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[/] [open8_urisc/] [trunk/] [taskmgr/] [sys_const.s] - Blame information for rev 334

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1 301 jshamlet
; Copyright (c)2022 Jeremy Seth Henry
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; All rights reserved.
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;
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; Redistribution and use in source and binary forms, with or without
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; modification, are permitted provided that the following conditions are met:
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;     * Redistributions of source code must retain the above copyright
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;       notice, this list of conditions and the following disclaimer.
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;     * Redistributions in binary form must reproduce the above copyright
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;       notice, this list of conditions and the following disclaimer in the
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;       documentation and/or other materials provided with the distribution,
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;       where applicable (as part of a user interface, debugging port, etc.)
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;
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; THIS SOFTWARE IS PROVIDED BY JEREMY SETH HENRY ``AS IS'' AND ANY
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; EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
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; WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
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; DISCLAIMED. IN NO EVENT SHALL JEREMY SETH HENRY BE LIABLE FOR ANY
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; DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
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; (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
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; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
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; ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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; (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
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; THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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;
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;------------------------------------------------------------------------------
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; sys_const.s
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;
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; Common constants & macros for generic hardware or structures used by several
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;  tasks
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;
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; Revision History
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; Author          Date     Change
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;---------------- -------- ---------------------------------------------------
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; Seth Henry      7/15/22  Initial Release
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;------------------------------------------------------------------------------
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;------------------------------------------------------------------------------
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;-- Serial Port Constants & Macros
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;------------------------------------------------------------------------------
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.DEFINE UART_DATA            0
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.DEFINE UART_STATUS          1
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.DEFINE UART_RX_PERR         3
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.DEFINE UART_RX_EMPTY        4
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.DEFINE UART_RX_FULL         5
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.DEFINE UART_TX_EMPTY        6
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.DEFINE UART_TX_FULL         7
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.DEFINE UART_RX_PERR_BIT     2^UART_RX_PERR
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.DEFINE UART_RX_PERR_MASK    UART_RX_PERR_BIT ~ $FF
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.DEFINE UART_RX_EMPTY_BIT    2^UART_RX_EMPTY
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.DEFINE UART_RX_EMPTY_MASK   UART_RX_EMPTY_BIT ~ $FF
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.DEFINE UART_RX_FULL_BIT     2^UART_RX_FULL
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.DEFINE UART_RX_FULL_MASK    UART_RX_FULL_BIT ~ $FF
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.DEFINE UART_TX_EMPTY_BIT    2^UART_TX_EMPTY
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.DEFINE UART_TX_EMPTY_MASK   UART_TX_EMPTY_BIT ~ $FF
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.DEFINE UART_TX_FULL_BIT     2^UART_TX_FULL
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.DEFINE UART_TX_FULL_MASK    UART_TX_FULL_BIT ~ $FF
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; Checking the UART flags involves testing bits in the status register
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;  The assembler isn't bright enough to use the defined constant, so this macro
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;  does the test on the correct bit
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.MACRO CHECK_UART_RX_PERR
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              BTT  3
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.ENDM
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.MACRO CHECK_UART_RX_EMPTY
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              BTT  4
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.ENDM
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.MACRO CHECK_UART_RX_FULL
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              BTT  5
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.ENDM
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.MACRO CHECK_UART_TX_EMPTY
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              BTT  6
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.ENDM
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.MACRO CHECK_UART_TX_FULL
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              BTT  7
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.ENDM
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; Register Map:
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; Offset  Bitfield Description                        Read/Write
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;   0x00  AAAAAAAA TX Data (WR) RX Data (RD)             (RW)
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;   0x01  EDCBA--- FIFO Status                           (RO*)
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;                  A: RX Parity Error (write to clear)
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;                  B: RX FIFO Empty
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;                  C: RX FIFO almost full (922/1024)
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;                  D: TX FIFO Empty
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;                  E: TX FIFO almost full (922/1024)
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;
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;------------------------------------------------------------------------------
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;------------------------------------------------------------------------------
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; Macros for setting the return value in Cmd_Error
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;------------------------------------------------------------------------------
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.DEFINE RX_CERR              $FB
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.DEFINE RX_TERR              $FC
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.DEFINE RX_LERR              $FD
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.DEFINE RX_PERR              $FE
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.DEFINE RX_OKAY              $FF
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.MACRO RETURN_RX_CMD_OKAY
