STM32MP15 ROM code overview

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1 ROM Code overview[edit source]

ROM code is the first code executed after a reset.

1.1 ROM code features[edit source]

The main features of ROM code include:

Secure Boot from serial link (Serial boot)
Secure Boot from various Flash memories (Flash memory boot)
Engineering boot
RMA boot
Wake up from low power modes
Exported secure services

ROM code overview

1.2 Device states[edit source]

The ROM code behaviour is strongly linked to the device state.

Device states

Open state: By default the device is in open state. Authentication is not mandatory. An authentication error does not prevent FSBL from beeing started.
Closed state: The device can be closed by writing to bit 6 of OTP WORD0. On closed devices, authentication is mandatory. An authentication error prevents FSBL from beeing started.
RMA state: A closed device can be put once in RMA state and back again in closed state. On devices in RMA state, all ROM code features, except the one used to go back in closed state are disabled.

2 Secure boot[edit source]

The ROM code ensures the first stage of the STM32MP15 secure boot, implemented in the trusted boot chain:

it loads FSBL image from selected boot interface
it authenticates FSBL image
if image is authenticated, it jumps to FSBL image entry point

ROM code - secure boot

2.1 Boot interface selection[edit source]

As shown in the figure below, the boot interface is determined by the configuration given by boot pins, OTP and a TAMP register.

ROM code - boot source selection

2.2 Image loading[edit source]

The ROM code loads the image into SYSRAM internal memory at address 0x2ffc2400.

2.3 FSBL authentication[edit source]

ROM code implements authentication process as described in STM32MP15 secure boot, Authentication processing chapter.

2.4 Jump to FSBL[edit source]

If image authentication is successful, the ROM code stores the address of the boot context in r0 register and jumps to the FSBL entry point defined in image header.

The boot context (see boot_api_context_t structure in plat/st/stm32mp1/include/boot_api.h ) is in the first 512 bytes of SYSRAM. It contains information on boot process (such as the selected boot device) and pointers to the ROM code services (used for secure boot authentication).

3 Serial boot[edit source]

The ROM supports UART and USB serial interfaces.

When serial boot is selected, the ROM code scans in parallel all bootable UART instances and the USB OTG. When an activity is detected on an interface, the boot process goes on with this interface and the others are ignored.

3.1 USB Boot[edit source]

The ROM supports boot on USB OTG interface with HS PHY.

USB OTG HS is clocked by a 48 MHz and a 60 MHz clock, generated by using HSE clock (from RCC).

The ROM code supports following HSE values:

8, 10, 12, 14, 16, 20, 24, 25, 26, 28, 32, 36, 40, 48 MHz

The ROM code selects which HSE it must use by following these steps:

If OTP WORD 3.HSE_value is 0b00 (default behaviour), then the ROM code autodetects HSE by using HSI clock (from RCC).

Recognized values are either 8, 10, 12, 14, 16, 20, 24, 32, 36, 28, 40, or 48 MHz.

If none of these value can be recognized, the ROM code considers that HSE = 24 MHz.

If OTP WORD 3.HSE_value is 0b01, then it considers that HSE=24 MHz
If OTP WORD 3.HSE_value is 0b10, then it considers that HSE=25 MHz
If OTP WORD 3.HSE_value is 0b11, then it considers that HSE=26 MHz

3.2 UART Boot[edit source]

The ROM supports the following UART interfaces:

USART/UART instances:
- USART2, USART3, UART4, UART5, USART6, UART7, UART8

(one start bit, 8 data bits, even parity bit and one stop bit).

Configuration:

By default the ROM code scans all UARTs listed above. This list may be reduced by blowing fuses in uart_intances_disable field of OTP WORD 3.

In case of Serial boot, the ROM code applies the following AFmuxes.
The ROM code first muxes only the RX pins of bootable UART instances and scans in parallel all these RX lines. When an activity is detected on an UART interface, the ROM code muxes the related TX, all others RX are unmuxed, and the boot process goes on with this interface. In case of USB boot detection, all UART RX are unmuxed.

