Skip to end of metadata
Go to start of metadata

You are viewing an old version of this page. View the current version.

Compare with Current View Page History

« Previous Version 4 Next »

1 设计简介

SPI(Serial Peripheral Interface)串行外围设备接口总线系统,是一种高速的,全双工,同步的通信总线,它可以使MCU与各种外围设备以串行方式进行通信以交换信息。SPI总线系统可直接与各个厂家生产的多种标准外围器件直接接口,主要应用在 EEPROM,FLASH,实时时钟,AD转换器,还有数字信号处理器和数字信号解码器之间。

SPI总线系统接口信号如下:

(1)SDO     –主设备数据输出,从设备数据输入

(2)SDI      –主设备数据输入,从设备数据输出

(3)SCLK    –时钟信号,由主设备产生

(4)CS       –从设备使能信号,由主设备控制

SPI的通信原理简单,以主从方式工作,这种模式通常有一个主设备和一个或多个从设备,需要4根线,并且在芯片的管脚上只占用四根线,节约了芯片的管脚,同时为PCB的布局上节省空间,提供方便,正是出于这种简单易用的特性,现在越来越多的芯片集成了这种通信协议。。

其中CS是控制芯片是否被选中的,也就是说只有片选信号为预先规定的使能信号时(高电位或低电位),对此芯片的操作才有效。这就允许在同一总线上连接多个SPI设备成为可能。接下来就负责通讯的3根线了。SCLK信号线只由主设备控制,从设备不能控制信号线。SPI是串行通讯协议,数据是一位一位的传输的。由SCLK提供时钟脉冲,SDI,SDO则基于此脉冲完成数据传输。数据输出通过 SDO线,数据在时钟上升沿或下降沿时改变,在紧接着的下降沿或上升沿被读取。完成一位数据传输,输入也使用同样原理。这样,在至少8次时钟信号的改变(上沿和下沿为一次),就可以完成8位数据的传输。

SPI还是一个数据交换协议:因为SPI的数据输入和输出线独立,所以允许同时完成数据的输入和输出。不同的SPI设备的实现方式不尽相同,主要是数据改变和采集的时间不同,在时钟信号上沿或下沿采集有不同定义,具体请参考相关器件的文档。

本实践所设计控制器遵循标准通用的SPI Flash控制协议,可实现多个厂家的SPI Flash device操作,配套的测试扩展板上的DIP 8插座可插上不同厂家的SPI Flash device; 本实例操作的为Winbond公司的W25xx系列,其端口结构如图所示:

华邦W25xx系列SPI NOR Flash

W25xx的SPI接口由8个引脚构成:/CS,DO,/WP,GND,VCC,/HOLD,CLK及DIO,其中GND和VCC是电源端,而CLK是整个SPI总线的时钟, DIO是主机的输出,从机的输入,DO 是主机的输入,从机的输出。/CS是从机的选择标志端口,在互相通信的两个SPI总线的器件,/CS 由主机控制,当/CS为低电平时,主机与从机开始交互信息。/WP为FLASH状态保护端口,当/WP为低电平时,FLASH部分状态位无法改变,这样可以间接对FLASH memory中的数据起到保护作用,防止外来数据的写入而造成原有数据的丢失。本实例通过对最基本的Flash 器件和SPI总线协议的研究和实现,设计了SPI Flash Controller, 以此来熟悉IP核的设计和验证。

2 设计规格

l  Support AMBA4 AXI(lite) 32 bit Bus interface.

l  Support SPI flash 1 bit interface.

l  Support SPI mode 0 and SPI mode 3 programable

l  Support 4 byte read/write buffer.

l  Support the following instruction: Write Enable/Disable, Read/Write Status Register, Read Data, Fast Read, Page Program, Block/Sector/Chip Erase, Read JEDEC ID.

l  Support write buffer before starting write_opeartion to device.

l  Support buffer empty/full interrupt.

l  Support transfer complete interrupt.

l  Support buffer empty/full and transfer complete status polling.

l  Support interrupt status write "1" clear.

l  Support interrupt enable/disable/programable.

l  Support system clock frequency 25MHz to 100MHz.

l  Support SPI interface transfer speed configurable: 1/4 system clock, 1/8 system clock, 1/16 system clock.

l  Support software reset.

