; E2File
;
; Upload a file structure into the EEPROM of the SX web-server. This code
; should be used in conjunction with the E2File.exe program on a PC.
; Updated may 11, 2000 to support both parallax and SASM (rev 1.44.6) assemblers.
; Copyright 1999 Celsius Research Ltd
;
;
;*****************************************************************************************
; Target SX
; Uncomment one of the following lines to choose the SX18AC, SX20AC, SX28AC, SX48BD/ES,
; SX48BD, SX52BD/ES or SX52BD. For SX48BD/ES and SX52BD/ES, uncomment both defines,
; SX48_52 and SX48_52_ES.
;*****************************************************************************************
;SX18_20
;SX28
SX48_52
;SX48_52_ES
;*****************************************************************************************
; Assembler Used
; Uncomment the following line if using the Parallax SX-Key assembler. SASM assembler
; enabled by default.
;*****************************************************************************************
;SX_Key
;*********************************************************************************
; Assembler directives:
; high speed external osc, turbo mode, 8-level stack, and extended option reg.
;
; SX18/20/28 - 4 pages of program memory and 8 banks of RAM enabled by default.
; SX48/52 - 8 pages of program memory and 16 banks of RAM enabled by default.
;
;*********************************************************************************
IFDEF SX_Key ;SX-Key Directives
IFDEF SX18_20 ;SX18AC or SX20AC device directives for SX-Key
device SX18L,oschs2,turbo,stackx_optionx
ENDIF
IFDEF SX28 ;SX28AC device directives for SX-Key
device SX28L,oschs2,turbo,stackx_optionx
ENDIF
IFDEF SX48_52_ES ;SX48BD/ES or SX52BD/ES device directives for SX-Key
device oschs,turbo,stackx,optionx
ELSE
IFDEF SX48_52 ;SX48/52/BD device directives for SX-Key
device oschs2
ENDIF
ENDIF
freq 50_000_000
ELSE ;SASM Directives
IFDEF SX18_20 ;SX18AC or SX20AC device directives for SASM
device SX18,oschs2,turbo,stackx,optionx
ENDIF
IFDEF SX28 ;SX28AC device directives for SASM
device SX28,oschs2,turbo,stackx,optionx
ENDIF
IFDEF SX48_52_ES ;SX48BD/ES or SX52BD/ES device directives for SASM
device SX52,oschs,turbo,stackx,optionx
ELSE
IFDEF SX48_52 ;SX48BD or SX52BD device directives for SASM
device SX52,oschs2
ENDIF
ENDIF
ENDIF
reset ResetVector
ID 'EEPROG'
Temp = $0F
UartBank = $10
UartStatus = UartBank + $0
UartTxStart = UartStatus.0
UartTxMode = UartStatus.1
UartRxAvail = UartStatus.2
UartRxMode = UartStatus.3
UartTxPin = rd.3 ;Output - Idle High
UartRxPin = rd.0 ;Input - Idle High
Uart9600 = 24
Uart19200 = 12
Uart38400 = 6
Uart57600 = 4
Uart115200 = 2
UartSpeed = Uart57600
UartTxData = UartBank + $1
UartTxBits = UartBank + $2
UartTxBitCount = UartBank + $3
UartTxDivide = UartBank + $4
UartRxData = UartBank + $5
UartRxBits = UartBank + $6
UartRxBitCount = UartBank + $7
UartRxDivide = UartBank + $8
E2Bank = $30
E2DeviceRD = %10100001
E2DeviceWR = %10100000
E2FileSizeH = E2Bank + $0
E2FileSizeL = E2Bank + $1
E2FileChecksumH = E2Bank + $2
E2FileChecksumL = E2Bank + $3
E2AddrH = E2Bank + $4
E2AddrL = E2Bank + $5
E2DataBits = E2Bank + $6
E2BitCount = E2Bank + $7
E2Delay = E2Bank + $8
E2Port = re
E2SCLPin = E2Port.0
E2SDAPin = E2Port.1
E2SCLMask = %00000001
E2SDAMask = %00000010
E2SDAInDDR = %11111110
E2SDAOutDDR = %11111100
E2PortInit = %11111111
E2Size = 32*1024
; ==============================================================================
bank52 MACRO 1
bank \1
IF \1 & %10000000 ;SX48BD and SX52BD (production release) bank instruction
setb fsr.7 ;modifies FSR bits 4,5 and 6. FSR.7 needs to be set by software.