UARTs

USART2
IO name	Pin id (AF mux)
USART2_RX	PA3 (AF07)
USART2_TX	PA2 (AF07)

USART3
IO name	Pin id (AF mux)
USART3_RX	PB12 (AF08)
USART3_TX	PB10 (AF07)

UART4
IO name	Pin id (AF mux)
UART4_RX	PB2 (AF08)
UART4_TX	PG11 (AF06)

USART5
IO name	Pin id (AF mux)
USART5_RX	PB5 (AF12)
USART5_TX	PB13 (AF14)

USART6
IO name	Pin id (AF mux)
USART6_RX	PC7 (AF07)
USART6_TX	PC6 (AF07)

UART7
IO name	Pin id (AF mux)
UART7_RX	PF6 (AF07)
UART7_TX	PF7 (AF07)

UART8
IO name	Pin id (AF mux)
UART8_RX	PE0 (AF08)
UART8_TX	PE1 (AF08)

4 Flash memory boot[edit source]

The ROM supports the following Flash interfaces:

QSPI NOR Flash via QUADSPI internal peripheral
QSPI NAND Flash via QUADSPI internal peripheral
FMC NAND Flash via FMC internal peripheral
SD card via SDMMC internal peripheral
e•MMC™ via SDMMC internal peripheral

Please refer to STM32MP15 Flash mapping article to see the details about the mapping of each of these memories.

4.1 Boot from NAND[edit source]

NAND contains n copies of FSBL in n first blocks. The ROM code scans blocks from the first and loads the FSBL contained in the first valid block.

The ROM code supports FMC (parallel) NANDs and QSPI (serial) NANDs.

Supported FMC (parallel) NANDs:

The ROM code supports FMC NAND with the following parameters.

Block size (KBytes )	Page size (KBytes)	Data width	ECC¹(bits and code)
128	2	8, 16	4 (bch), 8 (bch), 1 (hamming)
256	4	8, 16	4 (bch), 8 (bch), 1 (hamming)
512	4	8, 16	4 (bch), 8 (bch), 1 (hamming)
512	8	8, 16	4 (bch), 8 (bch), 1 (hamming)

¹: The ROM code supports both FMC NAND with or without on-die ECC. The ECC given here is for NAND without on-die ECC.

Supported QSPI (serial) NANDs:

The ROM code supports QSPI NAND with the following parameters.

Block size (KBytes)	Page size (KBytes)
128	2
256	4
512	4
512	8

Configuration:

In order to read a NAND flash, the ROM code needs to know the page size, the block size and the number of blocks. For FMC NAND it also needs to know the width and the number of ECC bits.

The ROM code detects NAND parameters storage location by checking OTP WORD9.nand_param_stored_in_otp value.

If OTP WORD9.nand_param_stored_in_otp value is equal to 0 (which is the default) then the NAND shall provide an ONFI compliant parameter table in which the ROM code looks for NAND parameters. “ONFI compliant” means that a NAND provides an ONFI get parameter command that returns a table where at least parameters needed by ROM code are located at standard ONFI offsets.

If OTP WORD9.nand_param_stored_in_otp value is equal to 1, the ROM code looks for NAND parameters in OTP WORD9.

The number of ECC bits is a particular case, as it can be set by OTP even if OTP WORD9.nand_param_stored_in_otp is equal to 0. This is to allow the user to override the recommanded number of ECC bits given by the parameter table of an ONFI NAND.

In case of QSPI NAND boot, the ROM code applies the same AFmuxes as the ones for QSPI NOR.

In case of FMC NAND boot, the ROM code applies the following AFmuxes:

FMC NAND

8 bits
IO name	Pin id (AF mux)
FMC_NOE	PD4 (AF12)
FMC_NWAIT	PD6 (AF12)
FMC_NWE	PD5 (AF12)
FMC_NCE	PG9 (AF12)
FMC_ALE	PD12 (AF12)
FMC_CLE	PD11 (AF12)
FMC_D0	PD14 (AF12)
FMC_D1	PD15 (AF12)
FMC_D2	PD0 (AF12)
FMC_D3	PD1 (AF12)
FMC_D4	PE7 (AF12)
FMC_D5	PE8 (AF12)
FMC_D6	PE9 (AF12)
FMC_D7	PE10 (AF12)

16 bits complement
IO name	Pin id (AF mux)
FMC_D8	PE11 (AF12)
FMC_D9	PE12 (AF12)
FMC_D10	PE13 (AF12)
FMC_D11	PE14 (AF12)
FMC_D12	PE15 (AF12)
FMC_D13	PD8 (AF12)
FMC_D14	Pd9 (AF12)
FMC_D15	PD10 (AF12)

4.2 Boot from NOR[edit source]

The NOR Flash contains two copies of FSBL. The ROM code tries to load and launch the first copy. In case of failure, it then tries to load the second copy.