3  I/O Ports Description

3.1 Global signal

Name

Direction

Width

Description

SYSCLK

Input

1

Global Clock Input

25 -100Mhz

RST_B

Input

1

Global Asynchronous Reset Input

Low active.

3.2 AXI Interface

Name

Direction

Width

Description

AWVALID

Input

1

Write Address Valid

This signal indicates that valid write address and control information are available..

AWREADY

Output

1

Write Address Ready

This signal indicates that the slave is ready to accept an address and associated control signals..

AWADDR

Input

32

Write Address

The write address bus gives the address of the first transfer in a writer burst transaction.

AWPROT

Input

3

Protect type

This signal indicates the normal, priviledged, or secure protection level of the transaction and whether the transaction.

WVALID

Input

1

Write Valid

This signal indicates that valid write data and strobes are available.

WREADY

Output

1

Write Ready

This signal indicates that slave can accept the write data.

WDATA

Input

32

Write Data

The write data bus is 32 bit wide.

WSTRB

Input

4

Write strobes

This signal indicates which bytes lanes to update in memory.

BVALID

Output

1

Write Response Valid

This signal indicates that a valid write response is available.

BREADY

Input

1

Write Response Ready

This signal indicates that the master can accept the response information.

BRESP

Output

2

Write Response

This signal the status of the write transaction.

ARVALID

Input

1

Read Address Valid

This signal indicates, when HIGH, that read address and control information is valid and will remain stable until the address acknowledge signal, ARREADY, is high

ARREADY

Output

1

Read Address Ready

This siganl indicates that the slave is ready to accept an address and associated control signal.

ARADDR

Input

32

Read Address

The read address bus gives the initial address of a read burst transaction.

ARPORT

Input

3

Protect type

This signal indicates the normal,priviledged, or secure protetion level of the transaction and whether the transaction is a data access or an instruction access.

RVALID

Output

1

Read Valid

This signal indicates that the required read data is available and the read transfer can complete.

RREADY

Input

1

Read Ready

This signal indicates that the master can accept the read data and response information.

RDATA

Output

32

Read Data

This read data bus is 32 bit wide.

RRESP

Output

2

Read Response

This signal indicates the status of the read transaction.

3.3 SPI Interface

Name

Direction

Width

Description

SPI_CLK

Output

1

SPI Serial Clock

Serial Clock for SPI Flash

SPI_DI

Input

1

Serial Data Input

Serial Data Output for SPI Flash

SPI_DO

Output

1

Serial Data Input

Serial Data Input for SPI Flash

SPI_CS_B

Output

1

SPI Chip Select

Chip Enable for SPI Flash.Low active to indicate that the SPI Flash is selected.

3.4 Interrupt

Name

Direction

Width

Description

SPI_INT

Output

1

SPI Interrupt

SPI Flash controller interrupt signal, high active

4 Registers File

Register Lists

Address

Name

Access

Description

32'h0

SPI_CON

RW

SPI Configuration Register .

32'h4

SPI_MODE

RW

SPI Mode Configuration Register.

32'h8

SPI_CMD

RW

SPI Flash Operation Command and Address.

32'hc

INT_FLAG

RW

The Interrupt Status Register

32'h10

INT_MASK

RW

The Interrupt Mask Register.

32'h14

W_DATA

RW

Transfer Data. Data from CPU.

32'h18

R_DATA

RW

Receive Data. Data from SPI Flash.

32'h1c

BYTE_NUM

RW

Indicate Write/Read Bytes.

4.1 SPI Configuration Register (SPI_CON,ADDR=32'h0)

Default value: 32’h00

Register Bits

Access

Function Description

0

STR

Start FLAG

High active to indicate start an operation.

1

    WR

Write/Read FLAG

This bit indicate write or read operation.

0: Write Flash;

1: Read Flash;

2

   RST_SW

Software Reset FLAG

High active to indicate software reset Flash.

