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[/] [rtfsimpleuart/] [trunk/] [doc/] [rtfSimpleUartUsage.txt] - Rev 15
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To use:
Set the pClkFreq parameter to the frequency of the system
clock (clk_i). This can be done when the core is instanced.
1) set the baud rate value in the clock multiplier
registers (CM1,2,3). A default multiplier value may
be specified using the pClkMul parameter, so it
doesn't have to be programmed at run time. (Note the
pBaud parameter may also be set, but it doesn't work
in all cases due to arithmetic limitations).
2) enable communication by activating the rts, and
dtr signals in the modem control register. These
signals are defaulted to be active on reset, so they
may not need to be set. The pRts and pDtr parameters
may be used to change the default setting.
3) use interrupts or poll the status register to
determine when to transmit or receive a byte of data
4) read / write the transmit / recieve data buffer
for communication.
Notes:
This core only supports a single transmission /
reception format: 1 start, 8 data, and 1 stop bit (no
parity).
The baud rate generator uses a 24 bit harmonic
frequency synthesizer. Compute the multiplier value
as if a 32 bit value was needed, then take the upper
24 bits of the value. (The number of significant bits
in the value determine the minimum frequency
resolution or the precision of the value).
baud rate * 16
value = -----------------------
(clock frequency / 2^32)
eg 38400 * 16
value = -----------------------
(28.63636MHz / 2^32)
= 92149557.65
= 057E1736 (hex)
taking the upper 24 bits
top 24 = 057E17
= 359959
so the value needed to be programmed into the register
for 38.4k baud is 57E17 (hex)
eg CM0 = 0 (not used)
CM1 = 17 hex
CM2 = 7E hex
CM3 = 05 hex
Register Description
reg
0 read / write (RW)
TRB - transmit / receive buffer
transmit / receive buffer
write - write to transmit buffer
read - read from receive buffer
1 read only (RO)
LS - line status register
bit 0 = receiver not empty, this bit is set if there is
any data available in the receiver fifo
bit 1 = overrun, this bit is set if receiver overrun occurs
bit 3 = framing error, this bit is set if there was a
framing error with the current byte in the receiver
buffer.
bit 5 = transmitter not full, this bit is set if the transmitter
can accept more data
bit 6 = transmitter empty, this bit is set if the transmitter is
completely empty
2 MS - modem status register (RO)
writing to the modem status register clears the change
indicators, which should clear a modem status interrupt
bit 3 = change on dcd signal
bit 4 = cts signal level
bit 5 = dsr signal level
bit 6 = ri signal level
bit 7 = dcd signal level
3 IS - interrupt status register (RO)
bit 0-4 = mailbox number
bit 0,1 = 00
bit 2-4 = encoded interrupt value
bit 5-6 = not used, reserved
bit 7 = 1 = interrupt pending, 0 = no interrupt
4 IE - interrupt enable register (RW)
bit 0 = receive interrupt (data present)
bit 1 = transmit interrupt (data empty)
bit 3 = modem status (dcd) register change
bit 5-7 = unused, reserved
5 FF - frame format register (RW)
this register doesn't do anything in the simpleUart
but is reserved for compatiblity with the more
advanced uart
6 MC - modem control register (RW)
bit 0 = dtr signal level output
bit 1 = rts signal level output
7 - control register
bit 0 = hardware flow control,
when this bit is set, the transmitter output is
controlled by the cts signal line automatically
* Clock multiplier steps the 16xbaud clock frequency
in increments of 1/2^32 of the clk_i input using a
harmonic frequency synthesizer
eg. to get a 9600 baud 16x clock (153.6 kHz) with a
27.175 MHz clock input,
value = upper24(9600 * 16 / (27.175MHz / 2^32))
Higher frequency baud rates will exhibit more jitter
on the 16x clock, but this will mostly be masked by the
16x clock factor.
8 CM0 - Clock Multiplier byte 0 (RW)
this is the least significant byte
of the clock multiplier value
this register is not used unless the clock
multiplier is set to contain 32 bit values
9 CM1 - Clock Multiplier byte 1 (RW)
this is the third most significant byte
of the clock multiplier value
this register is not used unless the clock
multiplier is set to contain 24 or 32 bit values
10 CM2 - Clock Multiplier byte 2 (RW)
this is the second most significant byte of the clock
multiplier value
11 CM3 - Clock Multiplier byte 3 (RW)
this is the most significant byte of the multiplier value
12 FC - Fifo control register (RW)
this register doesnt' do anything in the simpleUart
but is reserved for compatibility with the more
advanced uart
13-14 reserved registers
15 SPR - scratch pad register (RW)
SAMPLE SOFTWARE USAGE:
This is an extract of code from Tiny Basic 68000. The UART is in use as the auxilliary
port for tiny basic. The sample is in 68000 assembly language. The sample uses default
settings of the UART, which is 19.2k baud, so there is no initialization required.
;==============================================================================
;==============================================================================
UART EQU 0xFFDC0A00
UART_LS EQU UART+1
UART_CTRL EQU UART+7
;*
;* ===== Output character to the host (Port 2) from register D0
;* (Preserves all registers.)
;*
AUXOUT:
BTST #5,UART_LS ;is port ready for a character?
BEQ AUXOUT ;if not, wait for it
MOVE.B D0,UART ;out it goes.
RTS
;*
;* ===== Input a character from the host into register D0 (or
;* return Zero status if there's no character available).
;*
AUXIN:
BTST #0,UART_LS ;is character ready?
BEQ AXIRET ;if not, return Zero status
MOVE.B UART,D0 ;else get the character
AND.B #0x7F,D0 ;zero out the high bit
AXIRET:
RTS
;==============================================================================
;==============================================================================
EXAMPLE OF CORE INSTANCING:
The core needs to know the clock rate.
rtfSimpleUart #(16666667) uuart
(
// WISHBONE Slave interface
.rst_i(rst), // reset
.clk_i(clk25), // eg 100.7MHz
.cyc_i(sys_cyc), // cycle valid
.stb_i(sys_stb), // strobe
.we_i(sys_we), // 1 = write
.adr_i(cpu_adr), // register address
.dat_i(dbo[7:0]), // data input bus
.dat_o(uart_dbo), // data output bus
.ack_o(uart_ack), // transfer acknowledge
.vol_o(), // volatile register selected
.irq_o(), // interrupt request
//----------------
.cts_ni(1'b0), // clear to send - active low - (flow control)
.rts_no(), // request to send - active low - (flow control)
.dsr_ni(1'b0), // data set ready - active low
.dcd_ni(1'b0), // data carrier detect - active low
.dtr_no(), // data terminal ready - active low
.rxd_i(rxd), // serial data in
.txd_o(txd), // serial data out
.data_present_o()
);
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