38. Serial peripheral interface (SPI)

38.1 Introduction

The SPI interface can be used to communicate with external devices using the SPI protocol. SPI mode is selectable by software. SPI Motorola mode is selected by default after a device reset.

The serial peripheral interface (SPI) protocol supports half-duplex, full-duplex and simplex synchronous, serial communication with external devices. The interface can be configured as master and in this case it provides the communication clock (SCK) to the external slave device. The interface is also capable of operating in multimaster configuration.

38.2 SPI main features

• Master or slave operation
• Full-duplex synchronous transfers on three lines
• Half-duplex synchronous transfer on two lines (with bidirectional data line)
• Simplex synchronous transfers on two lines (with unidirectional data line)
• 4 to 16-bit data size selection
• Multimaster mode capability
• 8 master mode baud rate prescalers up to $f_{PCLK}/2$
• Slave mode frequency up to $f_{PCLK}/2$
• NSS management by hardware or software for both master and slave: dynamic change of master/slave operations
• Programmable clock polarity and phase
• Programmable data order with MSB-first or LSB-first shifting
• Dedicated transmission and reception flags with interrupt capability
• SPI bus busy status flag
• SPI Motorola support
• Hardware CRC feature for reliable communication:
- – CRC value can be transmitted as last byte in Tx mode
- – Automatic CRC error checking for last received byte
• Master mode fault, overrun flags with interrupt capability
• CRC Error flag
• Two 32-bit embedded Rx and Tx FIFOs with DMA capability
• Enhanced TI and NSS pulse modes support

38.3 SPI implementation

The following table describes all the SPI instances and their features embedded in the devices.

Table 238. SPI implementation

SPI Features	SPI1	SPI2 ⁽¹⁾
Enhanced NSSP & TI modes	Yes	Yes
I ²S support	No	No
Hardware CRC calculation	Yes	Yes
Data size configurable	from 4 to 16 bits	from 4 to 16 bits
Rx/Tx FIFO size	32 bits	32 bits
Wake-up capability from Low-power Sleep	Yes	Yes

1. Available only on STM32WB55xx devices.

38.4 SPI functional description

38.4.1 General description

The SPI allows synchronous, serial communication between the MCU and external devices. Application software can manage the communication by polling the status flag or using dedicated SPI interrupt. The main elements of SPI and their interactions are shown in the following block diagram Figure 373 .

Figure 373. SPI block diagram

Figure 373. SPI block diagram. This diagram illustrates the internal architecture of an SPI peripheral. At the top, an 'Address and data bus' connects to a 'Read' block, which in turn connects to an 'Rx FIFO'. Below the Rx FIFO is a 'Shift register'. Data is written from the 'Address and data bus' through a 'Write' block into a 'Tx FIFO', which then feeds into the 'Shift register'. The 'Shift register' has two output pins on the left: 'MOSI' and 'MISO'. The 'MOSI' pin is connected to the 'CRC controller' and the 'Communication controller'. The 'MISO' pin is connected to the 'Communication controller'. The 'Communication controller' is also connected to the 'CRC controller' and the 'NSS logic'. The 'CRC controller' has several input pins: 'RXONLY', 'CPOL', 'CPHA', and 'DS[0:3]'. The 'Communication controller' has input pins: 'BIDIOE' and 'BR[2:0]'. The 'BR[2:0]' pins are connected to a 'Baud rate generator', which is also connected to the 'SCK' pin. The 'NSS logic' is connected to the 'NSS' pin and the 'Internal NSS' signal. The diagram is labeled 'MS30117V1' in the bottom right corner.

Four I/O pins are dedicated to SPI communication with external devices.

• MISO: Master In / Slave Out data. In the general case, this pin is used to transmit data in slave mode and receive data in master mode.
• MOSI: Master Out / Slave In data. In the general case, this pin is used to transmit data in master mode and receive data in slave mode.
• SCK: Serial Clock output pin for SPI masters and input pin for SPI slaves.
• NSS: Slave select pin. Depending on the SPI and NSS settings, this pin can be used to either:
- – select an individual slave device for communication
- – synchronize the data frame or
- – detect a conflict between multiple masters

See Section 38.4.5: Slave select (NSS) pin management for details.

The SPI bus allows the communication between one master device and one or more slave devices. The bus consists of at least two wires - one for the clock signal and the other for synchronous data transfer. Other signals can be added depending on the data exchange between SPI nodes and their slave select signal management.

38.4.2 Communications between one master and one slave

The SPI allows the MCU to communicate using different configurations, depending on the device targeted and the application requirements. These configurations use 2 or 3 wires (with software NSS management) or 3 or 4 wires (with hardware NSS management). Communication is always initiated by the master.

Full-duplex communication

By default, the SPI is configured for full-duplex communication. In this configuration, the shift registers of the master and slave are linked using two unidirectional lines between the MOSI and the MISO pins. During SPI communication, data is shifted synchronously on the SCK clock edges provided by the master. The master transmits the data to be sent to the slave via the MOSI line and receives data from the slave via the MISO line. When the data frame transfer is complete (all the bits are shifted) the information between the master and slave is exchanged.

Figure 374. Full-duplex single master/ single slave application

Diagram of a full-duplex single master/single slave SPI application. The Master (left) has an Rx shift register, a Tx shift register, and an SPI clock generator. The Slave (right) has a Tx shift register and an Rx shift register. Connections: MISO (Master In / Slave Out) from Slave to Master; MOSI (Master Out / Slave In) from Master to Slave; SCK (Serial Clock) from Master to Slave; NSS (Slave Select) from Master to Slave. Arrows indicate data flow: MISO from Slave's Tx shift register to Master's Rx shift register; MOSI from Master's Tx shift register to Slave's Rx shift register; SCK from Master's SPI clock generator to Slave's Rx shift register. The diagram is labeled MSv39623V1.

1. The NSS pins can be used to provide a hardware control flow between master and slave. Optionally, the pins can be left unused by the peripheral. Then the flow has to be handled internally for both master and slave. For more details see Section 38.4.5: Slave select (NSS) pin management .

Half-duplex communication

The SPI can communicate in half-duplex mode by setting the BIDIMODE bit in the SPIx_CR1 register. In this configuration, one single cross connection line is used to link the shift registers of the master and slave together. During this communication, the data is synchronously shifted between the shift registers on the SCK clock edge in the transfer direction selected reciprocally by both master and slave with the BDIOE bit in their SPIx_CR1 registers. In this configuration, the master's MISO pin and the slave's MOSI pin are free for other application uses and act as GPIOs.

Figure 375. Half-duplex single master/ single slave application

The diagram illustrates a half-duplex SPI connection between a Master and a Slave. The Master side includes an 'Rx shift register', a 'Tx shift register', and an 'SPI clock generator'. The Slave side includes a 'Tx shift register' and an 'Rx shift register'. The Master's MISO pin (labeled MISO ⁽²⁾) and the Slave's MOSI pin (labeled MOSI ⁽²⁾) are connected to a common data line. A 1kΩ resistor (labeled 1kΩ ⁽³⁾) is connected between the Master's MISO and Slave's MOSI pins. The Master's MOSI pin and the Slave's MISO pin are also connected to this common data line. The Master's SCK pin is connected to the Slave's SCK pin. The Master's NSS pin (labeled NSS ⁽¹⁾) is connected to the Slave's NSS pin. The diagram is labeled MSV39624V1.

Diagram of a half-duplex SPI application showing a Master and a Slave connected by a single data line (MISO/MOSI), a clock line (SCK), and a slave select line (NSS). The Master contains an Rx shift register, a Tx shift register, and an SPI clock generator. The Slave contains a Tx shift register and an Rx shift register. A 1kΩ resistor is shown on the data line between the Master's MISO and Slave's MOSI pins. The diagram is labeled MSV39624V1.

1. The NSS pins can be used to provide a hardware control flow between master and slave. Optionally, the pins can be left unused by the peripheral. Then the flow has to be handled internally for both master and slave. For more details see Section 38.4.5: Slave select (NSS) pin management .
2. In this configuration, the master's MISO pin and the slave's MOSI pin can be used as GPIOs.
3. A critical situation can happen when communication direction is changed not synchronously between two nodes working at bidirectional mode and new transmitter accesses the common data line while former transmitter still keeps an opposite value on the line (the value depends on SPI configuration and communication data). Both nodes then fight while providing opposite output levels on the common line temporary till next node changes its direction settings correspondingly, too. It is suggested to insert a serial resistance between MISO and MOSI pins at this mode to protect the outputs and limit the current blowing between them at this situation.

Simplex communications

The SPI can communicate in simplex mode by setting the SPI in transmit-only or in receive-only using the RXONLY bit in the SPIx_CR1 register. In this configuration, only one line is used for the transfer between the shift registers of the master and slave. The remaining MISO and MOSI pins pair is not used for communication and can be used as standard GPIOs.

• Transmit-only mode (RXONLY=0): The configuration settings are the same as for full-duplex. The application has to ignore the information captured on the unused input pin. This pin can be used as a standard GPIO.
• Receive-only mode (RXONLY=1): The application can disable the SPI output function by setting the RXONLY bit. In slave configuration, the MISO output is disabled and the pin can be used as a GPIO. The slave continues to receive data from the MOSI pin while its slave select signal is active (see 38.4.5: Slave select (NSS) pin management ). Received data events appear depending on the data buffer configuration. In the master configuration, the MOSI output is disabled and the pin can be used as a GPIO. The clock signal is generated continuously as long as the SPI is enabled. The only way to stop the clock is to clear the RXONLY bit or the SPE bit and wait until the incoming pattern from the MISO pin is finished and fills the data buffer structure, depending on its configuration.

