1 uniform_delay=true ; CASE: true_size=1 && false_size=1 ; SUBCASE: Double test; true, then false btfsc __z___byte, __z___bit ; line_number = 339 ; led4 := 1 ; Delay at assignment is 0 bsf led4___byte, led4___bit btfss __z___byte, __z___bit ; line_number = 337 ; led4 := 0 ; Delay at assignment is 0 bcf led4___byte, led4___bit ; code.delay=6 back_code.delay=0 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; Uniform delay broke in relation_code_emit ; if final true delay=1 false delay=1 code delay=6 ; line_number = 336 ; if blink & blink_masks[4] != 0 done goto delay__34 delay__33: ; line_number = 341 ; led4 := 1 ; Delay at assignment is 0 bsf led4___byte, led4___bit ; Delay 6 cycles goto delay__35 delay__35: goto delay__36 delay__36: goto delay__37 delay__37: delay__34: ; code.delay=68 back_code.delay=0 ; <=bit_code_emit@symbol; sym=delay__select__32 (data:X0=>X0 code:XX=>XX) ; if final true delay=6 false delay=1 code delay=68 ; line_number = 335 ; if leds_mask_low@4 done ; line_number = 343 ; if leds_mask_high@0 start ; Delay at if is 68 delay__select__38___byte equ leds_mask_high delay__select__38___bit equ 0 ; (after recombine) true_delay=6, false_delay=1 uniform_delay=true ; CASE: true.size>1 false.size=1; no GOTO's btfss delay__select__38___byte, delay__select__38___bit goto delay__39 ; line_number = 344 ; if blink & blink_masks[5] != 0 start ; Delay at if is 0 ; Left minus Right movf blink_masks+5,w andwf delay__blink,w ; (after recombine) true_delay=1, false_delay=1 uniform_delay=true ; CASE: true_size=1 && false_size=1 ; SUBCASE: Double test; true, then false btfsc __z___byte, __z___bit ; line_number = 347 ; led5 := 1 ; Delay at assignment is 0 bsf led5___byte, led5___bit btfss __z___byte, __z___bit ; line_number = 345 ; led5 := 0 ; Delay at assignment is 0 bcf led5___byte, led5___bit ; code.delay=6 back_code.delay=0 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; Uniform delay broke in relation_code_emit ; if final true delay=1 false delay=1 code delay=6 ; line_number = 344 ; if blink & blink_masks[5] != 0 done goto delay__40 delay__39: ; line_number = 349 ; led5 := 1 ; Delay at assignment is 0 bsf led5___byte, led5___bit ; Delay 6 cycles goto delay__41 delay__41: goto delay__42 delay__42: goto delay__43 delay__43: delay__40: ; code.delay=78 back_code.delay=0 ; <=bit_code_emit@symbol; sym=delay__select__38 (data:X0=>X0 code:XX=>XX) ; if final true delay=6 false delay=1 code delay=78 ; line_number = 343 ; if leds_mask_high@0 done ; line_number = 351 ; if leds_mask_high@1 start ; Delay at if is 78 delay__select__44___byte equ leds_mask_high delay__select__44___bit equ 1 ; (after recombine) true_delay=6, false_delay=1 uniform_delay=true ; CASE: true.size>1 false.size=1; no GOTO's btfss delay__select__44___byte, delay__select__44___bit goto delay__45 ; line_number = 352 ; if blink & blink_masks[6] != 0 start ; Delay at if is 0 ; Left minus Right movf blink_masks+6,w andwf delay__blink,w ; (after recombine) true_delay=1, false_delay=1 uniform_delay=true ; CASE: true_size=1 && false_size=1 ; SUBCASE: Double test; true, then false btfsc __z___byte, __z___bit ; line_number = 355 ; led6 := 1 ; Delay at assignment is 0 bsf led6___byte, led6___bit btfss __z___byte, __z___bit ; line_number = 353 ; led6 := 0 ; Delay at assignment is 0 bcf led6___byte, led6___bit ; code.delay=6 back_code.delay=0 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; Uniform delay broke in relation_code_emit ; if final true delay=1 false delay=1 code delay=6 ; line_number = 352 ; if blink & blink_masks[6] != 0 done goto delay__46 