Peripheral Simulation
For Silicon Laboratories, Inc. C8051F041 — Serial UART 1 (Enhanced Interface)
Simulation support for this peripheral or feature is comprised of:
- Dialog boxes which display and allow you to change peripheral configuration.
- VTREGs (Virtual Target Registers) which support I/O with the peripheral.
These simulation capabilities are described below.
Serial Channel 1 Dialog
The Serial Channel dialog displays and allows you to edit the
configuration of the Serial Interface.
-
Mode displays and allows you to change the serial
interface mode of operation (data bit length and baud rate).
-
SCON1 (Serial Control Register 1) holds the control and
setup information for programming the serial port.
-
SBUF1 (Serial Interface Buffer Register 1) contains the
transmit data to be sent or received data.
-
SADDR1 (Slave Address) when the MCU is a master, this
selects a slave device for communication with another serial
device.
-
SADEN1 (Slave Address Mask) determines which bits of the
slave address are used for communication with another serial
device.
-
SM21 (Enable Serial Port Multiprocessor Communication In
Modes 2 and 3) is set to suppress a receiver interrupt (RI1) if the
received 9th data bit is 0.
-
TB81 (Serial Port Transmitter Bit 9) is the 9th data bit
to be transmitted for serial modes 2 and 3.
-
RB81 (Serial Port Receiver Bit 9) is set for serial
modes 2 and 3 when a 9th bit is received. In serial mode 1, this is
the stop bit.
-
SSTAT1 (Status Mode Select) is set to enable framing
error, receiver overrun and transmitter collision detection.
-
FE1 (Framing Error Detected) is set when an invalid stop
bit (framing error) is detected. This bit must be reset by
software.
-
REN1 (Receiver Enable) is set to enable serial data
input.
BaudRate
-
SMOD1 (Double Baudrate) is set to double the baudrate in
mode 2.
-
RCLK1 (Receive Clock Enable) is set to use Timer 2
overflows for the receive clock. If reset, Timer 1 overflows are
used.
-
TCLK1 (Transmit Clock Enable) is set to use Timer 2
overflows for the transmit clock. If reset, Timer 1 overflows are
used.
-
Transmit & Receive Baudrate is the actual baudrate
for the serial channel. It can be derived from the oscillator
frequency, or generated by Timer 1.
IRQ
-
TI1 (Transmitter Interrupt Flag) is set by hardware for
each character frame transmitted. TI1 is cleared by software.
-
RI1 (Receiver Interrupt Flag) is set by hardware for
each character frame received. RI1 is cleared by software.
SxIN VTREG
Data Type: unsigned int
The SxIN VTREG represents the serial input of the simulated
microcontroller. Values you assign to SxIN are input to the serial
channel 0, 1, 2, and so on. You may assign input using the command
window. For example,
S0IN='A'
causes the simulated microcontroller serial input 0 to receive the
ASCII character A. If you want to use the SxIN VRTEG to simulate
reception of multiple characters, you must be sure to delay for at
least one character time between successive assignments to SxIN. This
may be done using a signal function. For example:
signal void send_cat (void) {
swatch(0.01); /* Wait 1/100 seconds */
S0IN='C'; /* Send a C */
swatch(0.01);
S0IN='A';
swatch(0.01);
S0IN='T';
}
You may use the SxIN VTREG to input more than 8 bits of data. For
example,
S0IN=0x0123
inputs a 9-bit value. This is useful if you use 9-bit serial I/O.
In addition to the SxIN VRTEG, the serial window allows you to input
serial characters by simply typing. Serial characters that are
transmitted byt the simulated microcontroller appear in the serial
window.
SxOUT VTREG
Data Type: unsigned int
The SxOUT VTREG represents the serial output from the simulated
serial port 0, 1, and so on. Whenever the simulated serial port
transmits a character, the value transmitted is automatically
assigned to SxOUT (which is read-only). You may read the value of
SxOUT to determine the character transmitted by your simulated
program. For example,
S0OUT
outputs the value of the last character transmitted by serial port
0. SxOUT Format (16-bit Register)
- Bits 0-7: Data (5, 6, 7, or 8 bits)
- Bit 8: Parity bit Value
- Bit 9: Parity bit Presence (0=Not present, 1=Present)
- Bit 10: Invalid Stop bit (0=Normal, 1=Invalid)
For example:
S0OUT & 0x00FF // Data
S0OUT & 0x0200 // Parity bit is present
S0OUT & 0x0100 // Parity bit value (0=0, 0x0200=1)
Note that you cannot assign values to the SxOUT VTREGs. You may
use the SxOUT VTREG in a script to process transmitted data. For
example,
signal void s0out_sig (void) {
while (1)
{
wwatch(S0OUT); /* wait for something in S0OUT */
printf ("Transmitted a %2.2X\n", (unsigned) S0OUT);
}
}