10. General-purpose I/Os (GPIO)

10.1 Introduction

Each general-purpose I/O port has four 32-bit configuration registers (GPIOx_MODER, GPIOx_OTYPER, GPIOx_OSPEEDR and GPIOx_PUPDR), two 32-bit data registers (GPIOx_IDR and GPIOx_ODR), a 16 bits reset register (GPIOx_BRR) and a 32-bit set/reset register (GPIOx_BSRR).

In addition, all GPIOs have a 32-bit locking register (GPIOx_LCKR), two 32-bit alternate function selection registers (GPIOx_AFRH and GPIOx_AFRL).

10.2 GPIO main features

• • Output states: push-pull or open drain + pull-up/down
• • Output data from output data register (GPIOx_ODR) or peripheral (alternate function output)
• • Speed selection for each I/O
• • Input states: floating, pull-up/down, analog
• • Input data to input data register (GPIOx_IDR) or peripheral (alternate function input)
• • Bit set and reset register (GPIOx_BSRR) for bitwise write access to GPIOx_ODR
• • Lock mechanism (GPIOx_LCKR) provided to freeze the I/O port configurations
• • Analog function
• • Alternate function selection registers
• • Fast toggle capable of changing every two clock cycles
• • Highly flexible pin multiplexing allows the use of I/O pins as GPIOs or as one of several peripheral functions

10.3 GPIO functional description

Subject to the specific hardware characteristics of each I/O port listed in the datasheet, each port bit of the general-purpose I/O (GPIO) ports can be individually configured by software in several modes:

• • Input floating
• • Input pull-up
• • Input pull-down
• • Analog
• • Output open-drain with pull-up or pull-down capability
• • Output push-pull with pull-up or pull-down capability
• • Alternate function push-pull with pull-up or pull-down capability
• • Alternate function open-drain with pull-up or pull-down capability

Each I/O port bit is freely programmable, however the I/O port registers must be accessed as 32-bit words, half-words or bytes. The GPIOx_BSRR and GPIOx_BRR registers allow atomic read/modify accesses to any of the GPIOx_ODR registers. In this way, there is no risk of an IRQ occurring between the read and the modify access.

The figure below shows the basic structure of a three-volt or five-volt tolerant GPIO (TT or FT). The Table 85 gives the possible port bit configurations.

Figure 82. Structure of three-volt or five-volt tolerant GPIO (TT or FT)

Note: On a TT GPIO, the analog switch is not present and replaced by a direct connection. The analog bloc parasitic circuitry does not allow five-volt tolerance.

Table 85. Port bit configuration ⁽¹⁾

1. GP = general-purpose, PP = push-pull, PU = pull-up, PD = pull-down, OD = open-drain, AF = alternate function.

10.3.1 General-purpose I/O (GPIO)

During and just after reset, the alternate functions are not active and most of the I/O ports are configured in analog mode.

The debug pins are in AF pull-up/pull-down after reset:

• • PA15: JTDI in pull-up
• • PA14: JTCK/SWCLK in pull-down
• • PA13: JTMS/SWDIO in pull-up
• • PB4: NJTRST in pull-up
• • PB3: JTDO/TRACE SWO in floating state no pull-up/pull-down

When the pin is configured as output, the value written to the output data register (GPIOx_ODR) is output on the I/O pin. It is possible to use the output driver in push-pull mode or open-drain mode (only the low level is driven, high level is HI-Z).

The input data register (GPIOx_IDR) captures the data present on the I/O pin at every AHB clock cycle.

All GPIO pins have weak internal pull-up and pull-down resistors, that can be activated or not depending on the value in the GPIOx_PUPDR register.

10.3.2 I/O pin alternate function multiplexer and mapping

The device I/O pins are connected to on-board peripherals/modules through a multiplexer that allows only one peripheral alternate function (AF) connected to an I/O pin at a time. In this way, there is no conflict between peripherals available on the same I/O pin.