31:3

   Reserved

Reserved

 

4.2  SPI Mode Configuration Register(SPI_MODE,ADDR=32'h4)

Default value: 32’h0

Register Bits

Access

Function Description

0

SPI_MODE

SPI Flash Work Mode

This bit indicate the work mode of Flash.

0: mode 0;

1: mode 3;

2:1

  CLK_MODE

Clock Mode

This bits indicate the Clock mode of Flash.

00:1/4 system clock

01:1/8 system clock

10:1/16 system clock

11:Reserved

31:3

   Reserved

Reserved

4.3  SPI Flash Command and Address (SPI_CMD,ADDR=32'h8)

Default value: 32’h0

Register Bits

Access

Function Description

7:0

CMD

Command Code

The SPI Flash control operation code.

15:8

   ADDR_H

The High 8 bits address

The high 8 bits address to indicate the start of W/R into the flash.

23:16

   ADDR_M

The Middle 8 bits address

The middle 8 bits address to indicate the start of W/R into the flash.

31:24

   ADDR_L

The Low 8 bits address

The low 8 bits address to indicate the start of W/R into the flash.

4.4 Interrupt Status Register (INT_FLAG,ADDR=32'hc)

Default value: 32’h0

Register Bits

Access

Function Description

0

  CMP_FLAG

Transfer complete Flag, Write 1 Clear

High active to indicate transfer complete state.

1

T_EMP_FLAG

Transfer FIFO Empty Flag, Write 1 Clear

High active to indicate transfer FIFO empty state.

2

T_FUL_FLAG

Transfer FIFO Full Flag, Write 1 Clear

High active to indicate transfer FIFO full state.

3

R_EMP_FLAG

Receive FIFO Empty Flag, Write 1 Clear

High active to indicate receive FIFO empty state.

4

R_FUL_FLAG

Receive FIFO Full Flag, Write 1 Clear

High active to indicate receive FIFO full state.

31:3

Reserved

Reserved

4.5 Interrupt Mask Register (INT_MASK,ADDR=32'h10)

Default value: 32’h0

Register Bits

Access

Function Description

0

 CMP_MASK

Mask of Transfer complete Flag

High active.

1

T_EMP_MASK

Mask of Transfer FIFO Empty Flag

High active.

2

T_FUL_MASK

Mask of Transfer FIFO Full Flag

High active.

3

R_EMP_MASK

Mask of Receive FIFO Empty Flag

High active .

4

R_FUL_MASK

Mask of Receive FIFO Full Flag

High active.

30:5

Reserved

Reserved

31

GLO_MASK

Global  Mask

4.6 WRITE DATA (W_DATA,ADDR=32'h14)

Default value: 32’h0

Register Bits

Access

Function Description

31:0

W_DATA

Save the Data from CPU

32 bits.

4.7 Read Data FIFO (R_DATA,ADDR=32'h18)

Default value: 32’h0

Register Bits

Access

Function Description

31:0

R_DATA

Save the Data from SPI Flash

32 bits.

4.8 BYTE _NUM (ADDR=32'h1c)

Default value: 32’h1

Register Bits

Access

Function Description

15:0

BYTE_NUM

BYTE COUNT

Indicate the bytes of data R/W.

31:16

Reserved

Reserved

5     Functional Description

5.1  SPI Flash Controller Block Diagram

The FSM is used to control and harmonize the whole system. Master configures the necessary information to the controller through AXI Bus

FSM: Control the configuration logic, make the whole system to work normally.

Register File: Store the configure, status and data.

FIFO: Used as a buffer in RECEIVER and TRANSMITTER.

Interface : Translate the logic

5.2    Internal FSM

Current State

Function

Next Status

Jump Condition

IDLE

Wait start signal

T_CMD

STR = 1

IDLE

STR = 0 or Reset not end

T_CMD

Transfer Command

T_ADDR_H

T_count = 8

T_DATA

The command is 9FH

IDLE

The commnd is 06H|04H| C7H/60H

T_ADDR_H

Transfer the address high 8 bits.

T_ADDR_M

T_count = 8

T_ADDR_M

Transfer the address middle 8 bits.