Figure 376. Simplex single master/single slave application (master in transmit-only/slave in receive-only mode)

Figure 376: Simplex single master/single slave application diagram. The diagram shows a Master and a Slave connected by four lines: MISO, MOSI, SCK, and NSS. The Master contains an Rx shift register, a Tx shift register, and an SPI clock generator. The Slave contains a Tx shift register and an Rx shift register. Arrows indicate data flow from the Master's Tx shift register to the Slave's Rx shift register via the MOSI line. The SCK line is connected between the SPI clock generator and the Slave. The NSS line is connected between the Master and the Slave. The MISO lines are shown but not used in this configuration. The diagram is labeled MSV39625V1.

1. The NSS pins can be used to provide a hardware control flow between master and slave. Optionally, the pins can be left unused by the peripheral. Then the flow has to be handled internally for both master and slave. For more details see Section 38.4.5: Slave select (NSS) pin management .
2. An accidental input information is captured at the input of transmitter Rx shift register. All the events associated with the transmitter receive flow must be ignored in standard transmit only mode (e.g. OVR flag).
3. In this configuration, both the MISO pins can be used as GPIOs.

Note: Any simplex communication can be alternatively replaced by a variant of the half-duplex communication with a constant setting of the transaction direction (bidirectional mode is enabled while BDIO bit is not changed).

38.4.3 Standard multislave communication

In a configuration with two or more independent slaves, the master uses GPIO pins to manage the chip select lines for each slave (see Figure 377 ). The master must select one of the slaves individually by pulling low the GPIO connected to the slave NSS input. When this is done, a standard master and dedicated slave communication is established.

Figure 377. Master and three independent slaves

Diagram of SPI Master and three independent slaves. The Master is connected to three Slaves (Slave 1, Slave 2, Slave 3). The Master has pins NSS(1), MISO, MOSI, SCK, IO1, IO2, and IO3. The Slaves have pins MISO, MOSI, SCK, and NSS. The Master's MISO pin is connected to the Slaves' MISO pins. The Master's MOSI pin is connected to the Slaves' MOSI pins. The Master's SCK pin is connected to the Slaves' SCK pins. The Master's NSS pin is connected to the Slaves' NSS pins. The Master's IO1, IO2, and IO3 pins are connected to the Slaves' NSS pins. The Master has an internal SPI clock generator, Rx shift register, and Tx shift register. The Slaves have internal Tx shift register and Rx shift register. Arrows indicate data flow: MISO from Slave to Master, MOSI from Master to Slave, and SCK from Master to Slave. The diagram is labeled MSv39626V1.

1. NSS pin is not used on master side at this configuration. It has to be managed internally (SSM=1, SSI=1) to prevent any MODF error.
2. As MISO pins of the slaves are connected together, all slaves must have the GPIO configuration of their MISO pin set as alternate function open-drain (see I/O alternate function input/output section (GPIO)).

38.4.4 Multimaster communication

Unless SPI bus is not designed for a multimaster capability primarily, the user can use built-in feature which detects a potential conflict between two nodes trying to master the bus at the same time. For this detection, NSS pin is used configured at hardware input mode.

The connection of more than two SPI nodes working at this mode is impossible as only one node can apply its output on a common data line at time.

When nodes are non active, both stay at slave mode by default. Once one node wants to overtake control on the bus, it switches itself into master mode and applies active level on the slave select input of the other node via dedicated GPIO pin. After the session is completed, the active slave select signal is released and the node mastering the bus temporarily returns back to passive slave mode waiting for next session start.

If potentially both nodes raised their mastering request at the same time a bus conflict event appears (see mode fault MODF event). Then the user can apply some simple arbitration process (e.g. to postpone next attempt by predefined different time-outs applied at both nodes).

Figure 378. Multimaster application

Diagram of a multimaster SPI application showing two nodes connected via MISO, MOSI, SCK, and NSS lines. Each node contains an Rx (Tx) shift register, a Tx (Rx) shift register, and an SPI clock generator. The left node is labeled 'Master (Slave)' and the right node is also labeled 'Master (Slave)'. Arrows indicate signal flow: MISO lines are bidirectional, MOSI lines are bidirectional, SCK lines are bidirectional, and the NSS line has arrows pointing from the left node's GPIO to the right node's NSS(1) and from the right node's NSS(1) to the left node's GPIO.

1. The NSS pin is configured at hardware input mode at both nodes. Its active level enables the MISO line output control as the passive node is configured as a slave.

38.4.5 Slave select (NSS) pin management

In slave mode, the NSS works as a standard “chip select” input and lets the slave communicate with the master. In master mode, NSS can be used either as output or input. As an input it can prevent multimaster bus collision, and as an output it can drive a slave select signal of a single slave.

Hardware or software slave select management can be set using the SSM bit in the SPIx_CR1 register:

• Software NSS management (SSM = 1) : in this configuration, slave select information is driven internally by the SSI bit value in register SPIx_CR1. The external NSS pin is free for other application uses.
• Hardware NSS management (SSM = 0) : in this case, there are two possible configurations. The configuration used depends on the NSS output configuration (SSOE bit in register SPIx_CR1).
- – NSS output enable (SSM=0,SSOE = 1) : this configuration is only used when the MCU is set as master. The NSS pin is managed by the hardware. The NSS signal is driven low as soon as the SPI is enabled in master mode (SPE=1), and is kept low until the SPI is disabled (SPE =0). A pulse can be generated between continuous communications if NSS pulse mode is activated (NSSP=1). The SPI cannot work in multimaster configuration with this NSS setting.
- – NSS output disable (SSM=0, SSOE = 0) : if the microcontroller is acting as the master on the bus, this configuration allows multimaster capability. If the NSS pin is pulled low in this mode, the SPI enters master mode fault state and the device is automatically reconfigured in slave mode. In slave mode, the NSS pin works as a standard “chip select” input and the slave is selected while NSS line is at low level.

Figure 379. Hardware/software slave select management

The diagram illustrates the internal logic for Slave Select (NSS) management. On the left, the NSS pin is connected to a GPIO logic block. This block is connected to a 2-to-1 multiplexer. The multiplexer's inputs are labeled 1 and 0 . The SSI control bit is connected to input 1 , and the SSM control bit is connected to input 0 . The output of the multiplexer is the NSS Input . Below the multiplexer, an NSS Output Control block is shown. It is connected to the SSOE control bit and receives the NSS Input . Its output is the NSS Output , which is noted as being used in Master mode and NSS HW management only. The diagram is divided into NSS external logic (left of the dashed line) and NSS internal logic (right of the dashed line).

NSS Inp.	Master mode	Slave mode
Vdd	OK	Non active
Vss	Conflict	Active

MSv35526V6

Figure 379. Hardware/software slave select management diagram showing the internal logic for NSS management. It includes a 2-to-1 multiplexer controlled by SSI and SSM bits, a GPIO logic block connected to the NSS pin, and an NSS Output Control block connected to the SSOE bit. A table shows the relationship between NSS Input, Master mode, and Slave mode.

38.4.6 Communication formats

During SPI communication, receive and transmit operations are performed simultaneously. The serial clock (SCK) synchronizes the shifting and sampling of the information on the data lines. The communication format depends on the clock phase, the clock polarity and the data frame format. To be able to communicate together, the master and slaves devices must follow the same communication format.

Clock phase and polarity controls

Four possible timing relationships may be chosen by software, using the CPOL and CPHA bits in the SPIx_CR1 register. The CPOL (clock polarity) bit controls the idle state value of the clock when no data is being transferred. This bit affects both master and slave modes. If CPOL is reset, the SCK pin has a low-level idle state. If CPOL is set, the SCK pin has a high-level idle state.

If the CPHA bit is set, the second edge on the SCK pin captures the first data bit transacted (falling edge if the CPOL bit is reset, rising edge if the CPOL bit is set). Data are latched on each occurrence of this clock transition type. If the CPHA bit is reset, the first edge on the SCK pin captures the first data bit transacted (falling edge if the CPOL bit is set, rising edge if the CPOL bit is reset). Data are latched on each occurrence of this clock transition type.

The combination of CPOL (clock polarity) and CPHA (clock phase) bits selects the data capture clock edge.

Figure 380, shows an SPI full-duplex transfer with the four combinations of the CPHA and CPOL bits.

Note: Prior to changing the CPOL/CPHA bits the SPI must be disabled by resetting the SPE bit. The idle state of SCK must correspond to the polarity selected in the SPIx_CR1 register (by pulling up SCK if CPOL=1 or pulling down SCK if CPOL=0).

Figure 380. Data clock timing diagram

Figure 380. Data clock timing diagram. The diagram illustrates SPI full-duplex transfer timing for two CPHA settings: CPHA = 1 and CPHA = 0. Each section shows the relationship between the clock (SCK), master output (MOSI), master input (MISO), and slave select (NSS) signals over several clock cycles. The diagram is divided into two main parts: the top part for CPHA = 1 and the bottom part for CPHA = 0. In each part, the SCK signal is shown for CPOL = 1 and CPOL = 0. The MOSI signal is shown with MSB and LSB bits. The MISO signal is shown with MSB and LSB bits. The NSS signal is shown as a low-active signal. The capture strobe is shown as a pulse. The diagram is labeled 'ai17154e' in the bottom right corner.

