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1 Design Brief

UART is short for Universal Asynchronous Receiver and Transmitter. Used for communication between serial input and serial output devices. Serial transmission comes at the cost of speed, in exchange for a reduction in cost and complexity of wiring. UART provides synchronization of serial asynchronous received data, parallel-to-serial and serial-to-parallel data conversion of the transmitter and receiver, for digital systems that need to convert serial data streams to parallel data, these functions Is essential. Synchronization of the serial data stream is achieved by adding start and stop bits to the transmitted data to form a data character. Data integrity is achieved by appending a parity bit to the data character, which is provided by the receiver Check this parity bit to check whether there is any transmission bit error. It is mainly composed of data bus interface, control logic, baud rate generator, sending part and receiving part.

1.1 Protocol

The communication protocol is the regulation of the data transmission method, including the definition of the data format and the definition of the data bits. Both parties must follow a unified communication protocol. The following is the transmission format of character data specified by the asynchronous serial communication protocol. In asynchronous communication, data is transmitted frame by frame (including a character code or a byte of data), and the data format of each frame is shown in the following figure

In the frame format, a character is composed of four parts: start bit, data bit, parity bit, and stop bit.

 (1)、Start bit

The start bit (low level "0") occupies only one bit and informs the receiving device that a character to be received starts to arrive. Logic 1 state when no data is being transmitted on the communication line. When the sending device wants to send a character data, first add a logic 0 signal, this logic low level is the start bit, the receiving end continuously detects the state of the line, the receiving device detects this logic low level and starts Ready to accept data bit signals. The start bit of the character is also used to synchronize the clock of the receiving end to ensure that the subsequent reception can be performed correctly. The start bit enables the device to synchronize, and both parties must coordinate the synchronization before transmitting the data bit.

(2)、Data bit

The start bit is immediately followed by the data bit, which can be 5, 6, 7, or 8 bits. When the receiving device receives the start bit, it immediately receives the data bit. These data bits are received into the shift register and constitute the transmitted data characters. In the transmission of character data, the data bits are sent from the least significant bit and are sequentially converted into data in the receiving device.

(3)、Parity bit

After the data bits are sent, parity bits can be sent. The parity bit only occupies one bit, and the parity bit can be omitted, or this bit can be omitted, or this bit can also be used to determine the nature of the information represented by the characters in this frame (address / data, etc.) Parity check belongs to limited error detection, and both parties in communication must agree on a consistent parity check method. If you select even parity, the number of logic 1s that make up the data bits and parity bits must be even; if you select odd parity, then the number of logic 1s must be odd.

(4)、Stop bit convention

The stop bit is sent after the parity bit or data bit (when there is no parity check). The stop bit is the end mark of a character data, which can be a high level of 1, 5, or 2 bits. After receiving the stop bit, the receiving end indicates that the previous character has been transmitted, and at the same time, it is also ready to receive the next character. If it receives 0 again, the new character begins to transmit. If the stop bit is not followed by a character, the line level is kept high ("1"), which is the idle bit. After the receiving device receives the stop bit, the logic 1 state is restored on the communication line until the start bit of the next character data arrives.

(5)、Baud rate setting

All bit signals transmitted on the communication line maintain a consistent signal duration, and the signal duration of each bit is determined by the data transmission speed, that is, measured by how many binary bits per second, this speed is called the baud rate. If the data is transmitted on the communication line with 300 binary bits per second, the transmission speed is 300 baud, which is usually recorded as 300 b/s.

(6)、Handshake signal agreement

When the computer and modem exchange data, they often use some signal lines as a prerequisite for exchanging data. When the conditions are met, the data is allowed to be transmitted; when the conditions are not met, they are in a waiting state and wait until the signal that allows data transmission occurs. Data transmission begins again.

