;=======================================================================
; INTER - INTEGRATED CIRCUIT (I2C) SERIAL INTERFACE
; VIRTUAL PERIPHERAL
; I2CSDO1.SRC -- I2CS (Authentic I2C Slave) VP Demo #1
; Revision X1.01, 08.14.98
; Developed by Authentic Engineering for Scenix Semiconductor, Inc.
; Authentic Engineering // http://www.authenticeng.com // ak@silcom.com
;
; We consider this revision as a Beta version, and would appreciate
; any feedback and recommendation on the improvements of this VP.
;=======================================================================
;=======================================================================
;
; Authentic I2CS (I2CS Slave) Virtual Peripheral
;
; I2CS is a part of the Authentic SPI virtual peripherals for SX micro.
; This VP provides the means to connect the SX microcontroller to the
; I2C Bus. It supports data transfer in 10-bit address mode at clock
; rates up to 1.8MHz. It supports transfer of only one byte at a time.
;
; ------ Communication Protocol -----
;
; I2C Bus protocol was introduced more than ten years ago. Original
; I2CS protocol (with seven bit address and clock frequency up to
; 0.2 MHz) is widely used by the industry. However, some extensions
; of this protocol were developed in order to provide wider address
; space and faster transfer rate. For more details please refer to
; I2C Peripherals for Microcontrollers Data Handbook, published by
; Philips Semiconductors in 1992.
;
; I2CS complies with extension of the I2C protocol - 10 bit address
; and fast clock rate of 400 KHz (in fact data transfer rate may
; be as high as 1.8 Mb/s). I2CS does not support GENERAL CALL
; command on the I2C Bus. I2CS does not support CBUS protocol.
; I2CS also does not support original 7-bit address protocol,
; however it can be easily modified to work in 7-bit address mode.
;
; Authentic I2CS VP supports I2C Bus communication protocol,
; recommended by Philips for software implementations of I2C
; Slaves. According to this protocol data transfer cycle includes
; next steps:
;
; 1. I2C Bus Master generates S (start condition) and then generates
; Start Byte - special byte used only to establish communication
; with slow responding, software driven I2C devices. Start Byte is -
; 01h.
;
; I2C Slave monitors the SDA line often enough to detect the
; long SDA line LOW state associated with 01h byte. When this event
; on the Bus is detected the Slave starts to monitor the SDA line
; often enough to detect Sr (start repeat) condition. Slave
; should not generate ACK signal in response to Start Byte.
;
; 2. Master generates Sr (start repeat) condition. Sr condition
; is detected by Slave and Slave starts to receive the address from
; the Master.
;
; 3. Master sends to Slave two byte of address information. If the
; address information matches Slave address, the Slave must
; generate ACK signals for each of two bytes.
;
; First byte is 1111 0SS(r/w), where SS are two MSBs of 10-bit Slave
; address, R/W is the transfer direction bit. R/W=1 corresponds to
; data transfer from Slave to Master.
;
; Second Byte contains simply eight bits of Slave Bus address
;
; 4. Data are transferred to/from Master. When the data are transferred
; to Slave the Slave generates the ACK signal.
;
; 5. Master generates P (Stop) condition.
;
; 6. Transfer can be interrupted at any time by Sr or P (Stop) signals
; generated by Master. To detect these situations Slave monitors SDA line
; during each SCL HIGH state.
;
; It is worth mentioning that the I2CS protocol was developed having
; in mind easy hardware implementation. The software implementation
; of this protocol is relatively complicated. Specifically - the software
; must assure correct response on Start and Stop conditions on the bus.
; It may contradict with other software functions. In this case we recommend
; to develop relatively simple hardware extension to support this protocol.
;
; ----- Timing considerations ------
;
; I2CS must sample the SDA line often enough to assure detection of Start Byte.
; The minimum sampling depends on Bus Clock frequency. For the clock
; frequency of 400 KHz the sampling period should not be more than 18 usec.
; I2CS must be called by MAIN program at least every 18 usec. The I2CS will
; exit within 180 nsec in the case when SDA LOW state is not detected.