1. The order of data bits depends on LSBFIRST bit setting.

Data frame format

The SPI shift register can be set up to shift out MSB-first or LSB-first, depending on the value of the LSBFIRST bit. The data frame size is chosen by using the DS bits. It can be set from 4-bit up to 16-bit length and the setting applies for both transmission and reception. Whatever the selected data frame size, read access to the FIFO must be aligned with the FRXTH level. When the SPIx_DR register is accessed, data frames are always right-aligned into either a byte (if the data fits into a byte) or a half-word (see Figure 381). During communication, only bits within the data frame are clocked and transferred.

Figure 381. Data alignment when data length is not equal to 8-bit or 16-bit

DS <= 8 bits: data is right-aligned on byte
Example: DS = 5 bit

TX: [7 5 4 0] [XXX | Data frame]

RX: [7 5 4 0] [000 | Data frame]

DS > 8 bits: data is right-aligned on 16 bit
Example: DS = 14 bit

TX: [15 14 13 0] [XX | Data frame]

RX: [15 14 13 0] [00 | Data frame]

MS19589V2

Figure 381: Data alignment when data length is not equal to 8-bit or 16-bit. The diagram shows two cases for data alignment in SPI. Case 1: DS <= 8 bits (e.g., DS = 5 bits). The TX frame is 8 bits: bits 7-5 are 'XXX' and bits 4-0 are the 'Data frame'. The RX frame is 8 bits: bits 7-5 are '000' and bits 4-0 are the 'Data frame'. Case 2: DS > 8 bits (e.g., DS = 14 bits). The TX frame is 16 bits: bits 15-14 are 'XX' and bits 13-0 are the 'Data frame'. The RX frame is 16 bits: bits 15-14 are '00' and bits 13-0 are the 'Data frame'. MS19589V2

Note: The minimum data length is 4 bits. If a data length of less than 4 bits is selected, it is forced to an 8-bit data frame size.

38.4.7 Configuration of SPI

The configuration procedure is almost the same for master and slave. For specific mode setups, follow the dedicated sections. When a standard communication is to be initialized, perform these steps:

1. Write proper GPIO registers: Configure GPIO for MOSI, MISO and SCK pins.
2. Write to the SPI_CR1 register:
1. a) Configure the serial clock baud rate using the BR[2:0] bits (Note: 4).
2. b) Configure the CPOL and CPHA bits combination to define one of the four relationships between the data transfer and the serial clock (CPHA must be cleared in NSSP mode). (Note: 2 - except the case when CRC is enabled at TI mode).
3. c) Select simplex or half-duplex mode by configuring RXONLY or BIDIMODE and BIDIOE (RXONLY and BIDIMODE cannot be set at the same time).
4. d) Configure the LSBFIRST bit to define the frame format (Note: 2).
5. e) Configure the CRCL and CRCEN bits if CRC is needed (while SCK clock signal is at idle state).
6. f) Configure SSM and SSI (Notes: 2 & 3).
7. g) Configure the MSTR bit (in multimaster NSS configuration, avoid conflict state on NSS if master is configured to prevent MODF error).
3. Write to SPI_CR2 register:
1. a) Configure the DS[3:0] bits to select the data length for the transfer.
2. b) Configure SSOE (Notes: 1 & 2 & 3).
3. c) Set the FRF bit if the TI protocol is required (keep NSSP bit cleared in TI mode).
4. d) Set the NSSP bit if the NSS pulse mode between two data units is required (keep CHPA and TI bits cleared in NSSP mode).
5. e) Configure the FRXTH bit. The RXFIFO threshold must be aligned to the read access size for the SPIx_DR register.
6. f) Initialize LDMA_TX and LDMA_RX bits if DMA is used in packed mode.
4. Write to SPI_CRCPR register: Configure the CRC polynomial if needed.
5. Write proper DMA registers: Configure DMA streams dedicated for SPI Tx and Rx in DMA registers if the DMA streams are used.

Note:
- (1) Step is not required in slave mode.
- (2) Step is not required in TI mode.
- (3) Step is not required in NSSP mode.
- (4) The step is not required in slave mode except slave working at TI mode

38.4.8 Procedure for enabling SPI

It is recommended to enable the SPI slave before the master sends the clock. If not, undesired data transmission might occur. The data register of the slave must already contain data to be sent before starting communication with the master (either on the first edge of the communication clock, or before the end of the ongoing communication if the clock signal is continuous). The SCK signal must be settled at an idle state level corresponding to the selected polarity before the SPI slave is enabled.

The master at full-duplex (or in any transmit-only mode) starts to communicate when the SPI is enabled and TXFIFO is not empty, or with the next write to TXFIFO.

In any master receive only mode (RXONLY = 1 or BIDIMODE = 1 & BIDIOE = 0), master starts to communicate and the clock starts running immediately after SPI is enabled.

For handling DMA, follow the dedicated section.

38.4.9 Data transmission and reception procedures

RXFIFO and TXFIFO

All SPI data transactions pass through the 32-bit embedded FIFOs. This enables the SPI to work in a continuous flow, and prevents overruns when the data frame size is short. Each direction has its own FIFO called TXFIFO and RXFIFO. These FIFOs are used in all SPI modes except for receiver-only mode (slave or master) with CRC calculation enabled (see Section 38.4.14: CRC calculation ).

The handling of FIFOs depends on the data exchange mode (duplex, simplex), data frame format (number of bits in the frame), access size performed on the FIFO data registers (8-bit or 16-bit), and whether or not data packing is used when accessing the FIFOs (see Section 38.4.13: TI mode ).

A read access to the SPIx_DR register returns the oldest value stored in RXFIFO that has not been read yet. A write access to the SPIx_DR stores the written data in the TXFIFO at the end of a send queue. The read access must be always aligned with the RXFIFO threshold configured by the FRXTH bit in SPIx_CR2 register. FTLVL[1:0] and FRLVL[1:0] bits indicate the current occupancy level of both FIFOs.

A read access to the SPIx_DR register must be managed by the RXNE event. This event is triggered when data is stored in RXFIFO and the threshold (defined by FRXTH bit) is reached. When RXNE is cleared, RXFIFO is considered to be empty. In a similar way, write access of a data frame to be transmitted is managed by the TXE event. This event is triggered when the TXFIFO level is less than or equal to half of its capacity. Otherwise TXE is cleared and the TXFIFO is considered as full. In this way, RXFIFO can store up to four data frames, whereas TXFIFO can only store up to three when the data frame format is not greater than 8 bits. This difference prevents possible corruption of 3x 8-bit data frames already stored in the TXFIFO when software tries to write more data in 16-bit mode into TXFIFO. Both TXE and RXNE events can be polled or handled by interrupts. See Figure 383 through Figure 386 .

Another way to manage the data exchange is to use DMA (see Communication using DMA (direct memory addressing) ).

If the next data is received when the RXFIFO is full, an overrun event occurs (see description of OVR flag at Section 38.4.10: SPI status flags ). An overrun event can be polled or handled by an interrupt.

The BSY bit being set indicates ongoing transaction of a current data frame. When the clock signal runs continuously, the BSY flag stays set between data frames at master but becomes low for a minimum duration of one SPI clock at slave between each data frame transfer.

Sequence handling

A few data frames can be passed at single sequence to complete a message. When transmission is enabled, a sequence begins and continues while any data is present in the TXFIFO of the master. The clock signal is provided continuously by the master until TXFIFO becomes empty, then it stops waiting for additional data.

In receive-only modes, half-duplex (BIDIMODE=1, BIDIOE=0) or simplex (BIDIMODE=0, RXONLY=1) the master starts the sequence immediately when both SPI is enabled and receive-only mode is activated. The clock signal is provided by the master and it does not stop until either SPI or receive-only mode is disabled by the master. The master receives data frames continuously up to this moment.

While the master can provide all the transactions in continuous mode (SCK signal is continuous) it has to respect slave capability to handle data flow and its content at anytime. When necessary, the master must slow down the communication and provide either a slower clock or separate frames or data sessions with sufficient delays. Be aware there is no underflow error signal for master or slave in SPI mode, and data from the slave is always transacted and processed by the master even if the slave could not prepare it correctly in time. It is preferable for the slave to use DMA, especially when data frames are shorter and bus rate is high.

Each sequence must be encased by the NSS pulse in parallel with the multislave system to select just one of the slaves for communication. In a single slave system it is not necessary to control the slave with NSS, but it is often better to provide the pulse here too, to synchronize the slave with the beginning of each data sequence. NSS can be managed by both software and hardware (see Section 38.4.5: Slave select (NSS) pin management ).

When the BSY bit is set it signifies an ongoing data frame transaction. When the dedicated frame transaction is finished, the RXNE flag is raised. The last bit is just sampled and the complete data frame is stored in the RXFIFO.

Procedure for disabling the SPI

When SPI is disabled, it is mandatory to follow the disable procedures described in this paragraph. It is important to do this before the system enters a low-power mode when the peripheral clock is stopped. Ongoing transactions can be corrupted in this case. In some modes the disable procedure is the only way to stop continuous communication running.

Master in full-duplex or transmit only mode can finish any transaction when it stops providing data for transmission. In this case, the clock stops after the last data transaction. Special care must be taken in packing mode when an odd number of data frames are transacted to prevent some dummy byte exchange (refer to Data packing section). Before the SPI is disabled in these modes, the user must follow standard disable procedure. When

the SPI is disabled at the master transmitter while a frame transaction is ongoing or next data frame is stored in TXFIFO, the SPI behavior is not guaranteed.