delay__45: ; line_number = 357 ; led6 := 1 ; Delay at assignment is 0 bsf led6___byte, led6___bit ; Delay 6 cycles goto delay__47 delay__47: goto delay__48 delay__48: goto delay__49 delay__49: delay__46: ; code.delay=88 back_code.delay=0 ; <=bit_code_emit@symbol; sym=delay__select__44 (data:X0=>X0 code:XX=>XX) ; if final true delay=6 false delay=1 code delay=88 ; line_number = 351 ; if leds_mask_high@1 done ; line_number = 359 ; if leds_mask_high@2 start ; Delay at if is 88 delay__select__50___byte equ leds_mask_high delay__select__50___bit equ 2 ; (after recombine) true_delay=6, false_delay=1 uniform_delay=true ; CASE: true.size>1 false.size=1; no GOTO's btfss delay__select__50___byte, delay__select__50___bit goto delay__51 ; line_number = 360 ; if blink & blink_masks[7] != 0 start ; Delay at if is 0 ; Left minus Right movf blink_masks+7,w andwf delay__blink,w ; (after recombine) true_delay=1, false_delay=1 uniform_delay=true ; CASE: true_size=1 && false_size=1 ; SUBCASE: Double test; true, then false btfsc __z___byte, __z___bit ; line_number = 363 ; led7 := 1 ; Delay at assignment is 0 bsf led7___byte, led7___bit btfss __z___byte, __z___bit ; line_number = 361 ; led7 := 0 ; Delay at assignment is 0 bcf led7___byte, led7___bit ; code.delay=6 back_code.delay=0 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; Uniform delay broke in relation_code_emit ; if final true delay=1 false delay=1 code delay=6 ; line_number = 360 ; if blink & blink_masks[7] != 0 done goto delay__52 delay__51: ; line_number = 365 ; led7 := 1 ; Delay at assignment is 0 bsf led7___byte, led7___bit ; Delay 6 cycles goto delay__53 delay__53: goto delay__54 delay__54: goto delay__55 delay__55: delay__52: ; code.delay=98 back_code.delay=0 ; <=bit_code_emit@symbol; sym=delay__select__50 (data:X0=>X0 code:XX=>XX) ; if final true delay=6 false delay=1 code delay=98 ; line_number = 359 ; if leds_mask_high@2 done ; line_number = 367 ; if leds_mask_high@3 start ; Delay at if is 98 delay__select__56___byte equ leds_mask_high delay__select__56___bit equ 3 ; (after recombine) true_delay=6, false_delay=1 uniform_delay=true ; CASE: true.size>1 false.size=1; no GOTO's btfss delay__select__56___byte, delay__select__56___bit goto delay__57 ; line_number = 368 ; if blink & blink_masks[8] != 0 start ; Delay at if is 0 ; Left minus Right movf blink_masks+8,w andwf delay__blink,w ; (after recombine) true_delay=1, false_delay=1 uniform_delay=true ; CASE: true_size=1 && false_size=1 ; SUBCASE: Double test; true, then false btfsc __z___byte, __z___bit ; line_number = 371 ; led8 := 1 ; Delay at assignment is 0 bsf led8___byte, led8___bit btfss __z___byte, __z___bit ; line_number = 369 ; led8 := 0 ; Delay at assignment is 0 bcf led8___byte, led8___bit ; code.delay=6 back_code.delay=0 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; Uniform delay broke in relation_code_emit ; if final true delay=1 false delay=1 code delay=6 ; line_number = 368 ; if blink & blink_masks[8] != 0 done goto delay__58 delay__57: ; line_number = 373 ; led8 := 1 ; Delay at assignment is 0 bsf led8___byte, led8___bit ; Delay 6 cycles goto delay__59 delay__59: goto delay__60 delay__60: goto delay__61 delay__61: delay__58: ; code.delay=108 back_code.delay=0 ; <=bit_code_emit@symbol; sym=delay__select__56 (data:X0=>X0 code:XX=>XX) ; if final true delay=6 false delay=1 code delay=108 ; line_number = 367 ; if leds_mask_high@3 done ; line_number = 375 ; if leds_mask_high@4 start ; Delay at if is 108 delay__select__62___byte equ leds_mask_high delay__select__62___bit equ 4 ; (after recombine) true_delay=6, false_delay=1 