1.2 Serial-to-parallel conversion

Serial communication is to convert the parallel data to be transmitted inside the computer into serial data and transmit it through a communication line; then convert the received serial data into parallel data and send it to the computer. Before the computer serially sends data, the parallel data inside the computer is sent to the shift register and shifted out bit by bit, converting the parallel data into serial data. As shown below

When receiving data, the serial data from the communication line is sent to the shift register, and after being shifted and saved to 8 bits, it is sent to the computer in parallel

1.3 Data sampling

When the receiver receives data, the internal clock frequency of the UART is often higher than the external data input frequency. When the receiver starts to receive the signal, if the frequency of the internal clock is close to or less than the external data transmission frequency, when the receiver receives data, it is likely that the data will not be collected at the edge of data sampling, or the wrong data will be collected. The sampling frequency can be set to 8 times, 16 times the external data transmission frequency. The UART uses 16 times the external clock frequency, and the sampled waveforms are as follows:

In this example, through the research of the UART bus protocol, the UART Controller IP is designed to familiarize with the design and verification of the UART IP core

2 Design specifications

l  Support AMBA  APB2.0  BUS interface.

l  Support 5/6/7/8 bits data (packet) transmit and receive.

l  Support odd, even or none parity bit generation and declaration.

l  Support 1, 1.5 or 2 stop bits generation and declaration.

l  Support baud rate configuration (4800bps, 9600bps, 38400bps and 115200bps).

l  Support 4 types depth RX FIFO and TX FIFO.

l  Support software reset and enable.

l  Support polling status – FIFO full and empty, parity check error, stop bit check error.

l  Programmable interrupt enable control.

l  Support the SW write clear the interrupt.

.

3  I/O Ports Description

3.1 APB Register Bus Interface

Name

Direction

Width

Description

PSEL

Input

1

APB Bus Selected

Active high to select CTRL group registers.

PWRITE

Input

1

APB Bus Write Enable

Active high to enable register bus write operation.

Active low to enable register bus read operation.

PENABLE

Input

1

APB Bus Enable

Active high to select CTRL group registers.

PWDATA

Input

32

APB Write Data Bus

32 bit data with [31] is most significant bit.

PADDR

Input

5

APB Bus Address

5 bit address bus with [4] is most significant bit.

PRDATA

Output

32

APB Read Data Bus

Register read data bus, [31] is most significant bit. Valid when SL_APB_ACK is active.

3.2 Interrupt Line

Name

Direction

Width

Description

INT_B

Output

1

Interrupt

Low active. When finished a operation, INT_B will be active, such as received a packet or error case happened.

3.3 System Clock and Reset

Name

Direction

Width

Description

SYSCLK

Input

1

System Clock

Free running clock, all registers must be synchronous with SYSCLK.

RST_B

Input

1

System Reset

Low active. When this pin is asserted, all flip-flops must be reset to their default value.

3.4 UART interface

Name

Direction

Width

Description

RX

Input

1

Serial Data input

TX

output

1

Serial Data output

4 Registers File

4.1 Registers List

Address

Name

Access

Description

5’h00

LCR

RW

Line Control Register

5’h01

SER

RW

Software Enable Register

5’h02

BAUD_CNT

RW

Baud-rate Configuration Register

5’h03

LSR

RW

Line State Register

5’h04

RX_FIFO

RO

RX FIFO Register

5’h05

TX_FIFO

RW

TX FIFO Register

4.2 Line Configuration Register (LCR, Addr = 5’h0)

Default value: 0x0000_0000

Register Bits

Name

Function Description

1:0

WORD_SEL

Word Length Select of the UART

  00 : 8 bit data transmit and receive

  01 : 7 bit data transmit and receive

  10 : 6 bit data transmit and receive

  11 : 5 bit data transmit and receive

3:2

STOP_SEL

Stop Bit Length of the UART

  00 : 1 cycle stop bit

  01 : 1.5 cycle stop bit

  10 : 2 cycle stop bit

  Default : 1 cycle stop bit

5:4

PTY_SEL

Parity Select of the UART

  00 : even parity

  01 : odd parity

  10 : no parity

  Default : even parity

31:6

RSV

Reserved

4.3 Software Enable Register (SER, Addr = 5’h1)

Default Value: 0x0000_003f

Register Bits

Name

Function Description

0

RX_DONE_EN

Data Ready Interrupt Enable

Low active, when this bit is 1, Data Ready will not assert interrupt.

1

TX_DONE_EN

Transmitted Complete Interrupt Enable

Low active, when this bit is 1, Transmitted Complete will not assert interrupt.

