;======================================================================= ;======================================================================= ; SERIAL PERIPHERAL INTERFACE (SPI) DRIVER ; SPI_ML ; Revision 1.01, 07.05.98 ; Developed by Authentic Engineering for Scenix Semiconductor, Inc. ; Authentic Engineering // http://www.authenticeng.com // ak@silcom.com ; ;======================================================================= ; MASTER MODE LOW RATE SPI DRIVER. SINGLE MASTER CONFIGURATION ; ; This driver provides SPI interface to realtively slow devices. ; The data are transfered by words. Word length is software configurable ; from 1 to 16 bits. ; This driver is a part of a set of SX SPI drivers. It makes use of general ; set of control and status data, developed for the entire family of drivers ; ; CLOCK RATE ; ; The SPI clock rate is driven by the system RTCC. ; Minimum clock rate is limited by the RTCC prescaler setting which should be ; configured by the user. When the RTCC is configured to the minimum rate and ; prescaler is set to 1:2, the SPI clock rate will be equal to 10.2 microsec. ; With the prescaler setting at 1:256 the minimum clock rate will be 1.3056 millisec. ; Maximum clock rate can be achived at RTCC prescaler setting 1:2 ; and RTCC reload register - $80. Desierable configuration of the RTCC prescaler ; must be determined by the user. ; ; Clock (SCLK) PHASE and POLARITY are software configurable. ; ; There are FOUR basic signal lines associated with the SPI protocol: ; Master-Out-Slave-In MOSI signal line ; Master-In-Slave_Out MISO signal line ; Serial Clock SCLK signal line ; Slave Select SS signal line ; Arbitrary pins of the SX-28 can be used for current driver ; ;============================================================================== ; ; INITIALIZATION OF SPI DRIVER ; ; USER program must: ; 1. Provide appropriate configuration of the SX-28 ports. ; ; 2. Define next parameters: ; ; SPI_RAM_BANK - to define the origin in SX RAM banks ; SPI_CLOCK_RATE - to define the clock rate. This byte is used by the driver ; as the RTCC reload register value ; SPI_COMMAND - command and configuration byte. This byte defines: ; - SPI Clock polarity ; - Mode (Master or Slave) ; - Speed (Fast or Slow) ; - Direction (Read/Write) ; - Word Lenght (1 to 16). ; Driver will set the RTCC reload value to the SPI_CLOCK_RATE. The USER ; program must take care about restoration of the RTCC reload value, after ; the SPI driver will complete its operation. ; ; Current driver support only Master Mode and Slow Speed data transfer. ; ; The driver supports 5 commands, specified by the 4 MSBs of the SPI_COMMAND byte ; $0 RESET ; $2 GET WORD in MASTER mode, define FALLING edge ; $6 GET WORD in MASTER mode, define RISING edge ; $A SEND WORD in MASTER mode, define FALLING edge ; $E SEND WORD in MASTER mode, define RISING edge ; Generally for the SPI interface there is no diffrence between GET and SEND, ; however it seems convinient to have different commands, because it allows to customize ; transmit and receive cycles for specific peripherals. Such an examle is presented in Demo #1. ; ; Four LSBs of SPI_COMMAND byte are used for word length definition. ; ; $1 corresponds to one bit length ; ... ; $F corresponds to fifteen bit legth ; $0 corresponds to sixteen bit length ; ; For example, SPI_COMMAND for 12 bit data transfer to the peripheral looks like - $EC ; ; 3. Driver is driven by RTCC interrupts. In order to start data transfer USER program ; must: ; - check that SPI_BUSY flag is cleared ; - set SPI_CLOCK_RATE and SPI_COMMAND ; - enable timer interrupts ; - perform JMP SPI_ENTRY when RTCC interrupt occures ; See example in DEMO #1 ;============================================================================================= ; ; The SPI_STATUS byte provides the information on driver status. It consists of a set of ; flags, described in the comments to the code. ; ; ; SX-28 pin assignment presented below is an example used in 'SPI DEMO #1' ; program. ;======================= CODE START device pins28, pages4,banks8 device turbo, stackx, optionx id 'SPI_ML' ;======================= PIN ASSIGNMENT ;======== example of pin assignment used in DEMO #1 spi_clk_pin = rb.0 ;SPI clock line spi_out_pin = rb.1 ;master_in slave_out line spi_in_pin = rb.2 ;master_out slave_in line spi_ADC_cs_pin = rb.4 ;slave select (ADC) spi_DAC_cs_pin = rb.5 ;slave select (DAC) ;======================== SPI DEVICE RAM ORIGIN org 10h ;example of RAM bank assignment spi_ram_bank = $ spi_command ds 1 bit_wide_0 equ spi_command.0 ;the word length LSB bit_wide_1 equ spi_command.1 ;1_st bit bit_wide_2 equ spi_command.2 ;2_nd bit bit_wide_3 equ spi_command.3 ;the word length MSB fast_ON equ spi_command.4 ;set if FAST MODE master_ON equ spi_command.5 ;set if MASTER MODE rising_ON equ spi_command.6 ;set if RISING EDGE transmit_ON equ spi_command.7 ;set if TRANSMIT ;======================= SPI_STATUS byte spi_status ds 1 spi_ready equ spi_status.0 ;SET when driver is ready (has been