The ROM code looks for FSBL1 at offset LBA0 and FSBL2 at offset LBA512.

It is possible to use NOR flash either in single or in dual mode. In dual mode two NOR flashes are connected to the two ports of the NOR interface, and the two memories are used in interlaced mode.

Configuration:

The ROM code uses SPI legacy mode MOSI/MISO only (i.e. uses only 2 pins IO0 and IO1 to transfer data).

The ROM code automatically detects single and dual modes.

In dual mode, BK1_NCS shall be connected to BK2_NCS on board.

By default the ROM code applies the following AFmuxes:

QSPI NOR

QSPI NOR (single NOR)
IO name	Pin id (AF mux)
QUADSPI_CLK	PF10 (AF9)
QUADSPI_BK1_NCS	PB6 (AF10)
QUADSPI_BK1_IO0	PF8 (AF10)
QUADSPI_BK1_IO1	PF9 (AF10)

QSPI NOR (dual NOR)
IO name	Pin id (AF mux)
QUADSPI_CLK	PF10 (AF9)
QUADSPI_BK1_NCS	PB6 (AF10)
QUADSPI_BK1_IO0	PF8 (AF10)
QUADSPI_BK1_IO1	PF9 (AF10)
QUADSPI_BK2_IO0	PH2 (AF9)
QUADSPI_BK2_IO1	PH3 (AF9)

These default AFmux can be overwritten by OTP values defined by OTP WORD 5 to 7.

4.3 Boot from SD[edit source]

SD cards contain two versions of FSBL. The ROM code tries to load and launch the first copy. In case of failure, it then try to load the second copy.

The ROM code first looks for a GPT. If it finds it, it locates two FSBLs by looking for the two first GPT entries which name begins with "fsbl". If it cannot find a GPT, the ROM code looks for FSBL1 at offset LBA34 and FSBL2 at offset LBA546.

Configuration:

The ROM code uses only one data bit.

By default the ROM code uses SDMMC1 instance.

If OTP WORD 3 sd_if_id field value is not equal to 0, the ROM code uses the value of this field (1 or 2) to determine which SDMMC interface to use.

By default the ROM code applies the following AFmuxes:

IO name	Pin id (AF mux)
SDMMC1_CK	PC12 (AF12)
SDMMC1_CMD	PD2 (AF12)
SDMMC1_D0	PC8 (AF12)
SDMMC1_CDIR	PB9 (AF11)
SDMMC1_D0DIR	AFMUX OTP needed

If OTP WORD 3 sd_if_id field value is not equal to 0, the ROM code uses non default AFmux values defined by OTP WORD 5 to 7.

Note that AFmux for SDMMC1_D0DIR has no default value and, if needed, must be applied via OTP WORD 5 to 7.

4.4 Boot from e•MMC™[edit source]

An e•MMC™ contains two copies of FSBL in its two boot regions, but only one boot region is active at a time. The ROM code tries to load and launch the copy of FSBL contained in the active boot region.

Configuration:

The ROM code uses only one data bit.

By default the ROM code uses SDMMC2 instance.

If OTP WORD 3 emmc_if_id field value is not equal to 0, the ROM code uses the value of this field (1 or 2) to determine which SDMMC interface to use.

By default the ROM code applies following AFmuxes:

IO name	Pin id (AF mux)
SDMMC2_CK	PE3 (AF09)
SDMMC2_CMD	PG6 (AF10)
SDMMC2_D0	PB14 (AF09)

If OTP WORD 3 emmc_if_id field value is not equal to 0, the ROM code uses non default AFmux values defined by OTP WORD 5 to 7.

5 Engineering boot[edit source]

Engineering boot allows the user to connect a debugger on a opened device, so that it can load and run any software on either the CA7 or the CM4.

The ROM code detects engineering boot when boot pins value is 0b100. The ROM code then simply enters an infinite loop after having:

re-opened CA7 secure debug,
started CM4 to run an infinite loop

Engineering boot is not available on closed devices (cf Close the device)

6 Wake up from low power modes[edit source]

In case of Standby exit reset, the ROM code proceeds with a "wake up from low power modes" as shown on following figure:

ROM code - wake up from low power modes

In such resets the Cortex^®-M4 is always hold on reset, and only the ROM code on Cortex^®-A7 is running. The behavior of the ROM code depends on value of bits MCU_BEN, MPU_BEN of RCC_MP_BOOTCR register.