T_ADDR_L

T_count = 8

T_ADDR_L

Transfer the address low 8 bits

IDLE

CMD is D8H|52H|20H

T_DATA

T_count = 8

T_DATA

Transfer data

T_DATA

Transfer data not end

IDLE

Transfer data end

5.3    FIFO

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

It is a 8*8-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.

When FIFO is full/empty but still write/read, FIFO will overflow/underflow.

5.4    Polling Status and Interrupt

The design provide programmable interrupt output and polling the interrupt flag through INT_FLAG.   SPI_INT will be high when interrupt happens.

Each interrupt source can read in proper bits of INT_FLAG.

Each interrupt source can also be mask in the same bits of INT_MASK.

Each interrupt should be clear by sending clear interrupt command.

There are such  interrupt source as below:

Interrupt source

Description

Mask bit

CMP_FLAG

Transfer Complete

0

T_EMP_FLAG

Transfer FIFO Empty Flag

1

T_FUL_FLAG

Transfer FIFO Full Flag

2

R_EMP_FLAG

Receive FIFO Empty Flag

3

R_FUL_FLAG

Receive FIFO Full Flag

4

6   Timing Figures

6.1 AXI Bus Write

6.2  AXI Bus Read

6.3  SPI Bus Write

6.4  SPI Bus Read

6.5  SPI Clock

6.6   Parallel to Serial

6.7  Serial to Parallel

7 SOC 整合实现

7.1  SPI FLASH 控制器IP设计实验项目的硬件平台实现

SPI FLASH控制器IP核设计是AMBA  AXI slave 32bit总线接口,而我们FBIO Wrapper是AMBA  AXI 64bit总线接口, 不能直接连接在一起,需要一个axi64_to_axi32的Bridge进行连接,如下;如下图所示:

本实验以Plus1 7021实践平台配套的FPGA子板和扩展测试板完成相关实验,FPGA子板的开发工具采用XILINX的Vivado集成开发环境(版本号为2018.3);为了方便将用户自己需要验证的IP方便连接到SOC系统中验证,本实验提供了相应的设计参考基础文件,如下

设计案例与SP7021主板与FPGA子板脚位对应连接关系如下表所示:

1: 主板上的U20B接FPGA子板的J2(Pin脚对应,如 1-51...),提供主板上的Plus1 主芯片与FPGA的数据传输通道

Design Demo

FPGA子板

SP7021主板

spi_flash_axi

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: 主板上的U20A接FPGA子板的J1(Pin脚以一对应,如 1-1...),经由J17将FPGA Bank 35的42 pin IO(3.3v) 扩展出来,供用户使用;本实验案例中接测试扩展板的J2(Pin脚以一对应,如 1-1...),提供FPGA的IO扩展

Design Demo

FPGA子板

SP7021主板

测试扩展板

spi_flash_axi

J1

U1F

U20A

J17

J2

Top Port Name

Schematic Name

FPGA I/O

Schematic Name

Schematic Name

Schematic Name

 

1

GND

 

1

GND

 

 

 

 

 

2

GND

 

2

GND

 

 

 

 

 

3

B35_L23_N

K1

3

B35_L23_N

5

B35_L23_N

5

PMOD8

 

4

B35_L23_P

K2

4

B35_L23_P

6

B35_L23_P

6

PMOD7

 

5

VIN

 

5

VIN

 

 

 

 

 

6

VCCIO35

 

6

VCCIO35

 

 

 

 

 

7

B35_L15_N

G2

7

B35_L15_N

7

B35_L15_N

7

PMOD6

 

8

B35_L15_P

H2

8

B35_L15_P

8

B35_L15_P

8

PMOD5

 

9

B35_L13_N

F3

9

B35_L13_N

9

B35_L13_N

9

PMOD4

 

10

B35_L13_P

F4

10

B35_L13_P

10

B35_L13_P

10

PMOD3

 

11

B35_L12_N

D3

11

B35_L12_N

11

B35_L12_N

11

LED_D1

 

12

B35_L12_P

E3

12

B35_L12_P

12

B35_L12_P

12

PMOD1

 