When the master is in any receive only mode, the only way to stop the continuous clock is to disable the peripheral by SPE=0. This must occur in specific time window within last data frame transaction just between the sampling time of its first bit and before its last bit transfer starts (in order to receive a complete number of expected data frames and to prevent any additional “dummy” data reading after the last valid data frame). Specific procedure must be followed when disabling SPI in this mode.

Data received but not read remains stored in RXFIFO when the SPI is disabled, and must be processed the next time the SPI is enabled, before starting a new sequence. To prevent having unread data, ensure that RXFIFO is empty when disabling the SPI, by using the correct disabling procedure, or by initializing all the SPI registers with a software reset via the control of a specific register dedicated to peripheral reset (see the SPIIRST bits in the RCC_APB1RSTR registers).

Standard disable procedure is based on pulling BSY status together with FTLVL[1:0] to check if a transmission session is fully completed. This check can be done in specific cases, too, when it is necessary to identify the end of ongoing transactions, for example:

• When NSS signal is managed by software and master has to provide proper end of NSS pulse for slave, or
• When transactions' streams from DMA or FIFO are completed while the last data frame or CRC frame transaction is still ongoing in the peripheral bus.

The correct disable procedure is (except when receive only mode is used):

1. Wait until FTLVL[1:0] = 00 (no more data to transmit).
2. Wait until BSY=0 (the last data frame is processed).
3. Disable the SPI (SPE=0).
4. Read data until FRLVL[1:0] = 00 (read all the received data).

The correct disable procedure for certain receive only modes is:

1. Interrupt the receive flow by disabling SPI (SPE=0) in the specific time window while the last data frame is ongoing.
2. Wait until BSY=0 (the last data frame is processed).
3. Read data until FRLVL[1:0] = 00 (read all the received data).

Note: If packing mode is used and an odd number of data frames with a format less than or equal to 8 bits (fitting into one byte) has to be received, FRXTH must be set when FRLVL[1:0] = 01, in order to generate the RXNE event to read the last odd data frame and to keep good FIFO pointer alignment.

Data packing

When the data frame size fits into one byte (less than or equal to 8 bits), data packing is used automatically when any read or write 16-bit access is performed on the SPIx_DR register. The double data frame pattern is handled in parallel in this case. At first, the SPI operates using the pattern stored in the LSB of the accessed word, then with the other half stored in the MSB. Figure 382 provides an example of data packing mode sequence handling. Two data frames are sent after the single 16-bit access the SPIx_DR register of the transmitter. This sequence can generate just one RXNE event in the receiver if the RXFIFO threshold is set to 16 bits (FRXTH=0). The receiver then has to access both data frames by a single 16-bit read of SPIx_DR as a response to this single RXNE event. The

RxFIFO threshold setting and the following read access must be always kept aligned at the receiver side, as data can be lost if it is not in line.

A specific problem appears if an odd number of such “fit into one byte” data frames must be handled. On the transmitter side, writing the last data frame of any odd sequence with an 8-bit access to SPIx_DR is enough. The receiver has to change the Rx_FIFO threshold level for the last data frame received in the odd sequence of frames in order to generate the RXNE event.

Figure 382. Packing data in FIFO for transmission and reception

16-bit access when write to data register
SPI _DR= 0x040A when TXE=1

16-bit access when read from data register
SPI _DR= 0x040A when RXNE=1

MS19590V1

Figure 382: Packing data in FIFO for transmission and reception. The diagram shows the internal structure of an SPI interface. On the left, the TXFIFO is filled with data from the SPIx_DR register. A 16-bit access is shown writing 0x04 and 0x0A into the FIFO. The SPI fsm & shift block then transmits this data over the MOSI line, synchronized with the SCK signal. The NSS signal is shown as active low. On the right, the RXFIFO receives the transmitted data. A 16-bit access is shown reading 0x04 and 0x0A from the SPIx_DR register. The SPI fsm & shift block also handles the reception. The diagram includes timing diagrams for NSS, SCK, and MOSI signals. Text labels indicate that a 16-bit access to SPIx_DR is required when TXE=1 for transmission and when RXNE=1 for reception.

Communication using DMA (direct memory addressing)

To operate at its maximum speed and to facilitate the data register read/write process required to avoid overrun, the SPI features a DMA capability, which implements a simple request/acknowledge protocol.

A DMA access is requested when the TXDMAEN or RXDMAEN enable bit in the SPIx_CR2 register is set. Separate requests must be issued to the Tx and Rx buffers.

• In transmission, a DMA request is issued each time TXE is set to 1. The DMA then writes to the SPIx_DR register.
• In reception, a DMA request is issued each time RXNE is set to 1. The DMA then reads the SPIx_DR register.

See Figure 383 through Figure 386 .

When the SPI is used only to transmit data, it is possible to enable only the SPI Tx DMA channel. In this case, the OVR flag is set because the data received is not read. When the SPI is used only to receive data, it is possible to enable only the SPI Rx DMA channel.

In transmission mode, when the DMA has written all the data to be transmitted (the TCIF flag is set in the DMA_ISR register), the BSY flag can be monitored to ensure that the SPI communication is complete. This is required to avoid corrupting the last transmission before disabling the SPI or entering the Stop mode. The software must first wait until FTLVL[1:0]=00 and then until BSY=0.

When starting communication using DMA, to prevent DMA channel management raising error events, these steps must be followed in order:

1. Enable DMA Rx buffer in the RXDMAEN bit in the SPI_CR2 register, if DMA Rx is used.
2. Enable DMA streams for Tx and Rx in DMA registers, if the streams are used.
3. Enable DMA Tx buffer in the TXDMAEN bit in the SPI_CR2 register, if DMA Tx is used.
4. Enable the SPI by setting the SPE bit.

To close communication it is mandatory to follow these steps in order:

1. Disable DMA streams for Tx and Rx in the DMA registers, if the streams are used.
2. Disable the SPI by following the SPI disable procedure.
3. Disable DMA Tx and Rx buffers by clearing the TXDMAEN and RXDMAEN bits in the SPI_CR2 register, if DMA Tx and/or DMA Rx are used.

Packing with DMA

If the transfers are managed by DMA (TXDMAEN and RXDMAEN set in the SPIx_CR2 register) packing mode is enabled/disabled automatically depending on the PSIZE value configured for SPI TX and the SPI RX DMA channel. If the DMA channel PSIZE value is equal to 16-bit and SPI data size is less than or equal to 8-bit, then packing mode is enabled. The DMA then automatically manages the write operations to the SPIx_DR register.

If data packing mode is used and the number of data to transfer is not a multiple of two, the LDMA_TX/LDMA_RX bits must be set. The SPI then considers only one data for the transmission or reception to serve the last DMA transfer (for more details refer to Data packing on page 1225 .)

Communication diagrams

Some typical timing schemes are explained in this section. These schemes are valid no matter if the SPI events are handled by polling, interrupts or DMA. For simplicity, the LSBFIRST=0, CPOL=0 and CPHA=1 setting is used as a common assumption here. No complete configuration of DMA streams is provided.

The following numbered notes are common for Figure 383 on page 1229 through Figure 386 on page 1232 :

1. The slave starts to control MISO line as NSS is active and SPI is enabled, and is disconnected from the line when one of them is released. Sufficient time must be provided for the slave to prepare data dedicated to the master in advance before its transaction starts.
At the master, the SPI peripheral takes control at MOSI and SCK signals (occasionally at NSS signal as well) only if SPI is enabled. If SPI is disabled the SPI peripheral is disconnected from GPIO logic, so the levels at these lines depends on GPIO setting exclusively.
2. At the master, BSY stays active between frames if the communication (clock signal) is continuous. At the slave, BSY signal always goes down for at least one clock cycle between data frames.
3. The TXE signal is cleared only if TXFIFO is full.
4. The DMA arbitration process starts just after the TXDMAEN bit is set. The TXE interrupt is generated just after the TXEIE is set. As the TXE signal is at an active level, data transfers to TxFIFO start, until TxFIFO becomes full or the DMA transfer completes.
5. If all the data to be sent can fit into TxFIFO, the DMA Tx TCIF flag can be raised even before communication on the SPI bus starts. This flag always rises before the SPI transaction is completed.
6. The CRC value for a package is calculated continuously frame by frame in the SPIx_TXCRCR and SPIx_RXCRCR registers. The CRC information is processed after the entire data package has completed, either automatically by DMA (Tx channel must be set to the number of data frames to be processed) or by SW (the user must handle CRCNEXT bit during the last data frame processing).
While the CRC value calculated in SPIx_TXCRCR is simply sent out by transmitter, received CRC information is loaded into RxFIFO and then compared with the SPIx_RXCRCR register content (CRC error flag can be raised here if any difference). This is why the user must take care to flush this information from the FIFO, either by software reading out all the stored content of RxFIFO, or by DMA when the proper number of data frames is preset for Rx channel (number of data frames + number of CRC frames) (see the settings at the example assumption).
7. In data packed mode, TxE and RxNE events are paired and each read/write access to the FIFO is 16 bits wide until the number of data frames are even. If the TxFIFO is $\frac{3}{4}$ full FTLVL status stays at FIFO full level. That is why the last odd data frame cannot be stored before the TxFIFO becomes $\frac{1}{2}$ full. This frame is stored into TxFIFO with an 8-bit access either by software or automatically by DMA when LDMA_TX control is set.
8. To receive the last odd data frame in packed mode, the Rx threshold must be changed to 8-bit when the last data frame is processed, either by software setting FRXTH=1 or automatically by a DMA internal signal when LDMA_RX is set.