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              LDI  R0, #RX_OKAY
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.ENDM
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.MACRO RETURN_RX_CMD_ERROR
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              LDI  R0, #RX_CERR
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.ENDM
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.MACRO RETURN_RX_TIMEOUT_ERROR
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              LDI  R0, #RX_TERR
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.ENDM
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.MACRO RETURN_RX_LENGTH_ERROR
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              LDI  R0, #RX_LERR
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.ENDM
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.MACRO RETURN_RX_PARITY_ERROR
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              LDI  R0, #RX_PERR
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.ENDM
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;------------------------------------------------------------------------------
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;------------------------------------------------------------------------------
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; Common buffer/memory copy
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; Uses R3:R2 as source, R5:R4 as destination, and R1 as the counter variable
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;------------------------------------------------------------------------------
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.MACRO MEM_COPY
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__MEM_CP_LP\@:LDX  R2++
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              STX  R4++
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              DBNZ R1, __MEM_CP_LP\@
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.ENDM
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;------------------------------------------------------------------------------
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;------------------------------------------------------------------------------
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; Common buffer/memory fill/flush
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; Uses R5:R4 as destination, and R1 as the counter variable
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;------------------------------------------------------------------------------
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.MACRO MEM_FILL
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__MEM_FL_LP\@:STX  R4++
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              DBNZ R1, __MEM_FL_LP\@
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.ENDM
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.MACRO MEM_FLUSH
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              CLR  R0
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              MEM_FILL
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.ENDM
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;------------------------------------------------------------------------------
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;------------------------------------------------------------------------------
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; Compute 16-bit Checksum
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;
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; Uses R3:R2 as source, R5:R4 as destination, and R1 as the counter variable
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; Adds all of the memory locations specified to a 16-bit accumulator, returning
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;  the result in R5:R4 (destination)
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;------------------------------------------------------------------------------
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.MACRO CALC_CHECKSUM16
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              CLR  R0
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              T0X  R4                   ; Initialize accumulator R5:R0 to 0
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              T0X  R5
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              T0X  R7                   ; Initialize R7 to 0
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__CHK_SM_LP\@:LDX  R2++
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              ADD  R4
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              T0X  R4
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              TX0  R5
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              ADC  R7
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              T0X  R5
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              DBNZ R1, __CHK_SM_LP\@
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.ENDM
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; These macros assume that the pointer in R3:R2 has been left pointing to the
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;  end of the receive buffer by the CALC_CHECKSUM16 macro. Do NOT repoint
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; R3:R2, and be sure to use these macros in the order that the checksum bytes
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;  appear in the packet. (THESE ARE ORDER DEPENDENT)
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.MACRO CHECK_SUM_LB
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              LDX  R2++
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              XOR  R4
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.ENDM
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.MACRO CHECK_SUM_UB
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              LDX  R2++
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              XOR  R5
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.ENDM
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;------------------------------------------------------------------------------
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;------------------------------------------------------------------------------
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; Convert ASCII to HEX
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;
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; Converts an ASCII value into an integer value from 0x0 to 0xF
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; Assumes incoming data is in R0. Returns a value in R0
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; Returns a value of 0x00 to 0x0F for valid characters, or
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; 0xFF (-1) for invalid characters
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;------------------------------------------------------------------------------
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.MACRO CONVERT_ASC2HEX
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              PSH  R1       ; Preserve R1 and R2
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              PSH  R2
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              T0X  R2       ; Make a copy of R0 to R2 for backup
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              LDI  R1, #$F0 ; Mask off the lower bits to figure out the range
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              AND  R1
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              T0X  R1       ; Copy the upper 4-bits to R1 for branching tests
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              LDI  R0, #$30 ; Is it a decimal char 0-9?
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              XOR  R1
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              BRZ  _CNV_AH_09_\@
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              LDI  R0, #$40 ; Is it a hex char A-F?
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              XOR  R1
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              BRZ  _CNV_AH_AF_\@
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              LDI  R0, #$60 ; Is it a hex char a-f?
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              XOR  R1
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              BRZ  _CNV_AH_AF_\@
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              BNI  _CNV_AH_NV_\@
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; Valid HEX characters 0-9 are ASCII codes 0x30 to 0x39. Codes 0x3A to 0x3F are
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;  invalid, so check that the value in R0 is LESS than $3A.