initialized) spi_busy equ spi_status.1 ;set when data transfer is active ;spi_master equ spi_status.2 ;SET when SPI master is inited ;spi_slave equ spi_status.3 ;SET when SPI slave is inited spi_command_ERR equ spi_status.4 ;set when command byte containes not supported command spi_tx_complete equ spi_status.5 ;transmit complete spi_rx_complete equ spi_status.6 ;receive complete ;spi_error equ spi_status.7 ;SET when transmit is not finished correctly ;spi_rx_complete and spi_tx_complete flags are needed when two different SS lines were inited simultaneously ;and receive and transmit are controled in the same time. Otherwise, this flag is not extended ;(see SPI_M, SPI_S SPI drivers). ;======================= SPI_STATE byte spi_state ds 1 spi_ms_ON equ spi_state.0 ;set when Master Mode spi_sl_ON equ spi_state.1 ;set when Slave Mode spi_rx_ON equ spi_state.2 ;set when Receive Mode spi_tx_ON equ spi_state.3 ;set when Transmit Mode spi_clk_state equ spi_state.4 ;state of the SPI_CLOCK line; ;spi_timer_IRQ_ON equ spi_state.5 ;SPI transfer under timer IRQ :indicated by rc.0 ;spi_port_IRQ_ON equ spi_state.6 ;SPI transfer under port IRQ :indicated by rc.2 ;======================= SPI_CLOCK byte spi_clk_rate ds 1 ;RTCC reload value spi_buff ds 1 ;SPI I/O shift register (MSByte) spi_buff_low ds 1 ;SPI I/O shift register (LSByte) spi_shift_counter ds 1 ;shift counter spi_bits_total ds 1 ;number of bits to transfer spi_shifts_init ds 1 ;number of initial shifts before transfer spi_clk_counter ds 1 ;used only for DEMO #1 with LTC1594 spi_clks_init ds 1 ;used only for DEMO #1 with LTC1594 ;======================= INTERRUPT START spi_entry bank spi_ram_bank ;SPI driver entry point jb master_ON,master_entry snb rising_ON setb spi_command_ERR ;return from interrupt if wrong command snb transmit_ON setb spi_command_ERR clr spi_command setb spi_ready mov w,spi_clk_rate retiw ;======================= SPI MASTER ENTRY master_entry test spi_shift_counter ;test if this is first entry jnz :master_start :init_master jb spi_ms_ON,:ms_rx_finish ;initialization of the driver (on the first entry) setb spi_busy_ON setb spi_ms_ON sb transmit_ON setb spi_rx_ON snb transmit_ON setb spi_tx_ON snb spi_rx_ON clrb spi_ADC_cs_pin ;this is an example to show how ;generate CS signals for a specific ;peripherals. This is CS for ADC snb spi_tx_ON clrb spi_DAC_cs_pin ;CS for DAC sb rising_ON ;set the SPI_CLK polarity clrb clk_state snb rising_ON setb clk_state sb rising_ON clrb spi_clk_pin snb rising_ON setb spi_clk_pin mov w,spi_command ;set the number of bits to transfer and w,#%00001111 mov spi_bits_total,w mov w,spi_command or w,#%11110000 mov spi_shifts_init,w not spi_shifts_init inc spi_shifts_init mov spi_shift_counter,spi_bits_total clc rl spi_shift_counter mov spi_clk_counter,spi_clks_init ;Example for LTC1594 ADC only clc ;LTC1594 input MX control rl spi_clk_counter ;end of LTC1594 part :set_bit_position test spi_shifts_init ;initial shift before transfer clc ;needed to put MSB of the word to sz ;bit.7 SPI_BUFF position rl spi_buff_low sz rl spi_buff sz djnz spi_shifts_init,:set_bit_position jmp :master_exit ;initialization done, first interrupt exit ;=============================================== Example of the LTC1594 driver :master_start nop test spi_clk_counter ;Example for LTC1594 ADC only jz :master_rx ;Jump to normal master receive xor rb,#%00000001 ;LTC1594 input MX control dec spi_clk_counter ;sclk ADC UP/DOWN jmp :master_exit ;interrupt exit for the ADC MX control ;=============================================== End of ltc1594 example :master_rx jb clk_state,:master_tx ;bit reception from SPI_IN_PIN movb c,spi_in_pin rl spi_buff_low rl spi_buff setb spi_clk_pin dec spi_shift_counter setb clk_state jmp :master_exit ;bit received :master_tx movb spi_out_pin,spi_buff.7 ;bit transmit clrb spi_clk_pin dec spi_shift_counter clrb clk_state jmp :master_exit ;bit transmitted :ms_rx_finish sb spi_rx_ON ;reception completed jmp :ms_tx_finish setb spi_rx_complete ;correct reception finished setb spi_ADC_cs_pin ;disable ADC CS clrb spi_rx_ON jmp :master_finish :ms_tx_finish setb spi_DAC_cs_pin ;disable DAC CS clrb spi_tx_ON ;transmission completed setb spi_tx_complete jmp :master_finish :master_finish clrb spi_ms_ON clr spi_command clrb spi_busy_ON :master_exit mov w,spi_clk_rate retiw ;======================= END OF MASTER MODE SLOW SPI DRIVER
file: /Techref/scenix/spi_ml.src, 9KB, , updated: 1999/2/20 12:23, local time: 2024/11/26 23:32,
18.119.143.45:LOG IN
|
©2024 These pages are served without commercial sponsorship. (No popup ads, etc...).Bandwidth abuse increases hosting cost forcing sponsorship or shutdown. This server aggressively defends against automated copying for any reason including offline viewing, duplication, etc... Please respect this requirement and DO NOT RIP THIS SITE. Questions? <A HREF="http://techref.massmind.org/Techref/scenix/spi_ml.src"> scenix spi_ml</A> |
Did you find what you needed? |
Welcome to massmind.org! |
Welcome to techref.massmind.org! |
.