Figure 383. Master full-duplex communication

Timing diagram for master full-duplex SPI communication showing signal transitions and data flow for three frames.

The diagram illustrates the timing for master full-duplex SPI communication across three frames. The signals shown are:

NSS : Slave Select, active low. It is pulled low at the start of the first frame and returns high after the third frame.
SCK : Serial Clock, shown as a continuous square wave.
BSY : Busy flag, which goes high at the start of the first frame and returns low after the third frame. It is marked with '2' in two circles.
MOSI : Master Out Slave In. It transmits three frames: DTx1, DTx2, and DTx3. Each frame starts with the Most Significant Bit (MSB).
SPE : Serial Peripheral Enable, shown as a high signal throughout.
TXE : Transmit Buffer Empty flag. It pulses low when the buffer is empty, marked with '3' in two circles. A box labeled 'Enable Tx/Rx DMA or interrupts' is active during these pulses.
FTLVL : FIFO Level. It shows the level of data in the transmit FIFO: 00, 10, 11, 10, 11, 10, 00. Arrows indicate the loading of DTx1, DTx2, and DTx3 into the FIFO.
MISO : Master In Slave Out. It receives three frames: DRx1, DRx2, and DRx3. Each frame ends with the Least Significant Bit (LSB). It is marked with '4' in a circle at the start and '1' in a circle at the end.
RXNE : Receive Buffer Not Empty flag, which pulses high when a new frame is received.
FRLVL : FIFO Level for reception. It shows the level of data in the receive FIFO: 00, 10, 00, 10, 00, 10, 00. Arrows indicate the reading of DRx1, DRx2, and DRx3 from the FIFO. A box labeled 'DMA or software control at Rx events' is active during these reads.
DMA Tx TICF : DMA Transmit Transfer Interrupt Flag, which pulses high at the end of the third frame, marked with '5' in a circle.
DMA Rx TICF : DMA Receive Transfer Interrupt Flag, which pulses high at the end of the third frame.

Control signals for DMA or software control are indicated: 'Enable Tx/Rx DMA or interrupts' for transmission and 'DMA or software control at Tx events' and 'DMA or software control at Rx events' for reception.

Timing diagram for master full-duplex SPI communication showing signal transitions and data flow for three frames.

Assumptions for master full-duplex communication example:

• Data size > 8 bit

If DMA is used:

• Number of Tx frames transacted by DMA is set to 3
• Number of Rx frames transacted by DMA is set to 3

See also : Communication diagrams on page 1228 for details about common assumptions and notes.

Figure 384. Slave full-duplex communication

Timing diagram for SPI slave full-duplex communication showing signal transitions for NSS, SCK, BSY, MISO, SPE, TXE, FTLVL, MOSI, RXNE, and FRLVL over three data frames. Annotations include MSB/LSB markers, DMA control signals, and event indicators (1-5).

The diagram illustrates the timing for slave full-duplex SPI communication across three data frames. The signals shown are:

NSS (Slave Select): Active-low signal, held high throughout the sequence.
SCK (Serial Clock): Generated by the master, shown as a continuous square wave.
BSY (Busy): Goes high when the SPI is active and returns low when idle. It is labeled with a circled '2'.
MISO (Master In Slave Out): Outputs data from the slave to the master. It shows three frames: DTx1, DTx2, and DTx3. Each frame starts with the Most Significant Bit (MSB) and ends with the Least Significant Bit (LSB). A circled '1' is at the end of the third frame.
SPE (SPI Enable): Goes high to enable the SPI interface. It is labeled with a circled '1' at the start.
TXE (Transmit Buffer Empty): Goes high when the transmit buffer is empty and ready for new data. It is labeled with circled '3' at the start of each frame. A callout indicates 'Enable Tx/Rx DMA or interrupts' and 'DMA or software control at Tx events'.
FTLVL (Fill Level): Shows the level of data in the transmit buffer. It starts at 00, rises to 10 and 11 as data is written (DTx1, DTx2, DTx3), and returns to 00 after transmission. A circled '4' points to the start of the first frame.
MOSI (Master Out Slave In): Receives data from the master. It shows three frames: DRx1, DRx2, and DRx3. Each frame starts with the MSB and ends with the LSB. A callout indicates 'DMA or software control at Rx events'.
RXNE (Receive Buffer Not Empty): Goes high when there is data in the receive buffer to be read. It pulses high at the end of each received frame (DRx1, DRx2, DRx3).
FRLVL (Fill Level): Shows the level of data in the receive buffer. It starts at 00, rises to 10 and 00 as data is received (DRx1, DRx2, DRx3), and returns to 00 after reading. A circled '5' is at the end of the sequence.

Other labels include 'DMA Tx TICF' and 'DMA Rx TICF' at the bottom, and the identifier 'MSv32123V2' in the bottom right corner.

Timing diagram for SPI slave full-duplex communication showing signal transitions for NSS, SCK, BSY, MISO, SPE, TXE, FTLVL, MOSI, RXNE, and FRLVL over three data frames. Annotations include MSB/LSB markers, DMA control signals, and event indicators (1-5).

Assumptions for slave full-duplex communication example:

• Data size > 8 bit

If DMA is used:

• Number of Tx frames transacted by DMA is set to 3
• Number of Rx frames transacted by DMA is set to 3

See also Communication diagrams on page 1228 for details about common assumptions and notes.

Figure 385. Master full-duplex communication with CRC

Timing diagram for master full-duplex SPI communication with CRC. The diagram shows the relationship between NSS, SCK, BSY, MOSI, SPE, TXE, FTLVL, MISO, RXNE, and FRLVL signals over time. It illustrates the transmission of two data frames (DTx1, DTx2) and a CRC frame on the MOSI line, and the reception of three data frames (DRx1, DRx2, DRx3) and a CRC frame on the MISO line. The diagram also shows the state of the FTLVL and FRLVL registers and the generation of DMA Tx and Rx TICF flags. Numbered circles 1-6 indicate key events: 1. RXNE goes high when DRx1 is ready; 2. BSY goes high when the first frame is transmitted; 3. TXE goes high when DTx1 is ready for transmission; 4. FTLVL becomes 10 when DTx1 and DTx2 are ready; 5. DMA Tx TICF goes high when FTLVL reaches 11; 6. DMA Rx TICF goes high when FRLVL reaches 10.

Assumptions for master full-duplex communication with CRC example:

• Data size = 16 bit
• CRC enabled

If DMA is used:

• Number of Tx frames transacted by DMA is set to 2
• Number of Rx frames transacted by DMA is set to 3

See also : Communication diagrams on page 1228 for details about common assumptions and notes.

Figure 386. Master full-duplex communication in packed mode

Timing diagram for SPI master full-duplex communication in packed mode. It shows the relationship between NSS, SCK, BSY, MOSI, SPE, TXE, FTLVL, MISO, RXNE, and FRLVL signals over time. The diagram illustrates the flow of 5-bit data frames (DTx1-2, DTx3-4, DTx5) and the corresponding receive frames (DRx1-2, DRx3-4, DRx5). Key events include the assertion of BSY, the start of SCK, the transmission of data on MOSI, and the reception of data on MISO. The FTLVL and FRLVL signals show the level of data in the transmit and receive FIFOs, respectively. Annotations indicate DMA or software control points for transmission and reception. Numbered circles (1-8) mark specific events: 1. RXNE assertion; 2. BSY assertion; 3. TXE assertion; 4. First data frame on MISO; 5. DMA Tx TICF; 6. DTx5 transmission; 7. DMA or software control at Tx event; 8. FRTHX=1.

Assumptions for master full-duplex communication in packed mode example:

• Data size = 5 bit
• Read/write FIFO is performed mostly by 16-bit access
• FRXTH=0

If DMA is used:

• Number of Tx frames to be transacted by DMA is set to 3
• Number of Rx frames to be transacted by DMA is set to 3
• PSIZE for both Tx and Rx DMA channel is set to 16-bit
• LDMA_TX=1 and LDMA_RX=1

See also : Communication diagrams on page 1228 for details about common assumptions and notes.

38.4.10 SPI status flags

Three status flags are provided for the application to completely monitor the state of the SPI bus.

Tx buffer empty flag (TXE)

The TXE flag is set when transmission TXFIFO has enough space to store data to send. TXE flag is linked to the TXFIFO level. The flag goes high and stays high until the TXFIFO level is lower or equal to 1/2 of the FIFO depth. An interrupt can be generated if the TXEIE bit in the SPIx_CR2 register is set. The bit is cleared automatically when the TXFIFO level becomes greater than 1/2.

Rx buffer not empty (RXNE)

The RXNE flag is set depending on the FRXTH bit value in the SPIx_CR2 register:

• If FRXTH is set, RXNE goes high and stays high until the RXFIFO level is greater or equal to 1/4 (8-bit).
• If FRXTH is cleared, RXNE goes high and stays high until the RXFIFO level is greater than or equal to 1/2 (16-bit).

An interrupt can be generated if the RXNEIE bit in the SPIx_CR2 register is set.

The RXNE is cleared by hardware automatically when the above conditions are no longer true.

Busy flag (BSY)

The BSY flag is set and cleared by hardware (writing to this flag has no effect).

When BSY is set, it indicates that a data transfer is in progress on the SPI (the SPI bus is busy).

The BSY flag can be used in certain modes to detect the end of a transfer so that the software can disable the SPI or its peripheral clock before entering a low-power mode which does not provide a clock for the peripheral. This avoids corrupting the last transfer.