ELSE
clrb fsr.7
ENDIF
ENDM
; ==============================================================================
; Interrupt Handler
; ==============================================================================
; Description:
; Interrupts every 217 cycles = 4.34us
; ==============================================================================
mov FSR, #UartBank ;2
UartTxIsr
snb UartTxMode ;1/2 Transmitting ?
jmp UartTxDataIsr ;3 Yes => UartTxDataIsr
snb UartTxStart ;1/2 Start transmit ?
jmp UartTxStartIsr ;3 Yes => UartTxStartIsr
UartTxRet
UartRxIsr
snb UartRxMode ;1/2 Receiving ?
jmp UartRxDataIsr ;3 Yes => UartRxDataIsr
sb UartRxPin ;1/2 Start bit ? (start bit = 0)
jmp UartRxStartIsr ;3 Yes => UartRxStartIsr
UartRxRet
mov w, #-217 ;1 Interrupt in 217 cycles @ 50MHz
retiw ;3 Total Isr Time = x cycles
UartTxDataIsr ; Time = 4/15/18 cycles
decsz UartTxDivide ;1/2
jmp UartTxRet ;3 Isr Time = +n cycles from UartTxIsr
movb UartTxPin, UartTxBits.0 ;4 Output next bit
stc ;1 Stop bit (idle = 1)
rr UartTxBits ;1
mov UartTxDivide, #UartSpeed ;2 Apply baud rate
decsz UartTxBitCount ;1/2
jmp UartTxRet ;3 Isr Time = +n cycles from UartTxIsr
clrb UartTxMode ;1 Finished
jmp UartTxRet ;3 Isr Time = +n cycles from UartTxIsr
UartTxStartIsr
mov UartTxBits, UartTxData ;2 Load data for transmission
clrb UartTxPin ;1 Output start bit
mov UartTxDivide, #UartSpeed ;2 Apply UartSpeed
mov UartTxBitCount, #10 ;2 Bit count = 8 data + 1 stop + 1 for stop bit to complete
clrb UartTxStart ;1 Clear start mode
setb UartTxMode ;1 Enter Tx mode
jmp UartTxRet ;3 Isr Time = +n cycles
UartRxDataIsr
decsz UartRxDivide ;1/2
jmp UartRxRet ;3 Isr Time = +n cycles
decsz UartRxBitCount ;1/2
jmp :Read ;3
:Stop mov UartRxData, UartRxBits ;2 Copy bits into UartData
clrb UartRxMode ;1 Finished
setb UartRxAvail ;1
jmp UartRxRet ;3 Isr Time = +n cycles
:Read clc ;1 Determine bit
snb UartRxPin ;1/2 Determine bit
stc ;1 Determine bit
rr UartRxBits ;1 Record bit
mov UartRxDivide, #UartSpeed ;2 Apply baud rate
jmp UartRxRet ;3 Isr Time = +n cycles
UartRxStartIsr
mov UartRxDivide, #UartSpeed / 2 ;2 UartDivide = UartSpeed * 0.5
mov UartRxBitCount, #10 ;2 Bit count = 10 (1/2 start, 8 data, 1 stop)
setb UartRxMode ;1 Enter rx mode
jmp UartRxRet ;3 Isr Time = +n cycles
; ==============================================================================
; ==============================================================================
UartGetByte
bank52 UartBank
:Loop sb UartRxAvail
jmp :Loop
mov w, UartRxData
clrb UartRxAvail
retp
UartSendByte
bank52 UartBank
:Loop1 snb UartTxStart
jmp :Loop1
:Loop2 snb UartTxMode
jmp :Loop2
mov UartTxData, w
setb UartTxStart
retp
; ==============================================================================
ResetVector
bank52 UartBank
clr UartStatus
mov w, #$1F
mov m, w
mov rd, #$FF
mov !rd, #%11110111
mov re, #E2PortInit
mov !re, #E2SDAInDDR
mov w, #%10011111 ;Enable RTCC int
mov !option, w ;Enable RTCC int
bank52 E2Bank
clr E2AddrH
clr E2AddrL
Main call @UartGetByte
mov Temp, w
csne Temp, #'R'
jmp ReadFile
csne Temp, #'W'
jmp WriteBlock
csne Temp, #'?'
jmp Hello
jmp Main
ReadFile
call @UartGetByte
call @E2OpenFile
sz ;File open ? (z=true)
jmp :Error ;No => indicate error
mov w, #'[' ;indicate open
call @UartSendByte ;send indication
:Loop call @E2ReadFile ;get data byte
call @UartSendByte
snz ;More bytes ? (z=true)
jmp :Loop ;Yes => read next byte
mov w, #']' ;indicate complete
call @UartSendByte ;send indication
jmp Main
:Error mov w, #'!' ;indicate error
call @UartSendByte ;send indication
jmp Main
WriteBlock
call @UartGetByte
bank52 E2Bank
mov E2AddrH, w ;store address high
call @UartGetByte
bank52 E2Bank
and w, #%11100000 ;ensure address low = multiple of 32
mov E2AddrL, w ;store address low
call @E2WriteStart ;open stream
sz ;opened ?