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_CNV_AH_09_\@:TX0  R2       ; Restore R0 from backup
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              LDI  R1, #$0F ; Mask off the upper bits to check validity
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              AND  R1
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              T0X  R2       ; Backup the lower 4-bits to R2
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; Check for 0x0A to 0x0F
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              LDI  R1, #$0A ; Load R1 with 0x0A (:)
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              CMP  R1       ; Compare R0 to R1
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              BNN  _CNV_AH_NV_\@  ; Branch if not negative (R0 > 9)
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              TX0  R2       ; Restore the lower 4-bits to R0
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              BNI  _CNV_AH_EX_\@
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; Valid HEX characters A-F are 0x41 to 0x46 OR 0x61 to $66. The upper 4-bits
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;  have already been checked, so just verify that the lower 4-bits are between
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;  0x01 and 0x06. 0x00 and 0x07 to 0x0F are invalid,
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;  so check that the value in R0 is LESS than $3A
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_CNV_AH_AF_\@:TX0  R2       ; Restore R0 from backup
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              LDI  R1, #$0F ; Mask off the upper bits to check validity
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              AND  R1
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              T0X  R2       ; Backup the lower 4-bits to R2
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; Check for 0x00
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              BRZ  _CNV_AH_NV_\@  ; 0x0 is an invalid code
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; Check for 0x07 to 0x0F
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              LDI  R1, #$07 ; Load R1 with 0x7 (G or g)
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              CMP  R1       ; Compare R0 to R1
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              BNN  _CNV_AH_NV_\@  ; Branch of not negative (R0 > 6)
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; If this is a valid character, add 9 to the lower 4-bits for the result
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;  (0x01 to 0x06 -> 0x0A to 0x0F)
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              TX0  R2       ; Restore lower 4-bits to R0
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              LDI  R1, #$09 ; Load R1 with 0x9
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              ADD  R1       ; Added 9 to R0 to convert to A-F
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              BNI  _CNV_AH_EX_\@
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_CNV_AH_NV_\@:LDI  R0, #$FF ; Return 0xFF on an invalid character
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_CNV_AH_EX_\@:POP  R2       ; Restore R1 and R2
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              POP  R1
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.ENDM
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;------------------------------------------------------------------------------
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;------------------------------------------------------------------------------
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; Convert the lower nibble of R0 into a valid ASCII character
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; Accepts data in R0 and returns the ASCII code in R0
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;------------------------------------------------------------------------------
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.MACRO CONVERT_NIB2ASC
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              PSH  R1       ; Preserve R1
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              LDI  R1, #$0F ; Mask away the upper 4-bits
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              AND  R1
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              T0X  R1       ; Copy to R1
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              LDI  R0, #$09 ; Load R0 with 0x09
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              CMP  R1       ; Compare R0 to R1
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              BNN  _CNV_NA_09_\@
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              ; Fall into _MC_FM_CHA_AF
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_CNV_NA_AF_\@:LDI  R0, #$37 ; Add 0x37 to the nibble to get the ASCII value
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              ADD  R1
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              BNI  _CNV_NA_EX_\@
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_CNV_NA_09_\@:LDI  R0, #$30 ; Add 0x30 to the nibble to get the ASCII value
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              OR   R1
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              ; Fall into _MC_FM_CHA_EX
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_CNV_NA_EX_\@:POP  R1
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.ENDM
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;------------------------------------------------------------------------------
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;------------------------------------------------------------------------------
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; Convert the packed BCD value in R0 to its ASCII equivalent in R3:R2
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; $59 -> $35, $39
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;------------------------------------------------------------------------------
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.MACRO CONV_PBCD_TO_ASCII
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              T0X  R2        ; Copy R0 -> R2 for re-use
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              LDI  R0, #$F0  ; Set the upper nibble mask. BCD is only 3-bit
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              AND  R2        ; Mask off the upper 3-bits of value -> R0
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              CLP  PSR_C     ; Clear the carry (in case CPU options not set)
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              ROR  R0        ; Shift the upper nibble down
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              ROR  R0
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              ROR  R0
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              ROR  R0
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              LDI  R1, #$30  ; Set the ASCII upper nibble mask of $30
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              OR   R1        ; Create an ASCII character
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              T0X  R3        ; Transfer the upper character to R3
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              LDI  R0, #$0F  ; Set the lower nibble mask
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              AND  R2        ; Mask off the lower bits
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              OR   R1        ; Create an ASCII character
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              T0X  R2        ; Store the lower character to R1
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              RTS
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.ENDM
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;------------------------------------------------------------------------------

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