The BSY flag is also useful for preventing write collisions in a multimaster system.

The BSY flag is cleared under any one of the following conditions:

• When the SPI is correctly disabled
• When a fault is detected in Master mode (MODF bit set to 1)
• In Master mode, when it finishes a data transmission and no new data is ready to be sent
• In Slave mode, when the BSY flag is set to '0' for at least one SPI clock cycle between each data transfer.

Note: When the next transmission can be handled immediately by the master (e.g. if the master is in Receive-only mode or its Transmit FIFO is not empty), communication is continuous and the BSY flag remains set to '1' between transfers on the master side. Although this is not the case with a slave, it is recommended to use always the TXE and RXNE flags (instead of the BSY flags) to handle data transmission or reception operations.

38.4.11 SPI error flags

An SPI interrupt is generated if one of the following error flags is set and interrupt is enabled by setting the ERRIE bit.

Overrun flag (OVR)

An overrun condition occurs when data is received by a master or slave and the RXFIFO has not enough space to store this received data. This can happen if the software or the DMA did not have enough time to read the previously received data (stored in the RXFIFO) or when space for data storage is limited e.g. the RXFIFO is not available when CRC is enabled in receive only mode so in this case the reception buffer is limited into a single data frame buffer (see Section 38.4.14: CRC calculation ).

When an overrun condition occurs, the newly received value does not overwrite the previous one in the RXFIFO. The newly received value is discarded and all data transmitted subsequently is lost. Clearing the OVR bit is done by a read access to the SPI_DR register followed by a read access to the SPI_SR register.

Mode fault (MODF)

Mode fault occurs when the master device has its internal NSS signal (NSS pin in NSS hardware mode, or SSI bit in NSS software mode) pulled low. This automatically sets the MODF bit. Master mode fault affects the SPI interface in the following ways:

• The MODF bit is set and an SPI interrupt is generated if the ERRIE bit is set.
• The SPE bit is cleared. This blocks all output from the device and disables the SPI interface.
• The MSTR bit is cleared, thus forcing the device into slave mode.

Use the following software sequence to clear the MODF bit:

1. Make a read or write access to the SPIx_SR register while the MODF bit is set.
2. Then write to the SPIx_CR1 register.

To avoid any multiple slave conflicts in a system comprising several MCUs, the NSS pin must be pulled high during the MODF bit clearing sequence. The SPE and MSTR bits can be restored to their original state after this clearing sequence. As a security, hardware does not allow the SPE and MSTR bits to be set while the MODF bit is set. In a slave device the MODF bit cannot be set except as the result of a previous multimaster conflict.

CRC error (CRCERR)

This flag is used to verify the validity of the value received when the CRCEN bit in the SPIx_CR1 register is set. The CRCERR flag in the SPIx_SR register is set if the value received in the shift register does not match the receiver SPIx_RXCRCR value. The flag is cleared by the software.

TI mode frame format error (FRE)

A TI mode frame format error is detected when an NSS pulse occurs during an ongoing communication when the SPI is operating in slave mode and configured to conform to the TI mode protocol. When this error occurs, the FRE flag is set in the SPIx_SR register. The SPI is not disabled when an error occurs, the NSS pulse is ignored, and the SPI waits for the next NSS pulse before starting a new transfer. The data may be corrupted since the error detection may result in the loss of two data bytes.

The FRE flag is cleared when SPIx_SR register is read. If the ERRIE bit is set, an interrupt is generated on the NSS error detection. In this case, the SPI should be disabled because data consistency is no longer guaranteed and communications should be reinitiated by the master when the slave SPI is enabled again.

38.4.12 NSS pulse mode

This mode is activated by the NSSP bit in the SPIx_CR2 register and it takes effect only if the SPI interface is configured as Motorola SPI master (FRF=0) with capture on the first edge (SPIx_CR1 CPHA = 0, CPOL setting is ignored). When activated, an NSS pulse is generated between two consecutive data frame transfers when NSS stays at high level for the duration of one clock period at least. This mode allows the slave to latch data. NSSP pulse mode is designed for applications with a single master-slave pair.

Figure 387 illustrates NSS pin management when NSSP pulse mode is enabled.

Figure 387. NSSP pulse generation in Motorola SPI master mode

Timing diagram for NSSP pulse generation in Motorola SPI master mode. The diagram shows four signals: NSS output, SCK output, MOSI output, and MISO input. The NSS output is high before the first SCK edge and goes low at the first SCK edge, returning high after the last SCK edge of a frame. The SCK output is a continuous square wave. The MOSI output shows data frames (MSB and LSB) being transmitted. The MISO input shows 'Do not care' periods at the beginning and end of each frame, with data being received during the frame. Sampling edges are marked on the SCK signal. The duration of each frame is indicated as 4-bits to 16-bits. The diagram is titled 'Master continuous transfer (CPOL = 1; CPHA = 0; NSSP= 1)'. Timing markers for t_SCK are shown between clock edges and NSS transitions.

Note: Similar behavior is encountered when CPOL = 0. In this case the sampling edge is the rising edge of SCK, and NSS assertion and deassertion refer to this sampling edge.

38.4.13 TI mode

TI protocol in master mode

The SPI interface is compatible with the TI protocol. The FRF bit of the SPIx_CR2 register can be used to configure the SPI to be compliant with this protocol.

The clock polarity and phase are forced to conform to the TI protocol requirements whatever the values set in the SPIx_CR1 register. NSS management is also specific to the TI protocol which makes the configuration of NSS management through the SPIx_CR1 and SPIx_CR2 registers (SSM, SSI, SSOE) impossible in this case.

In slave mode, the SPI baud rate prescaler is used to control the moment when the MISO pin state changes to HiZ when the current transaction finishes (see Figure 388). Any baud rate can be used, making it possible to determine this moment with optimal flexibility. However, the baud rate is generally set to the external master clock baud rate. The delay for the MISO signal to become HiZ ( $t_{\text{release}}$ ) depends on internal resynchronization and on the

baud rate value set in through the BR[2:0] bits in the SPIx_CR1 register. It is given by the formula:

\frac{t_{\text{baud\_rate}}}{2} + 4 \times t_{\text{pclk}} < t_{\text{release}} < \frac{t_{\text{baud\_rate}}}{2} + 6 \times t_{\text{pclk}}

If the slave detects a misplaced NSS pulse during a data frame transaction the TIFRE flag is set.

If the data size is equal to 4-bits or 5-bits, the master in full-duplex mode or transmit-only mode uses a protocol with one more dummy data bit added after LSB. TI NSS pulse is generated above this dummy bit clock cycle instead of the LSB in each period.

This feature is not available for Motorola SPI communications (FRF bit set to 0).

Figure 388: TI mode transfer shows the SPI communication waveforms when TI mode is selected.

Figure 388. TI mode transfer

The diagram shows the timing for TI mode transfer. The top signal is NSS (Slave Select), which is active low. It is pulled low at the start of FRAME 1 and goes high at the start of FRAME 2. Below it is SCK (Serial Clock), a square wave. The MOSI (Master Out Slave In) signal shows data being transmitted from master to slave. The first byte has a 'Do not care' initial state, followed by MSB and LSB. The second byte also has MSB and LSB. The MISO (Master In Slave Out) signal shows data being received from slave to master. The first byte has '1 or 0', MSB, and LSB. The second byte also has MSB and LSB. The SCK signal has 'trigger' and 'sampling' points marked. The 'trigger' points are at the rising edges of SCK, and the 'sampling' points are at the falling edges of SCK. The release time (t_RELEASE) is indicated for the NSS signal, measured from the falling edge of SCK to the rising edge of NSS.

Timing diagram for TI mode transfer showing waveforms for NSS, SCK, MOSI, and MISO signals. The diagram illustrates two frames (FRAME 1 and FRAME 2) with trigger and sampling points for the clock (SCK). The MOSI signal shows data bits (MSB, LSB) being transmitted, while the MISO signal shows data bits (1 or 0, MSB, LSB) being received. The release time (t_RELEASE) is indicated for the NSS signal.

38.4.14 CRC calculation

Two separate CRC calculators are implemented in order to check the reliability of transmitted and received data. The SPI offers CRC8 or CRC16 calculation independently of the frame data length, which can be fixed to 8-bit or 16-bit. For all the other data frame lengths, no CRC is available.

CRC principle

CRC calculation is enabled by setting the CRCEN bit in the SPIx_CR1 register before the SPI is enabled (SPE = 1). The CRC value is calculated using an odd programmable polynomial on each bit. The calculation is processed on the sampling clock edge defined by the CPHA and CPOL bits in the SPIx_CR1 register. The calculated CRC value is checked automatically at the end of the data block as well as for transfer managed by CPU or by the DMA. When a mismatch is detected between the CRC calculated internally on the received data and the CRC sent by the transmitter, a CRCERR flag is set to indicate a data corruption error. The right procedure for handling the CRC calculation depends on the SPI configuration and the chosen transfer management.

Note: The polynomial value should only be odd. No even values are supported.

CRC transfer managed by CPU

Communication starts and continues normally until the last data frame has to be sent or received in the SPIx_DR register. Then CRCNEXT bit has to be set in the SPIx_CR1 register to indicate that the CRC frame transaction follows after the transaction of the currently processed data frame. The CRCNEXT bit must be set before the end of the last data frame transaction. CRC calculation is frozen during CRC transaction.