jmp :Error ;No => error
mov E2AddrL, #32 ;Count 32 bytes
mov w, #'[' ;indicate ready
call @UartSendByte ;send indication
:Loop call @UartGetByte ;get data byte
call @E2WriteData ;store data
decsz E2AddrL
jmp :Loop
call @E2WriteComplete ;finish write transaction
mov w, #']' ;indicate complete
call @UartSendByte ;send indication
jmp Main
:Error mov w, #'!' ;indicate error
call @UartSendByte ;send indication
jmp Main
Hello
mov w, #'#' ;Reply
call @UartSendByte ;send indication
mov w, #E2Size / 256 ;indicate size
call @UartSendByte ;send indication
jmp Main
; ==============================================================================
org $200
E2Start ;SCL=high, SDA=in
mov w, #E2SDAOutDDR ;Prepare to make SDA an output
clrb E2SDAPin ;When output SDA will be low
mov !E2Port, w ;Make SDA an output => low
jmp E2DelaySCLHigh ;Delay & return
E2Stop ;SCL=high, SDA=in/out
clrb E2SCLPin ;Make SCL go low => can change data
mov w, #E2SDAOutDDR ;Prepare to make SDA an output
clrb E2SDAPin ;Prepare to output SDA low
mov !E2Port, w ;Make SDA an output => low
call E2DelaySCLLow ;Delay
setb E2SCLPin ;Make SCL go high
call E2DelaySCLHigh ;Delay
mov w, #E2SDAInDDR ;Prepare to make SDA go high => stop bit
mov !E2Port, w ;Release SDA => stop bit
call E2DelaySCLHigh ;Delay
clz ;Indicate stream closed
retp
E2WriteToRead ;SCL=high, SDA=in
clrb E2SCLPin ;SCL goes low to allow data change
call E2DelaySCLLow ;Delay
setb E2SCLPin ;Return SCL high
call E2DelaySCLHigh ;Delay
jmp E2Start
E2Write ;SCL=high, SDA=in
mov E2DataBits, w ;Store data to be sent
mov E2BitCount, #8 ;Send 8 bits
:Bit clrb E2SCLPin ;SCL goes low to allow data change
rl E2DataBits ;C = bit to send (MSB first)
mov w, #E2SDAOutDDR ;Guess bit is a 0
snc ;Should bit be a 1 ?
mov w, #E2SDAInDDR ;Yes => Change to 1
clrb E2SDAPin ;SDA low in case of an ouput
mov !E2Port, w ;Apply SDA DDR
call E2DelaySCLLow ;Delay
setb E2SCLPin ;Return SCL high to allow E2 to read data
call E2DelaySCLHigh ;Delay
decsz E2BitCount ;More bits to send ?
jmp :Bit ;Yes => send next bit
mov w, #E2SDAInDDR ;Prepare to make SDA go high
mov !E2Port, w ;Release SDA pin for ack
clrb E2SCLPin ;SCL goes low for ack
call E2DelaySCLLow ;Delay
setb E2SCLPin ;Return SCL high to read ack
call E2DelaySCLHigh ;Delay
stz ;Assume a 0
snb E2SDAPin ;Is the data a 1 ?
clz ;Yes => change to a 1
retp
E2ReadAck ;SCL should be high
mov E2BitCount, #8 ;Get 8 bits
:Bit clrb E2SCLPin ;SCL goes low to allow data change
mov w, #E2SDAInDDR ;Prepare to make SDA go high
mov !E2Port, w ;Release SDA pin to allow data read
call E2DelaySCLLow ;Delay
setb E2SCLPin ;Return SCL high to allow E2 to read data
clc ;Assume a 0
snb E2SDAPin ;Is the data a 1 ?
stc ;Yes => change to a 1
rl E2DataBits ;Store new bit (MSB first)
call E2DelaySCLHigh ;Delay
decsz E2BitCount ;More bits to come ?
jmp :Bit ;Yes => get next bit
clrb E2SCLPin ;SCL goes low to allow data change for ack
mov w, #E2SDAOutDDR ;Prepare to make SDA go low for ack
clrb E2SDAPin ;SDA low when output
mov !E2Port, w ;Force SDA pin low
call E2DelaySCLLow ;Delay
setb E2SCLPin ;Return SCL high. Note SDA still low
call E2DelaySCLHigh ;Delay
mov w, E2DataBits ;Data to be returned
stz ;Indicate ack
retp
E2ReadNotAck ;SCL should be high
mov E2BitCount, #8 ;Get 8 bits of data
:Bit clrb E2SCLPin ;SCL goes low to allow data change
mov w, #E2SDAInDDR ;Prepare to make SDA go high
mov !E2Port, w ;Release SDA pin to allow data read
call E2DelaySCLLow ;Delay
setb E2SCLPin ;Return SCL high to allow E2 to read data
clc ;Assume a 0
snb E2SDAPin ;Is the data a 1 ?