; So, the sampling of the SDA Bus occupies only 1% of CPU time.
;
; When the SDA LOW state is detected, the I2CS will wait for 30 usec or until
; the Sr condition is detected. This waiting time is controlled by
;
; I2CS_START_TIMEOUT.
; F0h value corresponds to 30 usec waiting time.
;
; In order to prevent I2CS locking in case of I2C Bus faults (like absents of
; Clock signal), the I2CS VP make use of timeout timer. This timer is initiated
; whenever the I2CS comes into some wait state. When the timeout timer expires
; data transfer will be terminated by Slave. The waiting time is always the
; same and is controlled by
;
; I2CS_CLK_TIMEOUT. 50 (decimal) value corresponds to 6 usec.
;
; ------ Address ------
;
; I2CS provides direct memory access for the Master. The RAM space,
; accessible from the Master is limited to one bank - 16 bytes. This
; IO_RAM Bank can be randomly addressed by the Master and is used as a
; mail box between Bus Master and user application program, running on
; the Slave.
;
; The I2C Bus address of I2CS consists of 10 bits, four LSbits are
; used to address corresponding bytes in the IO_RAM bank. Upper six bits
; are user defined and represent the I2CS Bus address - (we call it Bus ID).
; I2CS 10-bit Bus ID consists of two parts. One is the address of the
; The IO_RAM bank itself is defined by Slave MAIN program.
; The address of I2CS is defined by next bytes:
;
; I2CS_IO_RAM
; Defines the base address of the BANK. Must be one of 10h, 30h....
;
; I2CS_ID_MASK_MSB
;
; Must be 1111 0SS0. Five MSBs are pointing that it is 10-bit address mode
; two bits SS are first two bits of 10-bit bus address. Last bit is zero.
;
; I2CS_ID_MASK_LSB
;
; Four MSBs define the Slave I2C Bus address. Four LSBs, must be zero.
;
; Example:
; Two address bytes send by Master: 1 1 1 1 0 s10 s9 1
; s8 s7 s6 s5 r4 r3 r2 r1
; will address location r4 r3 r2 r1 of the Slave IO_RAM in the case when
; Slave MASK_MSB and MASK_LSB will contain bits S10-S5 on corresponding
; positions:
; I2CS_ID_MASK_MSB 1 1 1 1 0 s10 s9 0
; I2CS_ID_MASK_LSB s8 s7 s6 s5 0 0 0 0
;
;
; ------- I/O pin configuration -------
;
; I2CS makes use of three pins.
; SCL line pin in always configured as an input.
; SDA input pin is always configured as input.
; SDA output pin is dynamically reconfigured from input to output state.
; I2CS make use of PortB only, However, it is relatively easy to change the
; the program so that it will work with any other port. The port configuration
; is controlled by next data:
;
; I2CS_SCL_PIN pointer to SCL pin
; I2CS_SDA_IN_PIN pointer to SDA input pin
; I2CS_SDA_OUT_PIN pointer to SDA output pin
; I2CS_PORT_RX_MASK image of PortB direction register
; in receive mode
; I2CS_PORT_TX_MASK image of port direction register
; in transmit mode
;
; ------- Entry points ------
;
; I2CS VP has two entry points:
;
; I2CS_INIT - an entry point of the subroutine, which will provide
; correct configuration of the PortB.
;
; I2CS_EXECUTE - an entry point of the I2CS VP.
;
; ------ Control and status data ------
;
; The following is a list of all I2CS control parameters (described above)
;
; I2CS_START_TIMEOUT. F0h value corresponds to 30 usec waiting time.
;
; I2CS_CLK_TIMEOUT. 50 (decimal) value corresponds to 6 usec.
;
; I2CS_IO_RAM
; Defines the base address of the BANK. Must be one of 10h, 30h....
;
; I2CS_ID_MASK_MSB
; I2CS_ID_MASK_LSB Two byte mask of I2CS Bus ID.