2

PTY_ERR_EN

Parity Error Interrupt Enable

Low active, when this bit is 1, Parity Error will not assert interrupt.

3

STOP_ERR_EN

Stop Bit Error Interrupt Enable

Low active, when this bit is 1, Stop Bit Error will not assert interrupt.

4

RX_FULL_EN

RX FIFO Full interrupt Enable

Low active, when this bit is 1, TRX FIFO full will not assert interrupt.

5

TX_EMPTY_EN

TX FIFO Empty interrupt Enable

Low active, when this bit is 1, TX FIFO empty will not assert interrupt.

6

SW_RST

Soft Reset UART

High active , the UART will reset  when Master writing 1 to this bit

7

RX_EN

Receiver FSM Stop

Low active , the Receiver will not work when this bit is 1

8

TX_EN

Transmitter FSM Stop

Low active , the Transmitter will not work when this bit is 1

31:9

RSV

Reserved

4.4 Baud-rate Configuration Register (BAUD_CNT, Addr = 5’h2)

Default Value: 0x0000_0000

Register Bits

Name

Function Description

31:0

BAUD_CNT

Baud Rate configure data

Store the count value of baud rate generation

4.5 Line State Register (LSR, Addr = 5’h3)

Default value: 0x0000_0000

Register Bits

Name

Function Description

0

RX_DONE

Data Ready

High active, the flag of the interrupt that Received a complete packet. The interrupt will be cleaned when this bit is written 0 by master.

1

TX_DONE

Transmitted Data Complete

High active, the flag of the interrupt that Transmitted a complete packet. The interrupt will be cleaned when this bit is written 0 by master.

2

PTY_ERR

Parity Error

High active. The interrupt flag that Parity error. The interrupt will be cleaned when this bit is written 0 by master.

3

STOP_ERR

Stop Bit Error

High active. The interrupt flag that Stop bit error. The interrupt will be cleaned when this bit is written 0 by master.

4

RX_FULL

RX FIFO Full

High active.  The interrupt flag that RX FIFO full. The interrupt will be cleaned when master reads out a data once.

5

RX_EMPTY

RX FIFO Empty

High active. The flag that the RX FIFO empty

6

TX_FULL

TX FIFO Full

High active. The flag that the TX FIFO full

7

TX_EMPTY

TX FIFO Empty

High active.  The flag of the interrupt that TX FIFO empty. The interrupt will be cleaned when master writes a data once.

31:8

RSV

Reserved

4.6 RX FIFO Register (RX_FIFO, Addr = 5’h4)

Default Value: 0x00

Register Bits

Name

Function Description

7:0

RX_FIFO

Read Data Buffer

The depth is 4.

Store the data written to Receiver buffer register.

4.7 TX FIFO Register (TX_FIFO, Addr =5’h5)

Default Value: 0x00

Register Bits

Name

Function Description

7:0

TX_FIFO

Write Data Buffer

The depth is 4.

Store the data written to Transmitter buffer register.

5 Functional Description

5.1 UART Structure

Interface model: communicate with CPU, configure the UART.

FIFO: store data which will be transmitted or received

Transmit/Receive register: transmit or receive the data stored in the FIFO.

Baud rate occur: occur the clock for transmitter and receiver

5.2  UART Receiver FSM

Current State

Function

Next Status

Jump Condition

IDLE

Wait start signal.