13

B35_L22_P

J3

13

B35_L22_P

13

B35_L22_P

13

LED_D2

 

14

B35_L22_N

J2

14

B35_L22_N

14

B35_L22_N

14

PMOD2

 

15

B35_L17_N

G1

15

B35_L17_N

15

B35_L17_N

15

LED_D3

 

16

B35_L17_P

H1

16

B35_L17_P

16

B35_L17_P

16

LED_D4

 

17

B35_L18_N

E1

17

B35_L18_N

17

B35_L18_N

17

LED_D5

 

18

B35_L18_P

F1

18

B35_L18_P

18

B35_L18_P

18

LED_D6

 

19

B35_L14_N

D2

19

B35_L14_N

19

B35_L14_N

19

LED_D7

 

20

B35_L14_P

E2

20

B35_L14_P

20

B35_L14_P

20

LED_D8

 

21

B35_L16_P

C2

21

B35_L16_P

21

B35_L16_P

21

SPI_WP

 FPGA_SPI_DI

22

B35_L16_N

C1

22

B35_L16_N

22

B35_L16_N

22

SPI_DO

 FPGA_SPI_CS_B

23

B35_L9_N

A1

23

B35_L9_N

23

B35_L9_N

23

SPI_CS

 

24

B35_L9_P

B1

24

B35_L9_P

24

B35_L9_P

24

SPI_HOLD

 FPGA_SPI_CLK

25

B35_L10_P

B3

25

B35_L10_P

25

B35_L10_P

25

SPI_CLK

 FPGA_SPI_DO

26

B35_L10_N

B2

26

B35_L10_N

26

B35_L10_N

26

SPI_DI

 

27

B35_L8_N

A3

27

B35_L8_N

27

B35_L8_N

27

U1-1

 

28

B35_L8_P

A4

28

B35_L8_P

28

B35_L8_P

28

U2-1

 

29

B35_L11_N

D4

29

B35_L11_N

29

B35_L11_N

29

U3-1

 

30

B35_L11_P

D5

30

B35_L11_P

30

B35_L11_P

30

U4-1

 

31

B35_L3_N

A5

31

B35_L3_N

31

B35_L3_N

31

LED-B

 

32

B35_L3_P

A6

32

B35_L3_P

32

B35_L3_P

32

LED-F

 

33

B35_L2_N

B6

33

B35_L2_N

33

B35_L2_N

33

LED-A

 

34

B35_L2_P

B7

34

B35_L2_P

34

B35_L2_P

34

LED-E

 

35

B35_L7_N

B4

35

B35_L7_N

35

B35_L7_N

35

LED-D

 

36

B35_L7_P

C4

36

B35_L7_P

36

B35_L7_P

36

LED-RA

 

37

B35_L1_N

C5

37

B35_L1_N

37

B35_L1_N

37

LED-C

 

38

B35_L1_P

C6

38

B35_L1_P

38

B35_L1_P

38

LED-G

 

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

 

 

 

 

 

46

VIN

 

46

VIN

 

 

 

 

 

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

 

 

 

 

 

50

GND

 

50

GND

 

 

 

 

7.2  SPI FLASH 控制器IP设计实验项目的系统软件平台实现

在IDE 环境中如下图所示,选择sp7021工程名,单击鼠标右键在弹出的菜单中选Copy

接下来再次选择sp7021工程名

单击鼠标右键在弹出的菜单中选Paste,出现下图

在Project name框中填写spi_flash_axi,完成spi_flash_axi 工程名及目录建立,如下图所示

接下来需要复制安装目录\SP7021\example\spi_flash_axi下的所有文件及文件夹到上面建好的spi_flash_axi工程目录中(路径为:安装目录 \SP7021\workspace\spi_flash_axi\),同名文件选择覆盖,这样SPI Flash控制器 IP设计实践所需的程序代码main.c;spi.c;spi.h分别放到如下的路径中:

1) 安装目录 \SP7021\workspace\ spi_flash_axi \ 文件夹下的main.c

2) 安装目录 \SP7021\workspace\ spi_flash_axi \testapi\util 文件夹下的spi.c

3) 安装目录 \SP7021\workspace\ spi_flash_axi \ include\util文件夹下的spi.h

最后按下图所示,鼠标选中红框1,接着点击鼠标右键出现下拉菜单,然后选中红框2,对刚才复制动作做刷新,这样刚才复制的文件就能在IDE环境中显示出来

main.c

void operation_done()

void flash_device_write_en()

void flash_device_done()

void spi_read_id()

void spi_write_data()

void spi_read_data()

int main(void)

{

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

    hw_init();

    sys_init();

    fbio_init();

    disp_hdmi_init();

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

    spi_read_id();

    spi_write_data();

    spi_read_data();

    printf("%s:%5d\n", __FUNCTION__,__LINE__);

    while(1);

}

对比数码管控制IP实验,增加了spi flash操作控制相关的函数,用来完成对spi flash读写及擦除操作,如下讲解。

void spi_read_id()

{

    spi_reg->SPI_CMD=0x9f;

    spi_reg->SPI_CON=0x3;

    operation_done();

    temp=spi_reg->R_DATA;

    printf("@spi flash device id [%x]\n", temp);

}

实现读取flash JEDEC ID的操作,如下:

spi_reg->SPI_CMD=0x9f;  设置读JEDEC ID的命令码9f;

spi_reg->SPI_CON=0x3;启动读JEDEC ID的操作;

operation_done(); 等待本次操作完成;

temp=spi_reg->R_DATA; 从RX FIFO里取出读JEDEC ID操作完成后的结果,并打印出;

void spi_write_data()

{

    /////////sector erase///////////////

    flash_device_write_en();

    spi_reg->SPI_CMD=0x3020;

    spi_reg->SPI_CON=0x1;

    operation_done();

    flash_device_done();

    //////////write data///////////////////////////

    flash_device_write_en();

    spi_reg->BYTE_NUM=0x8;

    spi_reg->W_DATA =0x12345678;

    spi_reg->W_DATA =0xabcdef91;

    spi_reg->SPI_CMD=0x3002;

    spi_reg->SPI_CON=0x1;

    operation_done();

    flash_device_done();

}

实现写数据到flash device的操作,写数据操作必须先对存储数据的地址空间做擦除,然后才能写入数据,如下:

flash_device_write_en(); 对flash 的擦除,写操作之前必需写使能,通过设置命令码06实现;

spi_reg->SPI_CMD=0x3020; 擦除flash 从0x300000地址开始的4k byte空间,通过设置命令码20实现

flash_device_done();等待擦除flash 从0x300000地址开始的4k byte空间,直到操作完成;

spi_reg->BYTE_NUM=0x8;设置写数据到flash device的数目,共8byte;

spi_reg->W_DATA =0x12345678; spi_reg->W_DATA =0xabcdef91;

设置需要写到flash device的数据

spi_reg->SPI_CMD=0x3002;设置flash 从0x300000地址开始的4k byte空间为写数据空间;通过设置命令码02实现

spi_reg->SPI_CON=0x1; 使能写数据操作;

operation_done();

flash_device_done();

等待写8byte数据到flash device,直到操作完成

void spi_read_data()

{

    spi_reg->BYTE_NUM=0x8;

    spi_reg->SPI_CMD=0x3003;

    spi_reg->SPI_CON=0x3;

    operation_done();

    temp= spi_reg->R_DATA;

    printf("Read SPI Flash:  [%x]\n", temp);

    temp= spi_reg->R_DATA;

    printf("Read SPI Flash:  [%x]\n", temp);

}

    spi_reg->BYTE_NUM=0x8; 设置从flash device读数据的数目,共8byte;

    spi_reg->SPI_CMD=0x3003; 设置flash 从0x300000地址开始读数据,通过设置命令码03实现

    spi_reg->SPI_CON=0x3; 使能读数据操作;

    operation_done();等待从flash device读8byte数据,直到操作完成

程序代码运行

在Plus1 IDE环境中compile后,下载到平台,在terminal窗口看到如下信息

  • No labels