Each I/O pin has a multiplexer with up to 16 alternate function inputs (AF0 to AF15) that can be configured through the GPIOx_AFRL (for pin 0 to 7) and GPIOx_AFRH (for pin 8 to 15) registers:

• • After reset, the multiplexer selection is alternate function 0 (AF0). The I/Os are configured in alternate function mode through GPIOx_MODER register.
• • The specific alternate function assignments for each pin are detailed in the device datasheet.

In addition to this flexible I/O multiplexing architecture, each peripheral has alternate functions mapped onto different I/O pins to optimize the number of peripherals available in smaller packages. The I/O pins on Port P and port O do not have alternate functions as these are dedicated for xSPI interface.

To use an I/O in a given configuration, the user must proceed as follows:

• • Debug function: after each device reset these pins are assigned as alternate function pins immediately usable by the debugger host.
• • GPIO: configure the desired I/O as output, input or analog in the GPIOx_MODER register.
• • Peripheral alternate function:
  • – Connect the I/O to the desired AFx in one of the GPIOx_AFRL or GPIOx_AFRH register.
  • – Select the type, pull-up/pull-down and output speed via the GPIOx_OTYPER, GPIOx_PUPDR and GPIOx_OSPEEDR registers respectively.
  • – Configure the desired I/O as an alternate function in the GPIOx_MODER register.
• • Additional functions:
  • – For all ADCs, configure the desired I/O in analog mode in the GPIOx_MODER register and configure the required function in the ADC registers.
  • – For the additional functions like RTC, WKUPx and oscillators, configure the required function in the related RTC, PWR and RCC registers. These functions have priority over the configuration in the standard GPIO registers.

Refer to the “Alternate function mapping” table in the device datasheet for the detailed mapping of the alternate function I/O pins.

10.3.3 I/O port control registers

Each of the GPIO ports has four 32-bit memory-mapped control registers (GPIOx_MODER, GPIOx_OTYPER, GPIOx_OSPEEDR, GPIOx_PUPDR) to configure up to 16 I/Os. The GPIOx_MODER register is used to select the I/O mode (input, output, AF, analog). The GPIOx_OTYPER and GPIOx_OSPEEDR registers are used to select the output type (push-pull or open-drain) and speed. The GPIOx_PUPDR register is used to select the pull-up/pull-down whatever the I/O direction.

10.3.4 I/O port data registers

Each GPIO has two 16-bit memory-mapped data registers: input and output data registers ( GPIO port input data register (GPIOx_IDR) (x = A to G, M to P) and GPIO port output data register (GPIOx_ODR) (x = A to G, M to P) ).

GPIOx_ODR stores the data to be output, it is read/write accessible. The data input through the I/O are stored into the input data register (GPIOx_IDR), a read-only register.

10.3.5 I/O data bitwise handling

The bit set reset register (GPIOx_BSRR) is a 32-bit register that allows the application to set and reset each individual bit in the output data register (GPIOx_ODR). The bit set reset register has twice the size of GPIOx_ODR.

To each bit in GPIOx_ODR, correspond two control bits in GPIOx_BSRR: BS(i) and BR(i). When written to 1, BS(i) sets the corresponding ODR(i) bit. When written to 1, BR(i) resets the ODR(i) corresponding bit.

Writing any bit to 0 in GPIOx_BSRR does not have any effect on the corresponding bit in GPIOx_ODR. If there is an attempt to both set and reset a bit in GPIOx_BSRR, the set action takes priority.

Using the GPIOx_BSRR register to change the values of individual bits in GPIOx_ODR is a “one-shot” effect that does not lock the GPIOx_ODR bits. The GPIOx_ODR bits can always be accessed directly. The GPIOx_BSRR register provides a way of performing atomic bitwise handling.

There is no need for the software to disable interrupts when programming the GPIOx_ODR at bit level: one or more bits can be modified in a single atomic AHB write access.

10.3.6 GPIO locking mechanism

The GPIO control registers can be frozen by applying a specific write sequence to the GPIOx_LCKR register. The frozen registers are GPIOx_MODER, GPIOx_OTYPER, GPIOx_OSPEEDR, GPIOx_PUPDR, GPIOx_AFRL, GPIOx_AFRH.