The received CRC is stored in the RXFIFO like a data byte or word. That is why in CRC mode only, the reception buffer has to be considered as a single 16-bit buffer used to receive only one data frame at a time.

A CRC-format transaction usually takes one more data frame to communicate at the end of data sequence. However, when setting an 8-bit data frame checked by 16-bit CRC, two more frames are necessary to send the complete CRC.

When the last CRC data is received, an automatic check is performed comparing the received value and the value in the SPIx_RXCRC register. Software has to check the CRCERR flag in the SPIx_SR register to determine if the data transfers were corrupted or not. Software clears the CRCERR flag by writing '0' to it.

After the CRC reception, the CRC value is stored in the RXFIFO and must be read in the SPIx_DR register in order to clear the RXNE flag.

CRC transfer managed by DMA

When SPI communication is enabled with CRC communication and DMA mode, the transmission and reception of the CRC at the end of communication is automatic (with the exception of reading CRC data in receive only mode). The CRCNEXT bit does not have to be handled by the software. The counter for the SPI transmission DMA channel has to be set to the number of data frames to transmit excluding the CRC frame. On the receiver side, the received CRC value is handled automatically by DMA at the end of the transaction but user must take care to flush out received CRC information from RXFIFO as it is always loaded into it. In full-duplex mode, the counter of the reception DMA channel can be set to the number of data frames to receive including the CRC, which means, for example, in the specific case of an 8-bit data frame checked by 16-bit CRC:

\text{DMA\_RX} = \text{Numb\_of\_data} + 2

In receive only mode, the DMA reception channel counter should contain only the amount of data transferred, excluding the CRC calculation. Then based on the complete transfer from DMA, all the CRC values must be read back by software from FIFO as it works as a single buffer in this mode.

At the end of the data and CRC transfers, the CRCERR flag in the SPIx_SR register is set if corruption occurred during the transfer.

If packing mode is used, the LDMA_RX bit needs managing if the number of data is odd.

Resetting the SPIx_TXCRC and SPIx_RXCRC values

The SPIx_TXCRC and SPIx_RXCRC values are cleared automatically when new data is sampled after a CRC phase. This allows the use of DMA circular mode (not available in receive-only mode) in order to transfer data without any interruption, (several data blocks covered by intermediate CRC checking phases).

If the SPI is disabled during a communication the following sequence must be followed:

1. Disable the SPI
2. Clear the CRCEN bit
3. Enable the CRCEN bit
4. Enable the SPI

Note: When the SPI interface is configured as a slave, the NSS internal signal needs to be kept low during transaction of the CRC phase once the CRCNEXT signal is released. That is why the CRC calculation cannot be used at NSS Pulse mode when NSS hardware mode should be applied at slave normally.

At TI mode, despite the fact that clock phase and clock polarity setting is fixed and independent on SPIx_CR1 register, the corresponding setting CPOL=0 CPHA=1 has to be kept at the SPIx_CR1 register anyway if CRC is applied. In addition, the CRC calculation has to be reset between sessions by SPI disable sequence with re-enable the CRCEN bit described above at both master and slave side, else CRC calculation can be corrupted at this specific mode.

38.5 SPI interrupts

During SPI communication an interrupt can be generated by the following events:

• Transmit TXFIFO ready to be loaded
• Data received in Receive RXFIFO
• Master mode fault
• Overrun error
• TI frame format error
• CRC protocol error

Interrupts can be enabled and disabled separately.

Table 239. SPI interrupt requests

Interrupt event	Event flag	Enable Control bit
Transmit TXFIFO ready to be loaded	TXE	TXEIE
Data received in RXFIFO	RXNE	RXNEIE
Master Mode fault event	MODF	ERRIE
Overrun error	OVR
TI frame format error	FRE
CRC protocol error	CRCERR

38.6 SPI registers

The peripheral registers can be accessed by half-words (16-bit) or words (32-bit). SPI_DR in addition can be accessed by 8-bit access.

38.6.1 SPI control register 1 (SPIx_CR1)

Address offset: 0x00

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
BIDI MODE	BIDIOE	CRC EN	CRCN EXT	CRCL	RX ONLY	SSM	SSI	LSB FIRST	SPE	BR[2:0]			MSTR	CPOL	CPHA
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bit 15 BIDIMODE : Bidirectional data mode enable.

This bit enables half-duplex communication using common single bidirectional data line. Keep RXONLY bit clear when bidirectional mode is active.

0: 2-line unidirectional data mode selected

1: 1-line bidirectional data mode selected

Bit 14 BIDIOE : Output enable in bidirectional mode

This bit combined with the BIDIMODE bit selects the direction of transfer in bidirectional mode.

0: Output disabled (receive-only mode)

1: Output enabled (transmit-only mode)

Note: In master mode, the MOSI pin is used and in slave mode, the MISO pin is used.

Bit 13 CRCEN : Hardware CRC calculation enable

0: CRC calculation disabled

1: CRC calculation enabled

Note: This bit should be written only when SPI is disabled (SPE = '0') for correct operation.

Bit 12 CRCNEXT : Transmit CRC next

0: Next transmit value is from Tx buffer.

1: Next transmit value is from Tx CRC register.

Note: This bit has to be written as soon as the last data is written in the SPIx_DR register.

Bit 11 CRCL : CRC length

This bit is set and cleared by software to select the CRC length.

0: 8-bit CRC length

1: 16-bit CRC length

Note: This bit should be written only when SPI is disabled (SPE = '0') for correct operation.

Bit 10 RXONLY : Receive only mode enabled.

This bit enables simplex communication using a single unidirectional line to receive data exclusively. Keep BIDIMODE bit clear when receive only mode is active. This bit is also useful in a multislave system in which this particular slave is not accessed, the output from the accessed slave is not corrupted.

0: Full-duplex (Transmit and receive)

1: Output disabled (Receive-only mode)

Bit 9 SSM : Software slave management

When the SSM bit is set, the NSS pin input is replaced with the value from the SSI bit.

0: Software slave management disabled

1: Software slave management enabled

Note: This bit is not used in SPI TI mode.

Bit 8 SSI : Internal slave select

This bit has an effect only when the SSM bit is set. The value of this bit is forced onto the NSS pin and the I/O value of the NSS pin is ignored.

Note: This bit is not used in SPI TI mode.

Bit 7 LSBFIRST : Frame format

0: data is transmitted / received with the MSB first

1: data is transmitted / received with the LSB first

Note: 1. This bit should not be changed when communication is ongoing.

2. This bit is not used in SPI TI mode.

Bit 6 SPE : SPI enable

0: Peripheral disabled

1: Peripheral enabled

Note: When disabling the SPI, follow the procedure described in Procedure for disabling the SPI on page 1224 .

Bits 5:3 BR[2:0] : Baud rate control

000: $f_{PCLK}/2$

001: $f_{PCLK}/4$

010: $f_{PCLK}/8$

011: $f_{PCLK}/16$

100: $f_{PCLK}/32$

101: $f_{PCLK}/64$

110: $f_{PCLK}/128$

111: $f_{PCLK}/256$

Note: These bits should not be changed when communication is ongoing.

Bit 2 MSTR : Master selection

0: Slave configuration

1: Master configuration

Note: This bit should not be changed when communication is ongoing.

Bit 1 CPOL : Clock polarity

0: CK to 0 when idle

1: CK to 1 when idle

Note: This bit should not be changed when communication is ongoing.

This bit is not used in SPI TI mode except the case when CRC is applied at TI mode.

Bit 0 CPHA : Clock phase

0: The first clock transition is the first data capture edge

1: The second clock transition is the first data capture edge

Note: This bit should not be changed when communication is ongoing.

This bit is not used in SPI TI mode except the case when CRC is applied at TI mode.

38.6.2 SPI control register 2 (SPIx_CR2)

Address offset: 0x04

Reset value: 0x0700

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
Res.	LDMA_TX	LDMA_RX	FRXTH	DS[3:0]				TXEIE	RXNEIE	ERRIE	FRF	NSSP	SSOE	TXDMAEN	RXDMAEN
	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bit 15 Reserved, must be kept at reset value.

Bit 14 LDMA_TX : Last DMA transfer for transmission

This bit is used in data packing mode, to define if the total number of data to transmit by DMA is odd or even. It has significance only if the TXDMAEN bit in the SPIx_CR2 register is set and if packing mode is used (data length <= 8-bit and write access to SPIx_DR is 16-bit wide). It has to be written when the SPI is disabled (SPE = 0 in the SPIx_CR1 register).

0: Number of data to transfer is even

1: Number of data to transfer is odd

Note: Refer to Procedure for disabling the SPI on page 1224 if the CRCEN bit is set.

Bit 13 LDMA_RX : Last DMA transfer for reception

This bit is used in data packing mode, to define if the total number of data to receive by DMA is odd or even. It has significance only if the RXDMAEN bit in the SPIx_CR2 register is set and if packing mode is used (data length <= 8-bit and write access to SPIx_DR is 16-bit wide). It has to be written when the SPI is disabled (SPE = 0 in the SPIx_CR1 register).

0: Number of data to transfer is even

1: Number of data to transfer is odd

Note: Refer to Procedure for disabling the SPI on page 1224 if the CRCEN bit is set.

Bit 12 FRXTH : FIFO reception threshold

This bit is used to set the threshold of the RXFIFO that triggers an RXNE event

0: RXNE event is generated if the FIFO level is greater than or equal to 1/2 (16-bit)

1: RXNE event is generated if the FIFO level is greater than or equal to 1/4 (8-bit)

Bits 11:8 DS[3:0] : Data size

These bits configure the data length for SPI transfers.