;
; I2CS_SCL_PIN pointer to SCL pin
; I2CS_SDA_IN_PIN pointer to SDA input pin
; I2CS_SDA_OUT_PIN pointer to SDA output pin
; I2CS_PORT_RX_MASK image of PortB direction register
; in receive mode
; I2CS_PORT_TX_MASK image of port direction register
; in transmit mode
;
; I2CS provides the feed back to the user program with a help of two bytes
; - I2CS_STATUS and I2CS_FSR.
;
; I2CS_FSR contains the image of FSR register for the last byte transferred
;
; I2CS_STATUS/Bit.0 - I2CS_READY
; Set by I2CS when data reception was accomplished. Should be cleared by MAIN
; program. Acts as a flag indicating that byte was written by Master.
;
; I2CS_STATUS/Bit.1 - I2CS_OVERFLOW
; Warning, set by I2CS when the data were written by I2C Bus Master
; before the previous data have been processed by MAIN (before
; I2CS_READY flag was cleared).
;
; I2CS_STATUS/Bit.3 - I2CS_STOP_EVENT
; Set when transfer was aborted because of Stop event.
;
; I2CS_STATUS/Bit.4 - I2CS_START_REPEAT_EVENT
; Set when Sr event occurred during the data transfer.
;
; I2CS_STATUS/Bit.5 - I2CS_TIMEOUT
; Set when transfer was aborted because of expiration of TIMEOUT TIMER.
;
; I2CS_STATUS/Bit.6 - I2CS_RECEIVE_TRANSMIT
; Set when last transfer was transmission to Master.
;
; I2CS_STATUS/Bit.7 - I2CS_TRANSFER_ERROR
; Set when transfer was aborted by either timeout or P events.
;
; ------ How to use I@CS from the user program ------
;
; 1. Initialize all control data
; 2. Call I2CS_INIT to initialize the Port (optional)
; 3. Disable interrupts and call I2CS_EXECUTE
; 4. Check the content of I2CS_STATUS, clear I2CS_READY bit, if necessary.
; 5. Make sure that steps 3 and 4 repeated often enough to support correct
; operation of I2CS Bus.
;
;=======================================================================
;================= Recommended system configuration ====================
;**************************** Code start *******************************
device pins28, pages4, banks8, oschs, turbo, stackx, optionx
id 'I2CS_D1'
reset reset_entry
;****************** I/O PINS and RAM configuration **********************
i2cs_port = rb ;SX port assigned for I2CS communication
i2cs_scl_pin = rb.0 ;I2CS clock line
i2cs_sda_in_pin = rb.1 ;I2CS data input pin
i2cs_sda_out_pin = rb.2 ;I2CS data output pin
sys_bank = 10h ;MAIN program RAM
i2cs_ram_bank = 30h ;I2CS RAM bank
i2cs_io_ram = 50h ;I2CS I/O RAM bank
;=======================================================================
;========================== Authentic I2C SLAVE VP =====================
;******************************** I2CS RAM *****************************
org i2cs_ram_bank
;I2CS control data
i2cs_port_rx_mask ds 1 ;PortB direction register image for receive mode
i2cs_port_tx_mask ds 1 ;PortB direction register image for transmit mode
i2cs_id_mask_msb ds 1 ;I2CS ID MSbyte, correct MSB value should be 1111 0SS(r/w)
;Bit sero is data transfer direction (r=1/W=0)
;Bits 1,2 (SS) are the MSBits of the 10 bit
;I2CS Bus ID.
;Bits 3 to 7 must be 1111 0XXX
i2cs_id_mask_lsb ds 1 ;LSByte of the ID. Bits from 0 to 3 address
;the RAM (r) within the selected bank, bits 4 to 7
;are the LSBits of I2CS Bus ID: SSSS rrrr
;So the two address mask bytes will look like
; 1111 0SS0 SSSS 0000
i2cs_fsr ds 1 ;FSR image for the last byte transferred (read/written)
i2cs_clk_timeout ds 1 ;Clock detection timeout
i2cs_start_timeout ds 1 ;Start detection timeout
;I2CS status data
i2cs_status ds 1 ;I2CS Status word
i2cs_ready equ i2cs_status.0 ;Set when data reception was accomplished.