To write the GPIOx_LCKR register, a specific write/read sequence must be applied. When the right LOCK sequence is applied to the bit 16 in this register, the value of LCKR[15:0] is used to lock the configuration of the I/Os (during the write sequence the LCKR[15:0] value must be the same). When the LOCK sequence is applied to a port bit, the value of the port bit can no longer be modified until the next MCU reset or peripheral reset. Each GPIOx_LCKR bit freezes the corresponding bit in the control registers (GPIOx_MODER, GPIOx_OTYPER, GPIOx_OSPEEDR, GPIOx_PUPDR, GPIOx_AFRL and GPIOx_AFRH).

The LOCK sequence can only be performed using a word (32-bit long) access to the GPIOx_LCKR register due to the fact that GPIOx_LCKR bit 16 must be set at the same time as the [15:0] bits.

10.3.7 I/O alternate function input/output

Two registers are provided to select one of the alternate function inputs/outputs available for each I/O. With these registers, the user can connect an alternate function to some other pin as required by the application.

This means that a number of possible peripheral functions are multiplexed on each GPIO using the GPIOx_AFRL and GPIOx_AFRH alternate function registers. The application can

thus select any one of the possible functions for each I/O. The AF selection signal being common to the alternate function input and alternate function output, a single channel is selected for the alternate function input/output of a given I/O.

To know which functions are multiplexed on each GPIO pin, refer to the device datasheet.

10.3.8 External interrupt/wake-up lines

All ports have external interrupt capability. To use external interrupt lines, the port can be configured in input, output or alternate function mode (the port must not be configured in analog mode). Refer to Section 20: Extended interrupt and event controller (EXTI) .

10.3.9 Input configuration

When the I/O port is programmed as input:

• • The output buffer is disabled.
• • The Schmitt trigger input is activated.
• • The pull-up and pull-down resistors are activated depending on the value in the GPIOx_PUPDR register.
• • The data present on the I/O pin are sampled into the input data register every AHB clock cycle.
• • A read access to the input data register provides the I/O state.

The figure below shows the input configuration of the I/O port bit.

Figure 83. Input floating/pull-up/pull-down configurations

10.3.10 Output configuration

When the I/O port is programmed as output:

• • The output buffer is enabled:
  • – Open-drain mode: a 0 in the output register activates the N-MOS whereas a 1 in the output register leaves the port in Hi-Z (the P-MOS is never activated).
  • – Push-pull mode: a 0 in the output register activates the N-MOS whereas a 1 in the output register activates the P-MOS.
• • The Schmitt trigger input is activated.
• • The pull-up and pull-down resistors are activated depending on the value in the GPIOx_PUPDR register.
• • The data present on the I/O pin are sampled into the input data register every AHB clock cycle.
• • A read access to the input data register gets the I/O state.
• • A read access to the output data register gets the last written value.

The figure below shows the output configuration of the I/O port bit.

Figure 84. Output configuration

10.3.11 Alternate function configuration

When the I/O port is programmed as alternate function:

• • The output buffer can be configured in open-drain or push-pull mode.
• • The output buffer is driven by the signals coming from the peripheral (transmitter enable and data).
• • The Schmitt trigger input is activated.
• • The weak pull-up and pull-down resistors are activated or not depending on the value in the GPIOx_PUPDR register.
• • The data present on the I/O pin are sampled into the input data register every AHB clock cycle.
• • A read access to the input data register gets the I/O state.

The figure below shows the alternate function configuration of the I/O port bit.

Figure 85. Alternate function configuration

10.3.12 Analog configuration

When the I/O port is programmed as analog configuration:

• • The output buffer is disabled.
• • The Schmitt trigger input is deactivated, providing zero consumption for every analog value of the I/O pin. The output of the Schmitt trigger is forced to a constant value (0).
• • The weak pull-up and pull-down resistors are disabled by hardware.
• • Read access to the input data register gets the value 0.

The figure below shows the high-impedance, analog-input configuration of the I/O port bits.