0000: Not used

0001: Not used

0010: Not used

0011: 4-bit

0100: 5-bit

0101: 6-bit

0110: 7-bit

0111: 8-bit

1000: 9-bit

1001: 10-bit

1010: 11-bit

1011: 12-bit

1100: 13-bit

1101: 14-bit

1110: 15-bit

1111: 16-bit

If software attempts to write one of the “Not used” values, they are forced to the value “0111” (8-bit)

Bit 7 TXEIE : Tx buffer empty interrupt enable

0: TXE interrupt masked

1: TXE interrupt not masked. Used to generate an interrupt request when the TXE flag is set.

Bit 6 RXNEIE : RX buffer not empty interrupt enable

0: RXNE interrupt masked

1: RXNE interrupt not masked. Used to generate an interrupt request when the RXNE flag is set.

Bit 5 ERRIE : Error interrupt enable

This bit controls the generation of an interrupt when an error condition occurs (CRCERR, OVR, MODF in SPI mode, FRE at TI mode).

0: Error interrupt is masked

1: Error interrupt is enabled

Bit 4 FRF : Frame format

0: SPI Motorola mode

1: SPI TI mode

Note: This bit must be written only when the SPI is disabled (SPE=0).

Bit 3 NSSP : NSS pulse management

This bit is used in master mode only. it allows the SPI to generate an NSS pulse between two consecutive data when doing continuous transfers. In the case of a single data transfer, it forces the NSS pin high level after the transfer.

It has no meaning if CPHA = '1', or FRF = '1'.

0: No NSS pulse

1: NSS pulse generated

Note: 1. This bit must be written only when the SPI is disabled (SPE=0).

2. This bit is not used in SPI TI mode.

Bit 2 SSOE : SS output enable

0: SS output is disabled in master mode and the SPI interface can work in multimaster configuration

1: SS output is enabled in master mode and when the SPI interface is enabled. The SPI interface cannot work in a multimaster environment.

Note: This bit is not used in SPI TI mode.

Bit 1 TXDMAEN : Tx buffer DMA enable

When this bit is set, a DMA request is generated whenever the TXE flag is set.

0: Tx buffer DMA disabled

1: Tx buffer DMA enabled

Bit 0 RXDMAEN : Rx buffer DMA enable

When this bit is set, a DMA request is generated whenever the RXNE flag is set.

0: Rx buffer DMA disabled

1: Rx buffer DMA enabled

38.6.3 SPI status register (SPIx_SR)

Address offset: 0x08

Reset value: 0x0002

15	14	13	12		11		10	9	8	7	6	5	4	3	2	1	0
Res.	Res.	Res.	FTLVL[1:0]		FRLVL[1:0]		FRE	BSY	OVR	MODF	CRCE RR	Res.	Res.	TXE	RXNE
			r \| r		r \| r		r	r	r	r	rc_w0			r	r

Bits 15:13 Reserved, must be kept at reset value.

Bits 12:11 FTLVL[1:0] : FIFO transmission level

These bits are set and cleared by hardware.

00: FIFO empty

01: 1/4 FIFO

10: 1/2 FIFO

11: FIFO full (considered as FULL when the FIFO threshold is greater than 1/2)

Bits 10:9 FRLVL[1:0] : FIFO reception level

These bits are set and cleared by hardware.

00: FIFO empty

01: 1/4 FIFO

10: 1/2 FIFO

11: FIFO full

Note: These bits are not used in SPI receive-only mode while CRC calculation is enabled.

Bit 8 FRE : Frame format error

This flag is used for SPI in TI slave mode. Refer to Section 38.4.11: SPI error flags .

This flag is set by hardware and reset when SPIx_SR is read by software.

0: No frame format error

1: A frame format error occurred

Bit 7 BSY : Busy flag

0: SPI not busy

1: SPI is busy in communication or Tx buffer is not empty

This flag is set and cleared by hardware.

Note: The BSY flag must be used with caution: refer to Section 38.4.10: SPI status flags and Procedure for disabling the SPI on page 1224 .

Bit 6 OVR : Overrun flag

0: No overrun occurred

1: Overrun occurred

This flag is set by hardware and reset by a software sequence.

Bit 5 MODF : Mode fault

0: No mode fault occurred

1: Mode fault occurred

This flag is set by hardware and reset by a software sequence. Refer to Section : Mode fault (MODF) on page 1234 for the software sequence.

Bit 4 CRCERR : CRC error flag

0: CRC value received matches the SPIx_RXCRCR value

1: CRC value received does not match the SPIx_RXCRCR value

Note: This flag is set by hardware and cleared by software writing 0.

Bits 3:2 Reserved, must be kept at reset value.

Bit 1 TXE : Transmit buffer empty

0: Tx buffer not empty

1: Tx buffer empty

Bit 0 RXNE : Receive buffer not empty

0: Rx buffer empty

1: Rx buffer not empty

38.6.4 SPI data register (SPIx_DR)

Address offset: 0x0C

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
DR[15:0]
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bits 15:0 DR[15:0] : Data register

Data received or to be transmitted

The data register serves as an interface between the Rx and Tx FIFOs. When the data register is read, RxFIFO is accessed while the write to data register accesses TxFIFO (See Section 38.4.9: Data transmission and reception procedures ).

Note: Data is always right-aligned. Unused bits are ignored when writing to the register, and read as zero when the register is read. The Rx threshold setting must always correspond with the read access currently used.

38.6.5 SPI CRC polynomial register (SPIx_CRCPR)

Address offset: 0x10

Reset value: 0x0007

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
CRCPOLY[15:0]
rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw	rw

Bits 15:0 CRCPOLY[15:0] : CRC polynomial register

This register contains the polynomial for the CRC calculation.

The CRC polynomial (0x0007) is the reset value of this register. Another polynomial can be configured as required.

Note: The polynomial value should be odd only. No even value is supported.

38.6.6 SPI Rx CRC register (SPIx_RXCRCR)

Address offset: 0x14

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
RXCRC[15:0]
r	r	r	r	r	r	r	r	r	r	r	r	r	r	r	r

Bits 15:0 RXCRC[15:0] : Rx CRC register

When CRC calculation is enabled, the RXCRC[15:0] bits contain the computed CRC value of the subsequently received bytes. This register is reset when the CRCEN bit in SPIx_CR1 register is written to 1. The CRC is calculated serially using the polynomial programmed in the SPIx_CRCPR register.

Only the 8 LSB bits are considered when the CRC frame format is set to be 8-bit length (CRCL bit in the SPIx_CR1 is cleared). CRC calculation is done based on any CRC8 standard.

The entire 16-bits of this register are considered when a 16-bit CRC frame format is selected (CRCL bit in the SPIx_CR1 register is set). CRC calculation is done based on any CRC16 standard.

A read to this register when the BSY Flag is set could return an incorrect value.

38.6.7 SPI Tx CRC register (SPIx_TXCRCR)

Address offset: 0x18

Reset value: 0x0000

15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
TXCRC[15:0]
r	r	r	r	r	r	r	r	r	r	r	r	r	r	r	r

Bits 15:0 TXCRC[15:0] : Tx CRC register

When CRC calculation is enabled, the TXCRC[7:0] bits contain the computed CRC value of the subsequently transmitted bytes. This register is reset when the CRCEN bit of SPIx_CR1 is written to 1. The CRC is calculated serially using the polynomial programmed in the SPIx_CRCPR register.

Only the 8 LSB bits are considered when the CRC frame format is set to be 8-bit length (CRCL bit in the SPIx_CR1 is cleared). CRC calculation is done based on any CRC8 standard.

The entire 16-bits of this register are considered when a 16-bit CRC frame format is selected (CRCL bit in the SPIx_CR1 register is set). CRC calculation is done based on any CRC16 standard.

A read to this register when the BSY flag is set could return an incorrect value.

38.6.8 SPI register map

Table 240 shows the SPI register map and reset values.

Table 240. SPI register map and reset values

Offset	Register name reset value	15	14	13	12	11	10	9	8	7	6	5	4	3	2	1	0
0x00	SPIx_CR1	BIDIMODE	BIDIOE	RCEN	RCNEXT	CRCL	RXONLY	SSM	SSI	LSBFIRST	SPE	BR [2:0]			MSTR	CPOL	CPHA
0x00	Reset value	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x04	SPIx_CR2	Res.	LDMA_TX	LDMA_RX	FRXTH	DS[3:0]			TXEIE	RXNEIE	ERRIE	FRF	NSSP	SSOE	TXDMAEN	RXDMAEN
0x04	Reset value		0	0	0	0	1	1	1	0	0	0	0	0	0	0	0
0x08	SPIx_SR	Res.	Res.	Res.	FTLVL[1:0]		FRLVL[1:0]		FRE	BSY	OVR	MODF	CRCERR			TXE	RXNE
0x08	Reset value				0	0	0	0	0	0	0	0	0			1	0
0x0C	SPIx_DR	DR[15:0]
0x0C	Reset value	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x10	SPIx_CRCPR	CRCPOLY[15:0]
0x10	Reset value	0	0	0	0	0	0	0	0	0	0	0	0	0	1	1	1
0x14	SPIx_RXCRCR	RXCRC[15:0]
0x14	Reset value	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0
0x18	SPIx_TXCRCR	TXCRC[15:0]
0x18	Reset value	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0	0

Refer to Section 2.2 on page 66 for the register boundary addresses.