uniform_delay=true ; CASE: true.size>1 false.size=1; no GOTO's btfss delay__select__62___byte, delay__select__62___bit goto delay__63 ; line_number = 376 ; if blink & blink_masks[9] != 0 start ; Delay at if is 0 ; Left minus Right movf blink_masks+9,w andwf delay__blink,w ; (after recombine) true_delay=1, false_delay=1 uniform_delay=true ; CASE: true_size=1 && false_size=1 ; SUBCASE: Double test; true, then false btfsc __z___byte, __z___bit ; line_number = 379 ; led9 := 1 ; Delay at assignment is 0 bsf led9___byte, led9___bit btfss __z___byte, __z___bit ; line_number = 377 ; led9 := 0 ; Delay at assignment is 0 bcf led9___byte, led9___bit ; code.delay=6 back_code.delay=0 ; <=bit_code_emit@symbol; sym=__z (data:X0=>X0 code:XX=>XX) ; Uniform delay broke in relation_code_emit ; if final true delay=1 false delay=1 code delay=6 ; line_number = 376 ; if blink & blink_masks[9] != 0 done goto delay__64 delay__63: ; line_number = 381 ; led9 := 1 ; Delay at assignment is 0 bsf led9___byte, led9___bit ; Delay 6 cycles goto delay__65 delay__65: goto delay__66 delay__66: goto delay__67 delay__67: delay__64: ; code.delay=118 back_code.delay=0 ; <=bit_code_emit@symbol; sym=delay__select__62 (data:X0=>X0 code:XX=>XX) ; if final true delay=6 false delay=1 code delay=118 ; line_number = 375 ; if leds_mask_high@4 done ; delay after procedure statements=118 ; Delay 13 cycles ; Delay loop takes 3 * 4 = 12 cycles movlw 3 delay__68: addlw 255 btfss __z___byte, __z___bit goto delay__68 nop ; Implied return retlw 0 ; Final delay = 133 ; line_number = 384 ; constant zero8 = "\0,0,0,0,0,0,0,0\" ; zero8 = '\0,0,0,0,0,0,0,0\' ; line_number = 385 ; constant module_name = "\6\LED10E" ; module_name = '\6\LED10E' ; line_number = 386 ; constant vendor_name = "\15\Gramlich&Benson" ; vendor_name = '\15\Gramlich&Benson' ; line_number = 388 ; string id = "\1,0,9,0,0,0,0,0\" ~ zero8 ~ zero8 ~ module_name ~ vendor_name start ; id = '\1,0,9,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,6\LED10E\15\Gramlich&Benson' id: ; Temporarily save index into FSR movwf __fsr ; Initialize PCLATH to point to this code page movlw id___base>>8 movwf __pclath ; Restore index from FSR movf __fsr,w addlw id___base ; Index to the correct return value movwf __pcl ; page_group 47 id___base: retlw 1 retlw 0 retlw 9 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 0 retlw 6 retlw 76 retlw 69 retlw 68 retlw 49 retlw 48 retlw 69 retlw 15 retlw 71 retlw 114 retlw 97 retlw 109 retlw 108 retlw 105 retlw 99 retlw 104 retlw 38 retlw 66 retlw 101 retlw 110 retlw 115 retlw 111 retlw 110 ; line_number = 388 ; string id = "\1,0,9,0,0,0,0,0\" ~ zero8 ~ zero8 ~ module_name ~ vendor_name start ; line_number = 390 ; string bit_to_mask = "\255,64,32,16,8,4,2,1\" start ; bit_to_mask = '\255\@ \16,8,4,2,1\' bit_to_mask: ; Temporarily save index into FSR movwf __fsr ; Initialize PCLATH to point to this code page movlw bit_to_mask___base>>8 movwf __pclath ; Restore index from FSR movf __fsr,w addlw bit_to_mask___base ; Index to the correct return value movwf __pcl ; page_group 8 bit_to_mask___base: retlw 255 retlw 64 retlw 32 retlw 16 retlw 8 retlw 4 retlw 2 retlw 1 ; line_number = 390 ; string bit_to_mask = "\255,64,32,16,8,4,2,1\" start ; Appending 2 delayed procedures to code bank 0 ; buffer = 'bit_bang' ; line_number = 33 ; procedure byte_get byte_get: ; arguments_none ; line_number = 35 ; returns byte ; # This procedure will wait for a byte to be received from ; # serial_in_bit. It calls the delay procedure for all delays. ; # This procedure will keep calling the {delay} routine