Figure 86. High-impedance analog configuration

10.3.13 Using the HSE or LSE oscillator pins as GPIOs

When the HSE or LSE oscillator is switched off (default state after reset), the related oscillator pins can be used as normal GPIOs.

When the HSE or LSE oscillator is switched on (by setting the HSEON or LSEON bit in the RCC_CSR register), the oscillator takes control of its associated pins and the GPIO configuration of these pins has no effect.

When the oscillator is configured in a user external clock mode, only the pin is reserved for clock input, and the OSC_OUT or OSC32_OUT pin can still be used as normal GPIO.

10.3.14 Using the GPIO pins in the RTC supply domain

The PC13/PC14/PC15 GPIO functionality is lost when the core supply domain is powered off (when the device enters Standby mode). In this case, if their GPIO configuration is not bypassed by the RTC configuration, these pins are set in an analog input mode.

For details about I/O control by the RTC, refer to Section 49.3: RTC functional description

10.3.15 Privileged and unprivileged modes

All GPIO registers can be read and written by privileged and unprivileged accesses, whatever the security state (secure or non-secure).

10.3.16 High-speed low-voltage mode (HSLV)

The I/Os can increase their maximum speed at low voltage by configuring them in HSLV mode. The I/O HSLV bit controls whether the I/O output speed is optimized to operate at 3.3 V (default setting) or at 1.8 V (HSLV = 1). The CSI must be enabled in order to configure the I/Os in HSLV mode.

Procedure to set the HSLV mode for the XSPIx interface:

1. 1. Set the user option byte for the targeted interface (XSPI1_HSLV, XSPI2_HSLV) in the FLASH option byte word 1 status register (FLASH_OBW1SR) .
2. 2. Enable the target interface EN_XSPIM1, EN_XSPIM2 in the PWR control register 2 (PWR_CSR2) .
3. 3. Activate the HSLV on the targeted i/f (XSPI1_IOHSLV, XSPI2_IOHSLV) in the SBS I/O compensation cell control and status register (SBS_CCCSR) .

Procedure to set the HSLV mode for all IOs including the FMC interface:

1. 1. Set the user option byte for the GPIO and the shared XSPI interface (VDDIO_HSLV, XSPI2_HSLV) in the FLASH option byte word 1 status register (FLASH_OBW1SR)
2. 2. For the XSPIx port refer to the previous procedure.
3. 3. Activate the HSLV on the targeted i/f (IOHSLV) in the SBS I/O compensation cell control and status register (SBS_CCCSR) .

Caution: The I/O HSLV configuration bit must not be set if the I/O supply ( \( V_{DD} \) ) is above 2.7 V. Setting it while the voltage is higher than 2.7 V can damage the device.

There is no hardware protection associated to this feature so it is recommended to use it only as a static configuration for fixed I/O supply.

Caution: The GPIOs are all programed with the same HSLV setting, except those from dedicated power rail (OCTO, HEXA and USB):

• • XSPIM2 rail: PN[0:12]
• • XSPIM1 rail: PO[0:5], PP[0:15]
• • USB no software compensation setting

GPIOs that are shared with the USB are limited in terms of frequency, to hundreds of kHz for UCPD-based GPIOs, and up to 1 MHz for USBHS and USBFS-based GPIOs. Refer to the datsheet for the exact values. In order to be used the IO supply must be above 2.7 V for the USBHS/FS.

Note: When using an FMC with HSLV both the XSPIM2 and GPIO must be set to HSLV and on the same supply, still respecting the HSLV I/O supply limitation.

10.3.17 I/O compensation cell

The I/O commutation slew rate (tfall / trise) can be adapted by software depending on process, voltage and temperature conditions, in order to reduce the I/O noise on the power supply.

10.4 GPIO registers

This section gives a detailed description of the GPIO registers.

The peripheral registers can be written in word, half word or byte mode.

10.4.1 GPIO port mode register (GPIOx_MODER) (x=A to H, M to P)

Address offset: 0x00

Reset value: 0xABFF FFFF (port A)

Reset value: 0xFFFF FEBF (port B)

Reset value: 0xFFFF FFFF (ports C...H and M...P)

Bits 31:0 MODEy[1:0] : Port x configuration I/O pin y (y = 15 to 0)

These bits are written by software to configure the I/O mode.