SHIFT

Start bit detected right and receiver buffer register isn’t full

IDLE

RX_EN enable or start bit not detected

SHIFT

Receive data

STOP

Last data bit and parity disable

PARITY

Last data bit and parity enable

SHIFT

Not last data bit

PARITY

Odd/even parity check

STOP

Parity check done

STOP

Stop bit check

IDLE

Check right, then jump to IDLE

Or check right wrong ,INT_B enable, then jump to IDLE

5.3 UART Transmitter FSM

Current State

Function

Next Status

Jump Condition

IDLE

Wait for transmitting

START

TX_FIFO is not empty

IDLE

TX_FIFO is empty or TX_EN enable

START

Transmit start bit

SHIFT

Transmit done

SHIFT

Transmit data

STOP_1BIT

Last data bit and parity disable

PARITY

Last data bit and parity enable

SHIFT

Not last data bit

PARITY

Parity bit

STOP_1BIT

Finished the parity configuration

STOP_1BIT

1 stop bit

START

1.5/2 stop bit disable

STOP_HALFBIT

1.5 stop bit enable

STOP_2BIT

2 stop bit enable

STOP_HALFBIT

1.5 stop bit

START

Finished the stop bit configuration

STOP_2BIT

2 stop bit

START

Finished the stop bit configuration

5.4 FIFO

FIFO is very important to this design as all data are transferred by it. Following is the 2-pointer FIFO

It is a 4X8-bit FIFO, so the width of both write pointer (WP) and read pointer (RP) are 3 bits. Read data once, RP adds one, while write data once, WP adds one.

When write, first write data, then move the WP pointer; when read, first read data, then move the RP pointer.

When WP = RP indicates FIFO is empty.

When WP [2] = (~RP [2]) and WP [1:0] = RP [1:0] shows this is a full FIFO

5.5 Timing Figures

Receive the serial data from RX

Transmit the serial data to TX

6 SOC integration

6.1  Hardware platform implementation of UART controller IP design experiment project

The UART controller IP core design is the AMBA APB bus interface, and our FBIO Wrapper is the AMBA AXI bus interface, which cannot be directly connected together, and requires an AXI2ABP Bridge to connect;

This experiment uses the FPGA daughter board supporting the Plus1 7021 SOC practice platform to complete the relevant experiment. The experiment is carried out in loopback mode, which is to connect the TX and RX of the UART controller IP core design; The development tool of FPGA daughter board uses XILINX's Vivado integrated development environment (version number is 2018.3); in order to facilitate the connection of the user's own verification IP to the SOC system for verification, this experiment provides the corresponding design reference basic files, as follows

The corresponding connection between the design case and the pin connection of the SP7021 motherboard and FPGA daughter board is shown in the following table: 1: U20B on the main board is connected to J2 of the FPGA daughter board (Pin pin corresponding, such as 1-51 ...), providing the data transmission channel between the Plus1 main chip on the main board and the FPGA

Design Demo

FPGA daughter board

SP7021 mother board

uart_apb

J2

U1E

U20B

Top Port Name

Schematic Name

FPGA I/O

Schematic Name

 

1

GND

 

51

GND

 

2

GND

 

52

GND

FPGA_PAD[0]

3

B34_L24_N

T8

53

FBIO_PAD_0

FPGA_PAD[43]

4

B34_L24_P

R8

54

FBIO_PAD_1

 

5

VIN

 

55

VCC(3.3V)

 

6

VCCIO34

 

56

VCC(3.3V)

FPGA_PAD[1]

7

B34_L21_N

V9

57

FBIO_PAD_2

FPGA_PAD[42]

8

B34_L21_P

U9

58

FBIO_PAD_3

FPGA_PAD[2]

9

B34_L18_N

N6

59

FBIO_PAD_4

FPGA_PAD[41]

10

B34_L18_P

M6

60

FBIO_PAD_5

FPGA_PAD[3]

11

B34_L22_N

U6

61

FBIO_PAD_6

FPGA_PAD[40]

12

B34_L22_P

U7

62

FBIO_PAD_7

FPGA_PAD[4]

13

B34_L20_N

V6

63

FBIO_PAD_8

FPGA_PAD[39]

14

B34_L20_P

V7

64

FBIO_PAD_9

FPGA_PAD[5]

15

B34_L23_N

T6

65

FBIO_PAD_10

FPGA_PAD[38]

16

B34_L23_P

R7

66

FBIO_PAD_11

FPGA_PAD[6]

17

B34_L10_N

V4

67

FBIO_PAD_12

FPGA_PAD[37]

18

B34_L10_P

V5

68

FBIO_PAD_13

FPGA_PAD[7]

19

B34_L19_P

R6

69

FBIO_PAD_14

FPGA_PAD[36]

20

B34_L19_N

R5

70

FBIO_PAD_15

FPGA_PAD[8]