until ; # data is received. ; line_number = 42 ; local count byte byte_get__count equ shared___globals ; line_number = 43 ; local byte byte byte_get__byte equ shared___globals+1 ; # Why does the delay procedure wait for a third of bit? Well, it ; # has to do with the loop immediately below. If we catch the ; # start bit at the beginning of a 1/3 bit time, we will be ; # sampling data at approximately 1/3 of the way into each bit. ; # Conversely, if we catch the start near the end of a 1/3 bit ; # bit time, we will be sampling data at approximately 2/3 of the ; # way into each bit. So, what this means is that our bit sample ; # times will be somewhere between 1/3 and 2/3 of bit (i.e. in ; # the middle of the bit. ; # It would be nice to tweak the code to shorter delay times ; # (1/4 bit, 1/5 bit, etc.) but then it gets too hard to get ; # the bookeeping done in the delay routine. A PIC running at ; # 4MHz (=1MIPS), only has 138 instructions available for the ; # delay routine when at 1/3 of bit. ; # Wait for a start bit: ; before procedure statements delay=non-uniform, bit states=(data:X0=>X0 code:XX=>XX) ; line_number = 62 ; waiting := 1 bsf waiting___byte, waiting___bit ; line_number = 63 ; receiving := 1 bsf receiving___byte, receiving___bit ; line_number = 64 ; while serial_in start byte_get__1: ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code.size = 0 && false_code.size > 1 ; bit_code_emit_helper1: body_code.size=2 true_test=true body_code.delay=0 (non-uniform delay) btfss serial_in___byte, serial_in___bit goto byte_get__2 ; line_number = 65 ; delay instructions_per_delay - 3 start ; Delay expression evaluates to 135 ; line_number = 66 ; call delay() ; Delay at call is 0 call delay ; line_number = 65 ; delay instructions_per_delay - 3 done goto byte_get__1 ; Recombine size1 = 0 || size2 = 0 byte_get__2: ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=serial_in (data:X0=>X0 code:XX=>XX) ; line_number = 64 ; while serial_in done ; line_number = 67 ; waiting := 0 bcf waiting___byte, waiting___bit ; # Clear out any preceeding interrupt condition: ; line_number = 70 ; serial_out := 1 bsf serial_out___byte, serial_out___bit ; # Skip over start bit: ; line_number = 73 ; delay instructions_per_bit - 2 start ; Delay expression evaluates to 414 ; # There are two instructions of set-up for following loop_exactly: ; line_number = 75 ; call delay() ; Delay at call is 0 call delay ; line_number = 76 ; call delay() ; Delay at call is 135 call delay ; line_number = 77 ; call delay() ; Delay at call is 270 call delay ; line_number = 78 ; byte := 0 ; Delay at assignment is 405 movlw 0 movwf byte_get__byte ; Delay 7 cycles goto byte_get__3 byte_get__3: goto byte_get__4 byte_get__4: goto byte_get__5 byte_get__5: nop ; line_number = 73 ; delay instructions_per_bit - 2 done ; # Read in 8 bits of data: ; line_number = 81 ; loop_exactly 8 start byte_get__6 equ shared___globals+36 movlw 8 movwf byte_get__6 byte_get__7: ; # There are 3 instrucitons of loop_exactly overhead: ; line_number = 83 ; delay instructions_per_bit - 3 start ; Delay expression evaluates to 413 ; line_number = 84 ; call delay() ; Delay at call is 0 call delay ; line_number = 85 ; byte := byte >> 1 ; Delay at assignment is 135 ; Assignment of variable to self (no code needed) rrf byte_get__byte,f bcf byte_get__byte, 7 ; line_number = 86 ; if serial_in start ; Delay at if is 137 ; (after recombine) true_delay=1, false_delay=0 uniform_delay=true ; CASE: True.size=1 False.size=0 btfsc serial_in___byte, serial_in___bit ; line_number = 87 ; byte@7 := 1 ; Delay