00: Input mode

01: General purpose output mode

10: Alternate function mode

11: Analog mode (reset state)

Note: The bitfield is reserved and must be kept to reset value when the corresponding I/O is not available on the selected package.

10.4.2 GPIO port output type register (GPIOx_OTYPER) (x = A to G, M to P)

Address offset: 0x04

Reset value: 0x0000 0000

Bits 31:16 Reserved, must be kept at reset value.

Bits 15:0 OTy : Port x configuration I/O pin y (y = 15 to 0)

These bits are written by software to configure the I/O output type.

0: Output push-pull (reset state)

1: Output open-drain

Note: The bit is reserved and must be kept to reset value when the corresponding I/O is not available on the selected package.

10.4.3 GPIO port output speed register (GPIOx_OSPEEDR) (x = A to G, M to P)

Address offset: 0x08

Reset value: 0x0C00 0000 (for port A)

Reset value: 0x0000 00C0 (for port B)

Reset value: 0x0000 0000 (for the other ports)

Bits 31:0 OSPEEDy[1:0] : Port x configuration I/O pin y (y = 15 to 0)

These bits are written by software to configure the I/O output speed.

00: Low speed

01: Medium speed

10: High speed

11: Very-high speed

Note: Refer to the device datasheet for the frequency specifications and the power supply and load conditions for each speed.

The bitfield is reserved and must be kept to reset value when the corresponding I/O is not available on the selected package.

10.4.4 GPIO port pull-up/pull-down register (GPIOx_PUPDR) (x = A to G, M to P)

Address offset: 0x0C

Reset value: 0x6400 0000 (for port A)

Reset value: 0x0000 0100 (for port B)

Reset value: 0x0000 0000 (for the other ports)

Bits 31:0 PUPDy[1:0] : Port x configuration I/O pin y (y = 15 to 0)

These bits are written by software to configure the I/O pull-up or pull-down

00: No pull-up, pull-down

01: Pull-up

10: Pull-down

11: Reserved

Note: The bitfield is reserved and must be kept to reset value when the corresponding I/O is not available on the selected package.

10.4.5 GPIO port input data register (GPIOx_IDR) (x = A to G, M to P)

Address offset: 0x10

Reset value: 0x0000 XXXX

Bits 31:16 Reserved, must be kept at reset value.

Bits 15:0 IDy : Port x input data I/O pin y (y = 15 to 0)

These bits are read-only. They contain the input value of the corresponding I/O port.

Note: The bit is reserved and must be kept to reset value when the corresponding I/O is not available on the selected package.

10.4.6 GPIO port output data register (GPIOx_ODR) (x = A to G, M to P)

Address offset: 0x14

Reset value: 0x0000 0000

Bits 31:16 Reserved, must be kept at reset value.

Bits 15:0 ODy : Port output data I/O pin y (y = 15 to 0)

These bits can be read and written by software.

Note: For atomic bit set/reset, the OD bits can be individually set and/or reset by writing to the GPIOx_BSR or GPIOx_BRR registers (x = A to G) (x = M to P).

The bit is reserved and must be kept to reset value when the corresponding I/O is not available on the selected package.

10.4.7 GPIO port bit set/reset register (GPIOx_BSR) (x = A to G, M to P)

Address offset: 0x18

Reset value: 0x0000 0000

Bits 31:16 BRy : Port x reset I/O pin y (y = 15 to 0)

These bits are write-only. A read to these bits returns the value 0x0000.

0: No action on the corresponding ODy bit

1: Resets the corresponding ODy bit

Note: If both BSy and BRy are set, BSy has priority.

The bit is reserved and must be kept to reset value when the corresponding I/O is not available on the selected package.

Bits 15:0 BSy : Port x set I/O pin y (y = 15 to 0)

These bits are write-only. A read to these bits returns the value 0x0000.

0: No action on the corresponding ODy bit

1: Sets the corresponding ODy bit

Note: The bit is reserved and must be kept to reset value when the corresponding I/O is not available on the selected package.