;Should be cleared by MAIN program. Acts as
;as a flag indicating that byte was written by Master
i2cs_overflow equ i2cs_status.1 ;Warning, set when the data are written
;by I2C Bus Master before the previous data
;were processed by MAIN (before I2CS_READY flag was cleared)
i2cs_stop_event equ i2cs_status.3 ;Set when the transfer was aborted
;because of detection of Stop event on the BUS
i2cs_start_repeat_event equ i2cs_status.4 ;Set when the Sr (Start Repetition) was detected
i2cs_timeout equ i2cs_status.5 ;Set when watchdog timeout occurred
i2cs_receive_transmit equ i2cs_status.6 ;Set when the last operation was transmission to Master
i2cs_transfer_error equ i2cs_status.7 ;Error - transfer aborted by I2CS timeout or P
i2cs_io_buffer ds 1 ;Data shift register for I2CS
;I2CS private data
i2cs_state ds 1 ;Internal state of the I2CS
i2cs_start_ok equ i2cs_state.0 ;Set when start condition was detected
i2cs_id_ok equ i2cs_state.1 ;Set when I2CS address was detected
i2cs_byte_ok equ i2cs_state.2 ;Set when data byte was transferred
i2cs_stop_ok equ i2cs_state.3 ;Set when Stop condition was detected
i2cs_start_repeat equ i2cs_state.4 ;Set when repetition start condition was detected
i2cs_timeout_exp equ i2cs_state.5 ;Set when I2CS timeout expires
i2cs_shift_counter ds 1 ;number of bits to transfer
i2cs_timeout_counter ds 1 ;I2CL timeout counter
org main_end
;********************** I2CS subroutines *******************************
;******************** Send acknowledgement *****************************
;
; This subroutine generates the ACK signal on I2CS_OUT_PIN.
; It first configures the PortB direction register with the
; I@CS_PORT_TX_MASK. Then sets the SDA pin LOW until the Clock
; signal occurs, or the timeout timer expires.
i2cs_send_ack mov i2cs_timeout_counter,i2cs_clk_timeout
;Initialize Clock timeout counter
mov m,#$0f
mov !rb,i2cs_port_tx_mask ;Configure the pin as an output
clrb i2cs_sda_out_pin ;Set ACK - SDA LOW
:i2cs_send_ack_1 jb i2cs_scl_pin,:i2cs_send_ack_2 ;Wait for SCL LOW to HIGH transition
djnz i2cs_timeout_counter,:i2cs_send_ack_1
setb i2cs_timeout_exp ;Exit when timeout expires
jmp :i2cs_send_ack_exit
mov i2cs_timeout_counter,i2cs_clk_timeout
;Initialize clock timeout counter
:i2cs_send_ack_2 jnb i2cs_scl_pin,:i2cs_send_ack_exit
;Wait for the end of ACK clock pulse
;(HIGH to LOW transition of SCL line)
djnz i2cs_timeout_counter,:i2cs_send_ack_2
setb i2cs_timeout_exp ;Exit when timeout expires
:i2cs_send_ack_exit mov !rb,i2cs_port_rx_mask ;Disactivate output pin and exit
setb i2cs_sda_out_pin
ret
;**************** End of Send Acknowledgement subroutine ***************
;************************* Get byte subroutine *************************
;
; This subroutine receives the byte from I2C Master and stores it
; in I2CS_IO_BUFFER. The Subrotine aborts data reception in cases
; when:
; - the clock frequency will be too low
; - the Sr (Start repetition) will occur
; - the P (Stop) will occur
i2cs_get_byte mov i2cs_shift_counter,#$08 ;Set the number of bits to receive