Cortex^®-M4 wake up

If bit MCU_BEN of RCC_MP_BOOTCR register is set to 1, the ROM proceeds to Cortex^®-M4 software wake up.

The ROM code wakes up Cortex^®-M4 by releasing it from its "hold on reset" state.

Cortex^®-M4 software integrity check

Before releasing Cortex^®-M4 the ROM code can use backup registers to recover the Cortex^®-M4 software integrity check value and compare it to the one computed on RETRAM.

Note: if the device is closed, this check is mandatory.

Cortex^®-A7 wake up

The Cortex^®-A7 software wake up consists in processing Secure boot. The ROM will proceed to Cortex^®-A7 software wake up in three cases:

If M4 software wake up is not required (i.e. MCU_BEN=0)
If M4 software wake up is required (i.e. MCU_BEN=0) but fails,
If M4 software wake up is required (i.e. MCU_BEN=0), is processed successfully and MPU_BEN is also set to 1

Cortex^®-A7 returns to CStandby low power mode

If Cortex^®-M4 software wake up is required (i.e. MCU_BEN=0), is processed successfully and MPU_BEN is set to 0, the ROM enters the Cortex^®-A7 in CStandby low power modes.

7 RMA boot[edit source]

RMA boot allow a user to perform a Return Material Authorization (RMA).

RMA Unlock

The user can request to put a closed device in RMA state by configuring via Jtag the RMA unlock password in BSEC JTAG_IN register, which the ROM code compares to the password stored in OTP WORD 56

RMA boot

When the device is in unlocked for RMA : DFT tests are possible again, but without possibility to access any sensitive data stored in fuses by the user.

RMA Relock

The user can request to put a RMA device back in closed state by configuring via Jtag the RMA relock password in BSEC JTAG_IN register, which the ROM code compares to the password stored in OTP WORD 56

8 Configuration[edit source]

8.1 Boot device selection via the boot pins and OTP[edit source]

BOOT pins	TAMP_REG[20] (Force Serial)	OTP WORD 3 Primary boot source	OTP WORD 3 Secondary boot source	Boot source #1	Boot source #2 if #1 fails	Boot source if #2 fails
b000	x (don't care)	x (don't care)	x (don't care)	Serial	-	-
b001	!= 0xFF	0 (virgin)	0 (virgin)	QSPI NOR	Serial	-
b010	!= 0xFF	0 (virgin)	0 (virgin)	e•MMC™	Serial	-
b011	!= 0xFF	0 (virgin)	0 (virgin)	FMC NAND	Serial	-
b100	x (don't care)	x (don't care)	x (don't care)	NoBoot	-	-
b101	!= 0xFF	0 (virgin)	0 (virgin)	SD-Card	Serial	-
b110	!= 0xFF	0 (virgin)	0 (virgin)	Serial	-	-
b111	!= 0xFF	0 (virgin)	0 (virgin)	QSPI NAND	Serial	-
!= b100	!= 0xFF	Primary¹	0 (virgin)	Primary¹	Serial	-
!= b100	!= 0xFF	0 (virgin)	Secondary¹	Secondary¹	Serial	-
!= b100	!= 0xFF	Primary¹	Secondary¹	Primary¹	Secondary¹	Serial
!= b100	0xFF	x (don't care)	x (don't care)	Serial	-	-

¹Primary and Secondary are fields of OTP WORD3.

8.2 OTP configuration[edit source]

The OTP are stored via BSEC internal peripheral.

8.2.1 OTP WORD 0[edit source]

Bit	Name	Size	Value	Description
31-7		25 bits		reserved
6	is_closed	1 bit		Close state
			0	device is in open state, authentication is optional.
			1	device is in close state, authentication is mandatory.
5-0		6 bits		reserved