21

B34_L8_P

U4

71

FBIO_PAD_16

FPGA_PAD[35]

22

B34_L8_N

U3

72

FBIO_TCLK

FPGA_PAD[9]

23

B34_L9_N

V2

73

FBIO_RCLK

FPGA_PAD[34]

24

B34_L9_P

U2

74

FBIO_PAD_17

FPGA_PAD[10]

25

B34_L7_N

V1

75

FBIO_PAD_18

FPGA_PAD[33]

26

B34_L7_P

U1

76

FBIO_PAD_19

FPGA_PAD[11]

27

B34_L13_P

N5

77

FBIO_PAD_20

FPGA_PAD[32]

28

B34_L13_N

P5

78

FBIO_PAD_21

FPGA_PAD[12]

29

B34_L12_P

T5

79

FBIO_PAD_22

FPGA_PAD[31]

30

B34_L12_N

T4

80

FBIO_PAD_23

FPGA_PAD[13]

31

B34_L11_N

T3

81

FBIO_PAD_24

FPGA_PAD[30]

32

B34_L11_P

R3

82

FBIO_PAD_25

FPGA_PAD[29]

33

B34_L14_P

P4

83

FBIO_PAD_26

FPGA_PAD[28]

34

B34_L14_N

P3

84

FBIO_PAD_27

FPGA_PAD[14]

35

B34_L16_N

N4

85

FBIO_PAD_28

FPGA_PAD[27]

36

B34_L16_P

M4

86

FBIO_PAD_29

FPGA_PAD[15]

37

B34_L17_N

T1

87

FBIO_PAD_30

FPGA_PAD[26]

38

B34_L17_P

R1

88

FBIO_PAD_31

FPGA_PAD[16]

39

B34_L15_N

R2

89

FBIO_PAD_32

FPGA_PAD[25]

40

B34_L15_P

P2

90

FBIO_PAD_33

FPGA_PAD[17]

41

B34_L3_N

N1

91

FBIO_PAD_34

FPGA_PAD[24]

42

B34_L3_P

N2

92

FBIO_PAD_35

FPGA_PAD[18]

43

B34_L1_N

M1

93

FBIO_PAD_RSTB

FPGA_PAD[23]

44

B34_L1_P

L1

94

EXT0_INT

 

45

VCCIO34

 

95

VCC(3.3V)

 

46

VIN

 

96

VCC(3.3V)

FPGA_PAD[19]

47

B34_L4_P

M3

97

EXT1_INT

FPGA_PAD[20]

48

B34_L4_N

M2

98

 

 

49

GND

 

99

GND

 

50

GND

 

100

GND

2: U20A on the motherboard is connected to J1 of the FPGA daughter board (Pin pins correspond to one, such as 1-1 ...), and the 42 pin IO (3.3v) of FPGA Bank 35 is extended via J17 for users to use

Design Demo

FPGA daughter board

SP7021 mother board

uart_apb

J1

U1F

U20A

J17

Top Port Name

Schematic Name

FPGA I/O

Schematic Name

Schematic Name

 

1

GND

 

1

GND

3

GND

 

2

GND

 

2

GND

4

GND

 FPGA_TX

3

B35_L23_N

K1

3

B35_L23_N

5

B35_L23_N

 

4

B35_L23_P

K2

4

B35_L23_P

6

B35_L23_P

 

5

VIN

 

5

VIN

1

VCC

 

6

VCCIO35

 

6

VCCIO35

2

VCC

 FPGA_RX

7

B35_L15_N

G2

7

B35_L15_N

7

B35_L15_N

 

8

B35_L15_P

H2

8

B35_L15_P

8

B35_L15_P

 

9

B35_L13_N

F3

9

B35_L13_N

9

B35_L13_N

 

10

B35_L13_P

F4

10

B35_L13_P

10

B35_L13_P

 

11

B35_L12_N

D3

11

B35_L12_N

11

B35_L12_N

 

12

B35_L12_P

E3

12

B35_L12_P

12

B35_L12_P

 

13

B35_L22_P

J3

13

B35_L22_P

13

B35_L22_P

 

14

B35_L22_N

J2

14

B35_L22_N

14

B35_L22_N

 