:i2cs_get_byte_loop mov i2cs_timeout_counter,i2cs_clk_timeout
;Set the timeout counter
:i2cs_get_0 jnb i2cs_scl_pin,:i2cs_get_1 ;Wait for SCL LOW state
djnz i2cs_timeout_counter,:i2cs_get_0
setb i2cs_timeout_exp ;Exit when timeout expires
ret
:i2cs_get_1 movb rc.1,i2cs_scl_pin ;XXXX TEST PIN TO MONITOR THE CLOCK
mov i2cs_timeout_counter,i2cs_clk_timeout
;Set the timeout counter
:i2cs_get_2 jb i2cs_scl_pin,:i2cs_get_bit_in ;Wait for SCL LOW to HIGH transition
djnz i2cs_timeout_counter,:i2cs_get_2
setb i2cs_timeout_exp ;Exit when timeout expires
ret
:i2cs_get_bit_in rl i2cs_io_buffer ;Shift the data in
movb i2cs_io_buffer.0,i2cs_sda_in_pin
movb rc.0,i2cs_sda_in_pin ;XXXX TEST PIN TO MONITOR THE DATA
movb rc.1,i2cs_scl_pin ;XXXX TEST PIN TO MONITOR THE CLOCK
mov i2cs_timeout_counter,i2cs_clk_timeout
;Set the timeout counter
:i2cs_get_wait jnb i2cs_scl_pin,:i2cs_get_3 ;Wait for SCL HIGH to LOW step
djnz i2cs_timeout_counter,:i2cs_get_wait
setb i2cs_timeout_exp ;Exit when timeout expires
ret
:i2cs_get_3 movb rc.1,i2cs_scl_pin ;XXXX TEST PIN TO MONITOR THE CLOCK
jb i2cs_io_buffer.0,:i2cs_get_4 ;Compare SDA line state right after
sb i2cs_sda_in_pin ;the HIGH to LOW clock transission
jmp :i2cs_get_continue ;to the SDA line state right after
;LOW to HIGH clock transmission
setb i2cs_stop_ok ;they should be identical, otherwise
ret ;it is either Sr or P event
:i2cs_get_4 snb i2cs_sda_in_pin ;In both cases - exit
jmp :i2cs_get_continue
setb i2cs_start_repeat
ret
:i2cs_get_continue djnz i2cs_shift_counter,:i2cs_get_byte_loop
ret
;******************* End of Get byte subroutine ************************
;*********************** Send byte subroutine **************************
;
; This subroutine sends the byte of data from I2CS_IO_BUFFER to the Master.
; The Subroutine aborts data reception in cases when:
; the clock frequency will be too low
; the Sr (Start repetition) will occur
i2cs_send_byte mov !rb,i2cs_port_tx_mask ;Set the direction of SDA pin as an output
mov i2cs_shift_counter,#$8 ;Set the shift counter
:i2cs_send_byte_loop
mov i2cs_timeout_counter,i2cs_clk_timeout
;Set the timeout counter
;to wait for SCL LOW state
:i2cs_send_0 jnb i2cs_scl_pin,:i2cs_shift_bit_out ;Wait for SCL LOW
djnz i2cs_timeout_counter,:i2cs_send_0
setb i2cs_timeout_exp ;Exit when timeout expires
jmp :i2cs_send_byte_exit
mov i2cs_timeout_counter,i2cs_clk_timeout
;Initialize clock timeout counter
;to wait for SCL LOW to HIGH step
:I2cs_shift_bit_out movb i2cs_sda_out_pin,i2cs_io_buffer.7
;Shift bit out
:i2cs_send_1 jb i2cs_scl_pin,:i2cs_send_2 ;Wait for SCL LOW to HIGH transition
djnz i2cs_timeout_counter,:i2cs_send_1
setb i2cs_timeout_exp ;Exit when timeout expires
jmp :i2cs_send_byte_exit
mov i2cs_timeout_counter,i2cs_clk_timeout
;Initialize clock timeout counter
;to wait for SCL HIGH to LOW step
:i2cs_send_2 jnb i2cs_scl_pin,:i2cs_send_3 ;Wait for SCL HIGH to LOW transition
djnz i2cs_timeout_counter,:i2cs_send_2
setb i2cs_timeout_exp ;Exit when timeout expires
jmp :i2cs_send_byte_exit