8.2.2 OTP WORD 3[edit source]

Bit	Name	Size	Value	Description
31-30	HSE_value	2 bits		HSE value
			0b00	HSE is autodetected
			0b01	HSE is 24 MHz
			0b10	HSE is 25 MHz
			0b11	HSE is 26 MHz
29-27	primary_boot_source	3 bits		Primary boot source
				If different from zero, identifies primary source used for boot
			0	No primary boot source is defined
			1	FMC NAND
			2	QSPI NOR
			3	e•MMC™
			4	SD
			5	QSPI NAND
26-24	secondary_boot_source	3 bits		Secondary boot source
				If different from zero, identifies secondary source used for boot
			0	No secondary boot source is defined
			1	FMC NAND
			2	QSPI NOR
			3	e•MMC™
			4	SD
			5	QSPI NAND
23-16	boot_source_disable	8 bits		Disable boot source
				if different from zero each bit disables a boot source
			0b00000001	disable FMC NAND boot source
			0b00000010	disable QSPI NOR boot source
			0b00000100	disable e•MMC™ boot source
			0b00001000	disable SD boot source
			0b00010000	disable UART boot source
			0b00100000	disable USB boot source
			0b01000000	disable QSPI NAND boot source
15-15	no_data_cache	1 bit		Data cache enable enabling
				If different from zero, data cache is not used by bootrom.
			0	Data cache is used by bootrom.
			1	Data cache is not used by bootrom.
14-7	uart_intances_disabled	8 bits		Uart instances disabled
				If different from zero each bit disables an UART instance.
				If all disable bits are set to 1 then all UARTs are enabled.
			0b00000001	reserved
			0b00000010	disable USART2
			0b00000100	disable USART3
			0b00001000	disable UART4
			0b00010000	disable UART5
			0b00100000	disable UART6
			0b01000000	disable UART7
			0b10000000	disable USART8
6	no_usb_dp_pullup	1 bit		USB DP pullup enabling
				If different from zero, USB DP pull-up is not set
			0	USB DP pull-up is set
			1	USB DP pull-up is not set
5	no_cpu_pll	1 bit		PLL enabling
				If different from zero, PLL are not enabled
			0	PLLs for CPU/AXI are enable for cold boot
			1	PLLs for CPU/AXI are not enable for cold boot
4-3	sd_if_id	2 bits		SD Memory interface
				If different from zero, identifies the default instance to be used for memory boot
			0	Source is default one : SDMMC1 with default AFMux
			1	SDMMC1 (uses non default AFmux defined in OTP)
			2	SDMMC2
2-1	emmc_if_id	2 bits		e•MMC™ Memory interface
				If different from zero, identifies the default instance to be used for memory boot
			0	Source is default one : SDMMC2 with default AFMux
			1	SDMMC1
			2	SDMMC2 (uses non default AFmux defined in OTP)
0	qspi_not_default_af	1 bit		QSPI don’t use default AFmux
			0	QSPI uses default hard coded AFmux
			1	QSPI uses AFmux defined in OTP

8.2.3 OTP WORD 4 - Monotonic counter[edit source]

This is an anti rollback monotonic counter. On closed devices, the ROM code checks that it must be less or equal to the one stored in the image header.

Bit	Name	Size	Value	Description
31-0	monotonic_val	32 bits		Monotonic counter value
				Gives the value of monotonic counter
			0b1xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 32
			0b01xxxxxxxxxxxxxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 31
			0b001xxxxxxxxxxxxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 30
			0b0001xxxxxxxxxxxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 29
			0b00001xxxxxxxxxxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 28
			0b000001xxxxxxxxxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 27
			0b0000001xxxxxxxxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 26
			0b00000001xxxxxxxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 25
			0b000000001xxxxxxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 24
			0b0000000001xxxxxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 23
			0b00000000001xxxxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 22
			0b000000000001xxxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 21
			0b0000000000001xxxxxxxxxxxxxxxxxxx	Value of monotonic counter is 20
			0b00000000000001xxxxxxxxxxxxxxxxxx	Value of monotonic counter is 19
			0b000000000000001xxxxxxxxxxxxxxxxx	Value of monotonic counter is 18
			0b0000000000000001xxxxxxxxxxxxxxxx	Value of monotonic counter is 17
			0b00000000000000001xxxxxxxxxxxxxxx	Value of monotonic counter is 16
			0b000000000000000001xxxxxxxxxxxxxx	Value of monotonic counter is 15
			0b0000000000000000001xxxxxxxxxxxxx	Value of monotonic counter is 14
			0b00000000000000000001xxxxxxxxxxxx	Value of monotonic counter is 13
			0b000000000000000000001xxxxxxxxxxx	Value of monotonic counter is 12
			0b0000000000000000000001xxxxxxxxxx	Value of monotonic counter is 11
			0b00000000000000000000001xxxxxxxxx	Value of monotonic counter is 10
			0b000000000000000000000001xxxxxxxx	Value of monotonic counter is 9
			0b0000000000000000000000001xxxxxxx	Value of monotonic counter is 8
			0b00000000000000000000000001xxxxxx	Value of monotonic counter is 7
			0b000000000000000000000000001xxxxx	Value of monotonic counter is 6
			0b0000000000000000000000000001xxxx	Value of monotonic counter is 5
			0b00000000000000000000000000001xxx	Value of monotonic counter is 4
			0b000000000000000000000000000001xx	Value of monotonic counter is 3
			0b0000000000000000000000000000001x	Value of monotonic counter is 2
			0b00000000000000000000000000000001	Value of monotonic counter is 1
			0b00000000000000000000000000000000	Value of monotonic counter is 0