15

B35_L17_N

G1

15

B35_L17_N

15

B35_L17_N

 

16

B35_L17_P

H1

16

B35_L17_P

16

B35_L17_P

 

17

B35_L18_N

E1

17

B35_L18_N

17

B35_L18_N

 

18

B35_L18_P

F1

18

B35_L18_P

18

B35_L18_P

 

19

B35_L14_N

D2

19

B35_L14_N

19

B35_L14_N

 

20

B35_L14_P

E2

20

B35_L14_P

20

B35_L14_P

 

21

B35_L16_P

C2

21

B35_L16_P

21

B35_L16_P

 

22

B35_L16_N

C1

22

B35_L16_N

22

B35_L16_N

 

23

B35_L9_N

A1

23

B35_L9_N

23

B35_L9_N

 

24

B35_L9_P

B1

24

B35_L9_P

24

B35_L9_P

 

25

B35_L10_P

B3

25

B35_L10_P

25

B35_L10_P

 

26

B35_L10_N

B2

26

B35_L10_N

26

B35_L10_N

 

27

B35_L8_N

A3

27

B35_L8_N

27

B35_L8_N

 

28

B35_L8_P

A4

28

B35_L8_P

28

B35_L8_P

 

29

B35_L11_N

D4

29

B35_L11_N

29

B35_L11_N

 

30

B35_L11_P

D5

30

B35_L11_P

30

B35_L11_P

 

31

B35_L3_N

A5

31

B35_L3_N

31

B35_L3_N

 

32

B35_L3_P

A6

32

B35_L3_P

32

B35_L3_P

 

33

B35_L2_N

B6

33

B35_L2_N

33

B35_L2_N

 

34

B35_L2_P

B7

34

B35_L2_P

34

B35_L2_P

 

35

B35_L7_N

B4

35

B35_L7_N

35

B35_L7_N

 

36

B35_L7_P

C4

36

B35_L7_P

36

B35_L7_P

 

37

B35_L1_N

C5

37

B35_L1_N

37

B35_L1_N

 

38

B35_L1_P

C6

38

B35_L1_P

38

B35_L1_P

 

39

B35_L5_N

E5

39

B35_L5_N

39

B35_L5_N

 

40

B35_L5_P

E6

40

B35_L5_P

40

B35_L5_P

 

41

B35_L6_N

D7

41

B35_L6_N

41

B35_L6_N

 

42

B35_L6_P

E7

42

B35_L6_P

42

B35_L6_P

 

43

B35_L19_P

G6

43

B35_L19_P

43

B35_L19_P

 

44

B35_L19_N

F6

44

B35_L19_N

44

B35_L19_N

 

45

VCCIO35

 

45

VCCIO35

49

VCC

 

46

VIN

 

46

VIN

50

VCC

 

47

B35_L4_N

C7

47

B35_L4_N

45

B35_L4_N

 

48

B35_L4_P

D8

48

B35_L4_P

46

B35_L4_P

 

49

GND

 

49

GND

47

GND

 

50

GND

 

50

GND

48

GND

6.2 Implementation of System Software Platform for UART Controller IP Design Experiment Project

In the IDE environment, as shown below, select the sp7021 project name, click the right mouse button and select Copy in the pop-up menu

Next, select the sp7021 project name again

Click the right mouse button and select Paste in the pop-up menu, the following picture appears

Fill in the uart_apb in the Project name box to complete the establishment of the uart_apb project name and directory, as shown below

Next, you need to copy all the files and folders under the installation directory \SP7021\example\uart_apb to the uart_apb project directory built above (the path is: installation directory \SP7021\workspace\uart_apb\), the file with the same name is selected to be overwritten, so that the UART The program codes main.c; uart.c; uart.h required for the IP design practice of the controller are placed in the following paths:

1) In the install directory \SP7021\workspace\uart_apb\main.c

2) In the install directory \SP7021\workspace\uart_apb\testapi\util\uart.c

3) In the install directory \SP7021\workspace\uart_apb\include\util\uart.h

Finally, as shown in the figure below, the mouse selects the red box 1, then clicks the right mouse button to appear the drop-down menu, and then selects the red box 2, refresh the copy action just now, so that the file just copied can be displayed in the IDE environment

main.c

int main(void)