:i2cs_send_3 mov i2cs_timeout_counter,#3 ;Hold the data for about 0.4 usec
:i2cs_send_4 djnz i2cs_timeout_counter,:i2cs_send_4
jnb i2cs_io_buffer.7,:i2cs_send_continue
;if the current bit was HIGH, then
;there is a chance of Sr condition
;generated by Master
jb i2cs_sda_in_pin,:i2cs_send_continue
;Current SDA line state is HIGH - continue
setb i2cs_start_repeat ;SDA line is LOW - Sr occurred, exit
jmp :i2cs_send_byte_exit
:i2cs_send_continue rl i2cs_io_buffer
djnz i2cs_shift_counter,:i2cs_send_byte_loop
;decrement bit counter and exit
:i2cs_send_byte_exit mov !rb,i2cs_port_rx_mask ;restore the direction register for DSA pin
ret
;******************* End of Send byte subroutine ***********************
;****************** I2CS initialization subroutine *********************
i2cs_init bank i2cs_ram_bank
mov m,#$0f ;set data direction registers
mov !rb,i2cs_port_rx_mask ;configure ports
setb i2cs_sda_out_pin
ret
;******************* End of initialization subroutine ******************
;************************* I2CS DATA TRANSFER **************************
i2cs_execute bank i2cs_ram_bank ;set I2CS RAM bank
;************** Detection of Start condition on the BUS ****************
snb i2cs_sda_in_pin ;Test if SDA line is LOW
ret ;SDA pin is HIGH - no Start Byte
;Exit
;SDA line LOW detected, wait for Sr (Start repetition)
i2cs_sr_detect mov i2cs_timeout_counter,i2cs_start_timeout
;Wait for SDA LOW to HIGH transition
clr i2cs_state ;Begin detection of the Sr,
;wait for SDA HIGH
:i2cs_sda_test jb i2cs_sda_in_pin,:i2cs_sda_high
;when SDA is HIGH - go to next step
djnz i2cs_timeout_counter,:i2cs_sda_test
;One wait cycle is 120 nsec
jmp :i2cs_false_start ;Timeout - exit
;Wait for first SDA HIGH to LOW transition
:i2cs_sda_high jnb i2cs_sda_in_pin,:i2cs_sda_low
;When SDA goes LOW - test the SCL
djnz i2cs_timeout_counter,:i2cs_sda_high
jmp :i2cs_false_start ;Timeout - exit
;Test the SCL line - it must be HIGH, if it is LOW - false start
:i2cs_sda_low snb i2cs_scl_pin ;It was LOW to HIGH step on SDA
;line, when the SCL was LOW - false start
jmp i2cs_start
:i2cs_false_start ret ;Exit I2CS, no Start detected
;************** Decode the first byte in transfer **********************
; Start condition detected; next step - decode the address
; First byte contains R/W bit, and two bits of 10-bit address
i2cs_start clr i2cs_state ;Reset the state machine
setb i2cs_start_ok ;Start detected
and i2cs_status,#$01 ;Clear all bits of Status byte but READY bit
;Ready bit may be cleared only by MAIN program
:get_transfer call i2cs_get_byte ;Get 1st address byte
;Test if the transfer was interrupted either by Sr, P signals or by timeout timer
mov w,i2cs_state
and w,#$38 ;Select three state bits
sz ;Continue if ZERO
jmp i2cs_exit
;Test if the byte was the Start Byte
mov w,i2cs_io_buffer
xor w,#$01 ;Is it the "START BYTE" (01h) ?
snz
jmp i2cs_sr_detect ;Yes, it was the Start Byte
;Go back and wait for Sr condition
;Check if this is I2CS ID
mov w,i2cs_io_buffer ;Is it 10-bit address ?