8.2.4 OTP WORD 5 to 7 - AFmux configuration[edit source]

Bit	Field	Size	Value	Description
31-28	port1[3:0]	4 bits		Bank id
			0	unused
			1	Bank A
			2	Bank B
			3	Bank C
			4	Bank D
			5	Bank E
			6	Bank FK
			7	Bank G
			8	Bank H
			9	Bank I
			10	Bank J
			11	Bank K
			12	Bank Z
			0b1111XXX	Invalid configuration
27-24	pin1[3:0]	4 bits	0-15	Pin Id
23-20	afmux1[3:0]	4 bits	0-15	AFmux value
19-16	mode0[3:0]	4 bits		Pin Mode
			0	AF ; No Pull ; Low Speed
			1	AF ; No Pull ; Medium Speed
			2	AF ; No Pull ; High Speed
			3	AF ; Pull Up ; Low Speed
			4	AF ; Pull Up ; Medium Speed
			5	AF ; Pull Up ; High Speed
			6	AF ; Pull Down ; Low Speed
			7	AF ; Pull Down ; Medium Speed
			8	AF ; Pull Down ; High Speed
			9	GPIO Output High
			10	GPIO Output Low
			11	GPIO Input
			12	GPIO open drain ; No pull
			13	GPIO open drain ; Pull Up
			14	GPIO open drain ; Pull Down
			15	GPIO analog mode
15-12	port0[3:0]	4 bits		Bank id
			0	unused
			1	Bank A
			2	Bank B
			3	Bank C
			4	Bank D
			5	Bank E
			6	Bank FK
			7	Bank G
			8	Bank H
			9	Bank I
			10	Bank J
			11	Bank K
			12	Bank Z
			0b1111XXX	Invalid configuration
8-Nov	pin0[3:0]	4 bits	0-15	Pin Id
4-Jul	afmux0[3:0]	4 bits	0-15	AFmux value
31-0	pull0mode0[31:0]	42 bits		Pin Pull Mode
			0	AF ; No Pull ; Low Speed
			1	AF ; No Pull ; Medium Speed
			2	AF ; No Pull ; High Speed
			3	AF ; Pull Up ; Low Speed
			4	AF ; Pull Up ; Medium Speed
			5	AF ; Pull Up ; High Speed
			6	AF ; Pull Down ; Low Speed
			7	AF ; Pull Down ; Medium Speed
			8	AF ; Pull Down ; High Speed
			9	GPIO Output High
			10	GPIO Output Low
			11	GPIO Input
			12	GPIO open drain ; No pull
			13	GPIO open drain ; Pull Up
			14	GPIO open drain ; Pull Down
			15	GPIO analog mode; Pull down