stc ;Yes => change to a 1
rl E2DataBits ;Store new bit (MSB first)
call E2DelaySCLHigh ;Delay
decsz E2BitCount ;More bits to come ?
jmp :Bit ;Yes => get next bit
clrb E2SCLPin ;SCL goes low to allow data change for ack
call E2DelaySCLLow ;Leave SDA high for not ack, Delay
setb E2SCLPin ;Return SCL high.
call E2DelaySCLHigh ;Delay
mov w, E2DataBits ;Data to be returned
clz ;Indicate not ack
retp
E2DelaySCLLow ;1300ns minimum = 65 instructions
mov E2Delay, #15 ;Loop 15 times (4 cycles per loop + 8 for overhead)
:Loop decsz E2Delay ;Delay complete ?
jmp :Loop ;No => loop again
retp
E2DelaySCLHigh ;600ns minimum = 30 instructions
mov E2Delay, #6 ;Loop 6 times (4 cycles per loop + 8 for overhead)
:Loop decsz E2Delay ;Delay complete ?
jmp :Loop ;No => loop again
retp
; ==============================================================================
; Mode must be DDR
E2WriteStart ;Returns Z=true for ready
bank52 E2Bank
call E2Start ;Send start bit
mov w, #E2DeviceWR
call E2Write ;Output device code
sz ;Ack ?
jmp E2Stop ;No => not ready, send stop bit + return z=false
mov w, E2AddrH
call E2Write ;Output AddrH
mov w, E2AddrL
call E2Write ;Output AddrL
sz ;Ack ?
jmp E2Stop ;No => not ready, send stop bit + return z=false
retp
E2WriteData ;W = data, returns Z=true for ack
bank52 E2Bank
jmp E2Write
E2WriteComplete ;Complete write process
bank52 E2Bank
jmp E2Stop
E2ReadStart ;Returns Z=true for ack
bank52 E2Bank
call E2Start ;Send start bit
mov w, #E2DeviceWR
call E2Write ;Output device code
sz ;Ack ?
jmp E2Stop ;No => not ready, send stop bit + return z=false
mov w, E2AddrH
call E2Write ;Output AddrH
mov w, E2AddrL
call E2Write ;Output AddrL
call E2WriteToRead ;Send start bit
mov w, #E2DeviceRD
call E2Write ;Output
sz ;Ack ?
jmp E2Stop ;No => not ready, send stop bit + return z=false
retp
E2ReadData ;Returns W=data
bank52 E2Bank
jmp E2ReadAck ;Read byte
E2ReadComplete ;Returns W=data
bank52 E2Bank
call E2ReadNotAck ;Read byte
call E2Stop ;Send stop bit
mov w, E2DataBits ;Data to be returned
retp
; ==============================================================================
E2OpenFile ;w = file reference, returns z=true for open
bank52 E2Bank
mov E2AddrL, w ;AddrL = reference
clr E2AddrH ;AddrH = 0
clc ;Prepare to multiply by 2
rl E2AddrL ;Multiply by 2
rl E2AddrH ;Multiply by 2
call E2ReadStart ;Prepare to read
sz ;Ack ?
retp ;No => return error (z=false)
call E2ReadData ;Read MSB of address
mov E2AddrH, w ;AddrH = MSB
call E2ReadComplete ;Read LSB of address
mov E2AddrL, w ;AddrL = LSB
call E2ReadStart ;Prepare to read
sz ;Ack ?
retp ;No => return error (z=false)
call E2ReadData ;Read 1st byte
mov E2FileSizeH, w ;1st byte = FilesizeH
call E2ReadData ;Read 2nd byte
mov E2FileSizeL, w ;2nd byte = FilesizeL
call E2ReadData ;Read 3rd byte
mov E2FileChecksumH, w ;3rd byte = ChecksumH
call E2ReadData ;Read 4th byte
mov E2FileChecksumL, w ;4th byte = ChecksumL
retp ;Return ready to read 1st real data byte
E2CloseFile = E2ReadComplete ;Should not be used unless closing file prior to reaching end
E2ReadFile ;Returns Z=More (=false for last byte)
bank52 E2Bank
decsz E2FilesizeL ;More ?
jmp E2ReadData ;Yes => read data
test E2FilesizeH ;No => check high
snz ;More ?
jmp E2ReadComplete ;No => read last byte and close file
dec E2FilesizeH ;Yes => decrement counter
jmp E2ReadData ; read data
; ==============================================================================
| file: /Techref/scenix/lib/io/osi3/tcpip/iSXSupportFiles/E2File2.src, 15KB, , updated: 2005/8/19 18:49, local time: 2024/4/23 18:47,
3.138.114.94:LOG IN
|
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