{

    printf("Build @%s, %s\n", __DATE__, __TIME__);

    hw_init();

    sys_init();

    fbio_init();

    uart_ctl();

    disp_hdmi_init();

    uart_interrupt_init(); /*uart interrupt configure */

    sp_interrupt_setup(); /* system interrupt manager module init */

    printf("UART IP test ready ");

    while(1)

{

        unsigned int i;

        for (i = 0; i < 256; i++)

            {

               while(1)

                {

                   if((uart_reg->LSR&0x20)==0x20)

                  {

                     uart_reg->SER=0x3f;

                     uart_reg->TX_FIFO=i;

                     printf("@tx_data [%d]\n", i);

                     uart_reg->SER=0x3e;

                      break;

                   }

                }

            }

    }

}

Compared with the digital tube control IP experiment, the uart_ctl () function is added to complete the configuration and initialization of the UART, as explained below.

void uart_ctl()

{

    uart_reg->LCR=0x20;

    printf("@LCR[%x]\n", temp);

    uart_reg->SER=0x3e;

    printf("@SER[%x]\n", temp);

    ///////////////// system clock is 65.057MHz//////65057000/16/buad//////

    uart_reg->BUAD_CNT=0x1A9; //9600

    printf("@BUAD_CNT[%x]\n", temp);

}

Realize the configuration and initialization operation of UART control IP as follows:

uart_reg->LCR=0x20;

Set UART to 8bit data bit, 1bit stop bit, no parity bit;

uart_reg->SER=0x3e;

Set the UART interrupt to: allow interrupts to be generated after receiving data is complete; disable interrupts to be generated after data transmission is complete; prohibit stop bits from receiving data and generate interrupts when the check bit is wrong; disable interrupts when receiving data FIFO is full; Generate an interrupt;

uart_reg->BUAD_CNT=0x1A9;

Set the UART baud rate to 9600;

The following introduces while (1) loop

if((uart_reg->LSR&0x20)==0x20) : Judge that the received data FIFO is empty

uart_reg->SER=0x3f; Forbid receiving data interruption;

uart_reg->TX_FIFO=i; Send data i to TX FIFO;

uart_reg->SER=0x3e;  Allow interrupt generation after receiving data

uart.c

#include "common_all.h"

#include "cache.h"

#include "sp_interrupt.h"

#define FPGA_EXT0_INT  (29)

#define FPGA_EXT1_INT  (30)

static unsigned int g_repeat_cnt = 0;

unsigned int rx_data;

void fpga_ext0_interrupt_control_mask(int enable)

void fpga_ext1_interrupt_control_mask(int enable)

static void fpga_ext0_isr_cfg()

static void fpga_ext1_isr_cfg()

void fpga_ext0_callback(void)

void fpga_ext1_callback(void)

void uart_interrupt_init ()

void fpga_ext1_test_init()

Compared with the LED.c of the LED control IP experiment, the structure is similar, the difference is that the interrupt handler is different, as explained below

void fpga_ext0_callback(void)

{

    rx_data=uart_reg->RX_FIFO;

    printf("@rx_data [%d]\n", rx_data);

    uart_reg->LSR=0x0;

}

The role of this interrupt handler: take the 8bit data received by the RX FIFO; then clear the status flag bit of this interrupt, so that the serial reception and transmission experiments of 1byte data are completed.

uart.h

#ifndef __FPGAINT_H__

#define __FPGAINT_H__

#define  FBIO_BASE_ADDR 0x70000000

typedef struct uart_reg_s {

    unsigned long LCR;

    unsigned long SER;

    unsigned long BUAD_CNT;

    unsigned long LSR;

    unsigned long RX_FIFO;

    unsigned long TX_FIFO;

} uart_reg_t;

extern uart_reg_t *uart_reg;

void uart_interrupt_init ();

void fpga_ext1_test_init();

#endif // __FPGAINT_H__

Defined UART control IP related registers

6.3 Run Program code

After compile in the Plus1 IDE environment, download to the platform and see the following information in the terminal window

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