8.2.5 OTP WORD 9 - NAND configuration[edit source]

Bit	Name	Size	Value	Description
31-31	nand_param_stored_in_otp	1 bit		NAND parameters storage flag
			0b0	NAND parameters are not stored here in OTP and are available via an ‘ONFI’ compliant get parameter command.
			0b1	NAND parameters are stored here in OTP
30-29	nand_page_size[1:0]	2 bits		NAND page size
			0	Page size is 2 Kbytes
			1	Page size is 4 Kbytes
			2	Page size is 8 Kbytes
			3	reserved
28-27	nand_block_size[1:0]	2 bits		NAND block size
			0	Block size is 64 pages
			1	Block size is 128 pages
			2	Block size is 256 pages
			3	reserved
26-19	nand_blocks_nb[7:0]	8 bits		NAND number of blocks
			N	Number of blocks of NAND in unit of 256 blocks (= N * 256 blocks)
18-18	fmc_nand_width	1 bit		FMC NAND width
			0	FMC NAND is 8 bits
			1	FMC NAND is 16 bits
17-15	fmc_ecc_bit_nb[2:0]	3 bits		FMC NAND number of ECC bits
			0	No setting. In case on ONFI NAND, means ‘use value defined in parameter table’
			1	1 bit ECC per 512 bytes, Hamming code
			2	4 bit ECC per 512 bytes of data, BCH (Bose, Chaudhuri and Hocquenghem) code
			3	8 bit ECC per 512 bytes of data, BCH (Bose, Chaudhuri and Hocquenghem) code
			4	on-die ECC
14	spinand_need_plane_select	1 bit		SPI NAND need plane select
			0	SPI NAND plane select not needed.
			1	SPI NAND plane select needed.
13-4	reserved	11 bits	-	-
3	disable_ddr_power_optim	1 bit		Disable DDR PLL switch off sequence
			0	DDR DLL switch off sequence enabled
			1	DDR DLL switch off sequence disabled.
2	disable_hse_bypass_detect	1 bit		Disable HSE bypass detection
			0	HSE bypass detection enabled.
			1	HSE bypass detection disabled.
1	disable_hse_freq_detect	1 bit		Disable HSE frequency autodetection
			0	HSE frequency autodetection enabled.
			1	HSE frequency autodetection disabled.
0	disable_traces	1 bit		Disable traces bit
			0	Bootrom trace are enabled.
			1	Bootrom trace are disabled.

8.2.6 OTP WORD 24 to 31 - Public Key Hash (PKH)[edit source]

OTP WORD 24 to 31 contain the SHA256 hash of (ECDSA algorithm id + ECDSA public key) where ECDSA algorithm id is 32-bit length and valid values are ‘1’ for P-256 NIST, or ‘2’ for Brainpool 256.

OTP word	Bit	Field	Size	Description
24	31-0	pkh0[31:0]	32 bits	Public Key Hash[31:0]
25	31-0	pkh1[31:0]	32 bits	Public Key Hash[63:32]
26	31-0	pkh2[31:0]	32 bits	Public Key Hash[95:64]
27	31-0	pkh3[31:0]	32 bits	Public Key Hash[128:96]
28	31-0	pkh4[31:0]	32 bits	Public Key Hash[159:128]
29	31-0	pkh5[31:0]	32 bits	Public Key Hash[191:160]
30	31-0	pkh6[31:0]	32 bits	Public Key Hash[223:192]
31	31-0	pkh7[31:0]	32 bits	Public Key Hash[255:224]

8.2.7 OTP WORD 56 - RMA password[edit source]

Bit	Name	Size	Description
31-30		2 bits	reserved
29-15	rma_relock_passwd	15 bits	Password required for RMA ReLock request
14-0	rma_passwd	15 bits	Password required for RMA Unlock request

9 Exported secure services[edit source]

The ROM exports authentication services to the following stages of the STM32MP15 secure boot.

10 Debug and error cases[edit source]

10.1 Debug and Error messages[edit source]

PA13 management

The ROM code uses PA13 pin to communicate some status. On STMicroelectronics boards, PA13 is connected to the red LED, as explained in LEDs and buttons on STM32 MPU boards article.

in case of boot failure, the PA13 pin is set to low open-drain (i.e. red LED will light bright).

During UART/USB boot, the PA13 pin will toggle open-drain at a rate of about 5 Hz until a connection is started (i.e. red LED will blink fast).

With BOOT[2:0] = 0b100 (engineering boot, used for specific debug), PA13 will toggle opendrain at a rate of about 5 kHz (i.e. red LED will light weak).

In all other cases, the PA13 is kept in it’s reset value, i.e. high-z until software setting.

Traces

During its execution, the ROM writes binary traces in memory.

Traces can be downloaded from address range 0x2ffc1c00-0x2ffc2404

In case of internal blocking error, the ROM code writes a uart log error at 9600bauds to PA13 pin.

10.2 Common debug and error cases[edit source]

Memory Boot failure

Secure boot flow always enters the serial boot loop during which the Error LED is blinking. Therefore, observing such blinking when Memory boot is required indicates that Memory boot failed.

Security issue

If the bootrom encounters a security issue, it stops immediately the secure boot and sets the Error LED to light bright.