10.4.8 GPIO port configuration lock register (GPIOx_LCKR) (x = A to G, M to P)

This register is used to lock the configuration of the port bits when a correct write sequence is applied to bit 16 (LCKK). The value of bits [15:0] is used to lock the configuration of the GPIO. During the write sequence, the value of LCKR[15:0] must not change. When the LOCK sequence has been applied on a port bit, the value of this port bit can no longer be modified until the next MCU reset or peripheral reset.

Note: A specific write sequence is used to write to the GPIOx_LCKR register. Only word access (32-bit long) is allowed during this locking sequence.

Each lock bit freezes a specific configuration register (control and alternate function registers).

Address offset: 0x1C

Reset value: 0x0000 0000

Bits 31:17 Reserved, must be kept at reset value.

Bit 16 LCKK : Lock key

This bit can be read any time. It can only be modified using the lock key write sequence.

0: Port configuration lock key not active

1: Port configuration lock key active. The GPIOx_LCKR register is locked until the next MCU reset or peripheral reset.

- LOCK key write sequence:

WR LCKR[16] = 1 + LCKR[15:0]

WR LCKR[16] = 0 + LCKR[15:0]

WR LCKR[16] = 1 + LCKR[15:0]

- LOCK key read

RD LCKR[16] = 1 (this read operation is optional but it confirms that the lock is active)

Note: During the LOCK key write sequence, the value of LCK[15:0] must not change.

Any error in the lock sequence aborts the LOCK.

After the first LOCK sequence on any bit of the port, any read access on the LCKK bit returns 1 until the next MCU reset or peripheral reset.

Bits 15:0 LCKy : Port x lock I/O pin y (y = 15 to 0)

These bits are read/write but can only be written when the LCKK bit is 0

0: Port configuration not locked

1: Port configuration locked

Note: The bit is reserved and must be kept to reset value when the corresponding I/O is not available on the selected package.

10.4.9 GPIO alternate function low register (GPIOx_AFRL) (x = A to G, M to P)

Address offset: 0x20

Reset value: 0x0000 0000

Bits 31:0 AFSELy[3:0] : Alternate function selection for port x I/O pin y (y = 7 to 0)

These bits are written by software to configure alternate function I/Os.

0000: AF0
0001: AF1
0010: AF2
0011: AF3
0100: AF4
0101: AF5
0110: AF6
0111: AF7
1000: AF8
1001: AF9
1010: AF10
1011: AF11
1100: AF12
1101: AF13
1110: AF14
1111: AF15

Note: The bitfield is reserved and must be kept to reset value when the corresponding I/O is not available on the selected package.

10.4.10 GPIO alternate function high register (GPIOx_AFRH) (x = A to G, M to P)

Address offset: 0x24

Reset value: 0x0000 0000

Bits 31:0 AFSELy[3:0] : Alternate function selection for port x I/O pin y (y = 15 to 8)

These bits are written by software to configure alternate function I/Os.

0000: AF0
0001: AF1
0010: AF2
0011: AF3
0100: AF4
0101: AF5
0110: AF6
0111: AF7
1000: AF8
1001: AF9
1010: AF10
1011: AF11
1100: AF12
1101: AF13
1110: AF14
1111: AF15

Note: The bitfield is reserved and must be kept to reset value when the corresponding I/O is not available on the selected package.

10.4.11 GPIO port bit reset register (GPIOx_BRR) (x = A to G, M to P)

Address offset: 0x28

Reset value: 0x0000 0000

Bits 31:16 Reserved, must be kept at reset value.

Bits 15:0 BRy : Port x reset IO pin y (y = 15 to 0)

These bits are write-only. A read to these bits returns the value 0x0000.

0: No action on the corresponding ODy bit

1: Reset the corresponding ODy bit

Note: The bit is reserved and must be kept to reset value when the corresponding I/O is not available on the selected package.

10.4.12 GPIO register map

Table 86. GPIO register map and reset values

Table 86. GPIO register map and reset values (continued)

Refer to Section 2.3 for the register boundary addresses.