and w,#$fe ;Mask the r/w bit
xor w,i2cs_id_mask_msb ;Test ten bit address (must be1111 0SSX)
sz
jmp i2cs_exit ;This is not I2CS ID - exit
;Decode R/W bit
clrb i2cs_receive_transmit
snb i2cs_io_buffer.0 ;Test the r/w bit
setb i2cs_receive_transmit ;Zero indicates transmission from master
;Send ack
call I2cs_send_ack ;Generate ACK signal
snb i2cs_timeout_exp ;Was the timeout OK ?
jmp i2cs_exit ;No
;************************ Decode the second byte ***********************
; Second byte contains last eight bit of 10-bit address
call i2cs_get_byte
;Test if the transfer was interrupted by either Sr or P signal or timeout timer
mov w,i2cs_state
and w,#$38 ;Select three state bits
sz ;Continue if ZERO
jmp i2cs_exit
;Decode the LSB of Bus ID
mov w,i2cs_io_buffer
and w,#$f0 ;Test the ID
xor w,i2cs_id_mask_lsb ;Is it the I2CS bus ID ?
sz
jmp i2cs_exit ;This is not I2CS Bus ID
;Decode ram address
mov w,i2cs_io_buffer
and w,#$0f
or w,i2cs_io_ram ;Combine the last 4 bits of BUS ID
;with the defined I/O_RAM bank address
mov i2cs_fsr,w ;Save the FSR image
setb i2cs_id_ok
call i2cs_send_ack ;Generate the ACK
snb i2cs_timeout_exp ;Was the timeout OK ?
jmp i2cs_exit ;No
;*********************** Transfer the byte *****************************
jb i2cs_receive_transmit,:i2cs_transmit_byte
;Receive the byte
call i2cs_get_byte
;Test if the transfer was interrupted by either Sr or P signal
mov w,i2cs_state
and w,#$38 ;Select three state bits
sz ;Continue if ZERO
jmp i2cs_exit
mov 08h,i2cs_io_buffer ;Move the data to I2CS I/O RAM location
mov fsr,i2cs_fsr ;using FSR as I/O data pointer
mov indf,08h
bank i2cs_ram_bank
call i2cs_send_ack ;Generate the ACK signal
snb i2cs_timeout_exp ;Was the timeout OK ?
jmp i2cs_exit ;No
setb i2cs_byte_ok
jmp i2cs_exit ;Data transfer finished - exit
;Transmit the byte
:i2cs_transmit_byte mov fsr,i2cs_fsr ;Move the data from I2CS RAM Location
mov 08h,indf ;to I2CS_IO_BUFFER using FSR as pointer
bank i2cs_ram_bank
mov i2cs_io_buffer,08h
call i2cs_send_byte ;Send the data
jmp i2cs_exit ;Whatever happened - exit
;*********************** Data Transfer Exit ****************************
;
; This part of I2CS VP may be customized to meet specific needs of
; the interface to the MAIN program
;
i2cs_exit jnb i2cs_start_repeat,:i2cs_exit_1
;Was Sr detected ?
setb I2cs_start_repeat
jmp i2cs_start ;Yes, start all over again
:I2cs_exit_1 jnb i2cs_stop_ok,:i2cs_exit_2
;Was stop condition detected ?
setb i2cs_stop_event ;Yes, set the flags and exit
setb i2cs_transfer_error
jmp :i2cs_finish
:i2cs_exit_2 jnb i2cs_timeout_exp,:i2cs_exit_3
;Was timeout detected ?
setb i2cs_timeout ;Yes, set the flags and exit
setb i2cs_transfer_error
jmp :i2cs_finish
:i2cs_exit_3 jb i2cs_receive_transmit,:i2cs_finish
;Was it data transmission from the Master
snb i2cs_ready ;Yes, check if the Warning should be set
setb i2cs_overflow
setb i2cs_ready
:i2cs_finish ret
;========================== END OF I2CS VP =============================
file: /Techref/scenix/i2cs_vp.src, 24KB, , updated: 1999/2/20 12:23, local time: 2024/11/20 01:12,
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