at assignment is 0 byte_get__select__8___byte equ byte_get__byte byte_get__select__8___bit equ 7 bsf byte_get__select__8___byte, byte_get__select__8___bit ; code.delay=139 back_code.delay=0 ; <=bit_code_emit@symbol; sym=serial_in (data:X0=>X0 code:XX=>XX) ; if final true delay=1 false delay=0 code delay=139 ; line_number = 86 ; if serial_in done ; line_number = 88 ; call delay() ; Delay at call is 139 call delay ; line_number = 89 ; call delay() ; Delay at call is 274 call delay ; Delay 4 cycles goto byte_get__9 byte_get__9: goto byte_get__10 byte_get__10: ; line_number = 83 ; delay instructions_per_bit - 3 done ; line_number = 81 ; loop_exactly 8 wrap-up decfsz byte_get__6,f goto byte_get__7 ; line_number = 81 ; loop_exactly 8 done ; # Skip over 2/3's of stop bit; 3 cycles for return: ; line_number = 92 ; delay instructions_per_delay*2 - 3 start ; Delay expression evaluates to 273 ; line_number = 93 ; call delay() ; Delay at call is 0 call delay ; line_number = 94 ; call delay() ; Delay at call is 135 call delay ; Delay 3 cycles goto byte_get__11 byte_get__11: nop ; line_number = 92 ; delay instructions_per_delay*2 - 3 done ; line_number = 95 ; command_previous := command_last movf command_last,w movwf command_previous ; line_number = 96 ; command_last := byte movf byte_get__byte,w movwf command_last ; line_number = 97 ; serial_out := 1 bsf serial_out___byte, serial_out___bit ; line_number = 98 ; return byte start ; line_number = 98 movf byte_get__byte,w return ; line_number = 98 ; return byte done ; delay after procedure statements=non-uniform ; line_number = 101 ; procedure byte_put byte_put: ; Last argument is sitting in W; save into argument variable movwf byte_put__byte ; delay=4294967295 ; line_number = 102 ; argument byte byte byte_put__byte equ shared___globals+3 ; line_number = 103 ; returns_nothing ; # This procedure will send {byte} to {serial_out} pin. The {delay} ; # procedure is called to provide the appropriate bit timing. ; line_number = 108 ; local count byte byte_put__count equ shared___globals+2 ; # {receiving} will be 1 if the last get/put routine was a get. ; # Before we start transmitting a response back, we want to ensure ; # that there has been enough time to turn the line around. ; # We delay the first 1/3 of a bit to pad out the 9-2/3 bits ; # from get_byte to 10 bits. We delay another 3 bits just to ; # ensure that slow interpreters do not get overrun. ; before procedure statements delay=non-uniform, bit states=(data:X0=>X0 code:XX=>XX) ; line_number = 116 ; sent_previous := sent_last movf sent_last,w movwf sent_previous ; line_number = 117 ; sent_last := byte movf byte_put__byte,w movwf sent_last ; line_number = 118 ; if receiving start ; (after recombine) true_delay=non-uniform, false_delay=non-uniform ; CASE: true_code.size = 0 && false_code.size > 1 ; bit_code_emit_helper1: body_code.size=4 true_test=true body_code.delay=0 (non-uniform delay) btfss receiving___byte, receiving___bit goto byte_put__3 ; line_number = 119 ; receiving := 0 bcf receiving___byte, receiving___bit ; # 10 = 1 + 3*3 = 3-1/3 extra bits of delay: ; line_number = 121 ; loop_exactly 10 start byte_put__1 equ shared___globals+37 movlw 10 movwf byte_put__1 byte_put__2: ; line_number = 122 ; call delay() call delay ; line_number = 121 ; loop_exactly 10 wrap-up decfsz byte_put__1,f goto byte_put__2 ; line_number = 121 ; loop_exactly 10 done ; Recombine size1 = 0 || size2 = 0 byte_put__3: ; code.delay=4294967295 back_code.delay=4294967295 ; <=bit_code_emit@symbol; sym=receiving (data:X0=>X0 code:XX=>XX) ; line_number = 118 ; if receiving done ; # Send the start bit: ; line_number = 125 ; delay instructions_per_bit - 2 start ; Delay expression evaluates to 414 ; # The loop_exactly setup after this is 2 instructions: ; line_number = 127 ; serial_out := 0 ; Delay at assignment is 0 bcf serial_out___byte, serial_out___bit ; line_number = 128 ; call delay() ; Delay at call is 1 call delay ; line_number = 129 ; call delay() ; Delay at call is 136 call delay ; line_number = 130 ; call delay() ; Delay at call is 271 call delay ; Delay 8 cycles ; Delay loop takes 2 * 4 = 8 cycles movlw 2 byte_put__4: addlw 255 btfss __z___byte, __z___bit goto byte_put__4 ; line_number = 125 ; delay instructions_per_bit - 2 done ; # Send the data: ; line_number = 133 ; loop_exactly 8 start byte_put__5 equ shared___globals+37 movlw 8 movwf byte_put__5 byte_put__6: ; # Loop_exactly overhead is 3 instructions: ; line_number = 135 ; delay instructions_per_bit - 3 start ; Delay expression evaluates to 413 ; line_number = 136 ; if byte@0 start ; Delay at if is 0 byte_put__select__7___byte equ byte_put__byte byte_put__select__7___bit equ 0 ; (after recombine) true_delay=1, false_delay=1 uniform_delay=true ; CASE: true_size=1 && false_size=1 ; SUBCASE: Double test; true, then false btfsc byte_put__select__7___byte, byte_put__select__7___bit ; line_number = 137 ; serial_out := 1 ; Delay at assignment is 0 bsf serial_out___byte, serial_out___bit btfss byte_put__select__7___byte, byte_put__select__7___bit ; line_number = 139 ; serial_out := 0 ; Delay at assignment is 0 bcf serial_out___byte, serial_out___bit ; code.delay=4 back_code.delay=0 ; <=bit_code_emit@symbol; sym=byte_put__select__7 (data:X0=>X0 code:XX=>XX) ; if final true delay=1 false delay=1 code delay=4 ; line_number = 136 ; if byte@0 done ; line_number = 140 ; byte := byte >> 1 ; Delay at assignment is 4 ; Assignment of variable to self (no code needed) rrf byte_put__byte,f bcf byte_put__byte, 7 ; line_number = 141 ; call delay() ; Delay at call is 6 call delay ; line_number = 142 ; call delay() ; Delay at call is 141 call delay ; line_number = 143 ; call delay() ; Delay at call is 276 call delay ; Delay 2 cycles goto byte_put__8 byte_put__8: ; line_number = 135 ; delay instructions_per_bit - 3 done ; line_number = 133 ; loop_exactly 8 wrap-up decfsz byte_put__5,f goto byte_put__6 ; line_number = 133 ; loop_exactly 8 done ; # Send the stop bit: ; line_number = 146 ; delay instructions_per_bit start ; Delay expression evaluates to 416 ; line_number = 147 ; serial_out := 1 ; Delay at assignment is 0 bsf serial_out___byte, serial_out___bit ; line_number = 148 ; call delay() ; Delay at call is 1 call delay ; line_number = 149 ; call delay() ; Delay at call is 136 call delay ; line_number = 150 ; call delay() ; Delay at call is 271 call delay ; Delay 10 cycles ; Delay loop takes 2 * 4 = 8 cycles movlw 2 byte_put__9: addlw 255 btfss __z___byte, __z___bit goto byte_put__9 goto byte_put__10 byte_put__10: ; line_number = 146 ; delay instructions_per_bit done ; delay after procedure statements=non-uniform ; Implied return retlw 0 ; Configuration bits ; fill = 0x0 ; bg = bg11 (0x3000) ; cpd = off (0x100) ; cp = off (0x80) ; boden = off (0x0) ; mclre = off (0x0) ; pwrte = off (0x10) ; wdte = off (0x0) ; fosc = int_no_clk (0x4) ; 12692 = 0x3194 __config 12692 ; Define start addresses for data regions ; Region="shared___globals" Address=32" Size=64 Bytes=38 Bits=2 Available=25 ; Region="shared___globals" Address=32" Size=64 Bytes=38 Bits=2 Available=25 ; Region="shared___globals" Address=32" Size=64 Bytes=38 Bits=2 Available=25 end