Peripheral Simulation
For NXP (founded by Philips) LPC2290 — UART 1
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.
UART 1 Dialog
The Universal Asynchronous Receiver Transmitter (UART 1) Dialog
configures UART 1. A UART transfers serial data to and from external
devices and the ARM controller. The UART can be configured in a
variety of ways to suit the external serial device.
Line Control Group
-
LCR (Line Control Register) displays the combined
control information for the following:
-
Word Length selects the data character length of 5, 6, 7
or 8 bits per character.
-
Stop Bits (Number of Stop Bits) selects the number of
stop bits to be sent with each character.
-
Parity selects odd, even or no (forced "0" or "1")
parity.
-
DLAB (Divisor Latch Access Bit) is set to calculate the
baud rate based on the Divisor Latch register (DLL and DLM)
values.
-
Break Control is set to enable transmission of a
Break.
-
Parity Enable is set to enable parity generation and
checking.
Line Status Group
-
Receiver Data Ready (RDR) set when the UART 1 receives
at least 1 character and the receiver hold register is not
empty.
-
Overrun Error (OE) set if the controller detects an
overrun condition since the last status reset command.
-
Parity Error (PE) set if the controller detects at least
1 false parity bit since the last status reset command.
-
Framing Error (FE) set if the controller detects a
framing error since the last status reset command.
-
Break Interrupt (BI) is set when a Break condition
occurs while receiving data.
-
Tx Holding Register Empty (THRE) is set when the
transmission hold register is empty.
-
Transmitter Empty (TEMT) set if there are no characters
in the transmitter.
-
Error in Rx FIFO (RXFE) is set when the receiver detects
any error (parity, framing, overrun or break).
Interrupt Enable Group
-
IER (Interrupt Enable Register) contains the RBR, THRE
and Line Status Enable bits.
-
RBR IE (Receive Buffer Register Interrupt Enable) is set
to enable the Receive Data Available interrupt.
-
THRE IE (Transmit Hold Register Empty Interrupt Enable)
is set to enable the Transmitter Empty (THRE) interrupt.
-
Rx Line Status EI (Line Status Interrrupt Enable) is set
to enable Line Status interrupts.
-
Modem Status EI (Modem Status Interrrupt Enable) is set
to enable modem interrupts.
Interrupt ID & FIFO Control Group
-
IIR/FCR (Interrupt Identification/FIFO Control
Register)
-
Interrupt displays the interrupt type(Line Status, THRE,
RDA, Character Time-out).
-
FIFO Enable (FIFO Enable) is set to clear and enable the
receive and transmit FIFOs.
-
Rx Trigger (Rx Trigger Level Select) sets the number of
characters required to trigger a receive interrupt.
- Rx FIFO Reset clears the receive FIFO buffer.
- Tx FIFO Reset clears the transmit FIFO buffer.
Divisor Latch Group
-
DLL (Divisor Latch LSB Register) contains the lower
8-bit value that the MCU divides into the MCU clock (PCLK) to
generate the UART baud rate.
-
DLM (Divisor Latch MSB Register) contains the upper
8-bit value that the MCU divides into the MCU clock (PCLK) to
generate the UART baud rate.
- Baudrate is the computed UART baud rate.
Receiver & Transmitter Registers Group
-
RBR/THR (Receiver Buffer Register/Transmitter Hold
Register) when receiving, is the oldest character received. When
transmitting, it is the newest character to be transmitted.
Scratch Pad Group
-
SCR (Scratch Pad Register) has no effect on the UART
operation. It can be used for general purpose storage.
Modem Control Group
-
MCR (Modem Control Register) contains the DTR, RTS and
Loobback modem controls.
-
DTR Control (Data Terminal Ready Control) is the DTR
modem output level.
-
RTS Control (Request To Send Control) is the RTS modem
output level.
-
Loopback Mode is set to perform diagnostic loopback
testing.
Modem Status Group
-
MSR (Modem Status Register) contains the following
status from the modem input signals:
-
Delta CTS (Delta Clear to Send) is set when the state of
modem input CTS changes.
-
Delta DSR (Delta Data Set Ready) is set when the state
of modem input DSR changes.
-
Trailing Edge RI (Trailing Edge Ring Indicator) is set
when a low-to-high transition occurs on the RI input.
-
Delta DCD (Delta Data Carrier Detect) is set when the
state of modem input DCD changes.
-
CTS (Clear To Send) is the complement of the CTS input
signal.
-
DSR (Data Set Ready) is the complement of the CTS input
signal.
-
RI (Ring Indicator) is the complement of the CTS input
signal.
-
DCD (Data Carrier Detect) is the complement of the CTS
input signal.
Modem Lines Group This group displays the following modem
signal levels.
- RTS1 Request To Send
- CTS1 Clear To Send
- DTR1 Data Terminal Ready
- DSR1 Data Set Ready
- DCD1 Data Carrier Detect
- RI1 Ring Indicator
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 data (5-8 bits), parity, frame
error and break condition. SxIN Format (16-bit Register)
- Bits 0-7: Data (5, 6, 7, or 8 bit)
- 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:
S0IN=0x0074 // Data = 0x74, No Parity bit
S0IN=0x0274 // Data = 0x74, Parity bit = 0
S0IN=0x0374 // Data = 0x74, Parity bit = 1
S0IN=0x0474 // Data = 0x74, No Parity bit
// Invalid Stop bit - Frame Error
S0IN=0x0400 // Break Condintion
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);
}
}
SxTIME VTREG
Data Type: unsigned char
The SxTIME VTREG allows you to control the timing of the simulated
serial port 0, 1, and so on.
-
A value of 1 (which is the default) indicates that the serial
port timing is identical to the target hardware. Use this value
when you want to see the effects of baud rate on the serial port
I/O.
-
A value of 0 indicates that all serial input and output occur
instantaneously. Use this value when you don't care about any baud
rate effects or when you want serial output to be fast.
For example:
S0TIME = 0 /* Set Serial Port 0 for FAST timing */
S0TIME = 1 /* Set Serial Port 0 for accurate timing */