Difference between revisions of "Unit BootRPi2"
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=== Description === | === Description === | ||
---- | ---- | ||
| + | |||
| + | '''Ultibo Initialization code for Raspberry Pi 2 unit''' | ||
'''Raspberry Pi 2''' | '''Raspberry Pi 2''' | ||
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CPU: Cortex A7 (ARMv7) (4 @ 900MHz) | CPU: Cortex A7 (ARMv7) (4 @ 900MHz) | ||
| − | Cache: L1 32KB (Per Core) / L2 512KB (Shared by all Cores) | + | Cache: L1 32KB (Per Core)/L2 512KB (Shared by all Cores) |
FPU: VFPV3 | FPU: VFPV3 | ||
| Line 28: | Line 30: | ||
Bluetooth: (None) | Bluetooth: (None) | ||
| − | Other: GPIO / SPI / I2C / I2S / PL011 (UART) / PWM / SMI / Watchdog (PM) / Random (RNG) / Timer | + | Other: GPIO/SPI/I2C/I2S/PL011 (UART)/PWM/SMI/Watchdog (PM)/Random(RNG)/Timer |
| + | |||
'''Boot RPi2''' | '''Boot RPi2''' | ||
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SMP Coherence - Enabled (Firmware enabled prior to Non Secure switch) | SMP Coherence - Enabled (Firmware enabled prior to Non Secure switch) | ||
| + | |||
If the processor is in Hypervisor mode (Firmware behaviour after 2/10/2015) then Ultibo switches it to Supervisor mode during initial boot. | If the processor is in Hypervisor mode (Firmware behaviour after 2/10/2015) then Ultibo switches it to Supervisor mode during initial boot. | ||
| − | If the configuration option | + | If the configuration option ARMSecureBoot is set to 1 then Ultibo switches the processor back to Secure world during initial boot (see note below). |
Ultibo then switches the processor to System mode for all operations and remains in either the Secure or Non Secure World as per the option above. | Ultibo then switches the processor to System mode for all operations and remains in either the Secure or Non Secure World as per the option above. | ||
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The initialization process enables the MMU, FPU, L1 Cache and other performance optimizations. | The initialization process enables the MMU, FPU, L1 Cache and other performance optimizations. | ||
| + | |||
'''Returning to Secure World:''' | '''Returning to Secure World:''' | ||
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b) Switch to Hypervisor mode (Firmware later than 2/10/2015) | b) Switch to Hypervisor mode (Firmware later than 2/10/2015) | ||
| + | |||
It is not normally possible (by design) to return from the Non Secure world to the Secure world except by invoking the Secure Monitor which then handles any requests in the Secure world. | It is not normally possible (by design) to return from the Non Secure world to the Secure world except by invoking the Secure Monitor which then handles any requests in the Secure world. | ||
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- Perform a Secure Monitor Call (SMC) | - Perform a Secure Monitor Call (SMC) | ||
| − | - From within the newly installed Secure Monitor Call read the Secure Configuration Register (SCR) mask off the Non Secure (NS) bit, rewrite the SCR and then return to Supervisor mode | + | - From within the newly installed Secure Monitor Call read the Secure Configuration Register (SCR) mask off the Non Secure (NS) bit, rewrite the SCR and then return to Supervisor mode. |
| + | |||
Secondary cores also switch back to the Secure world using the same technique however they do not need to install the new SMC vector and instead use the one installed by the primary core. | Secondary cores also switch back to the Secure world using the same technique however they do not need to install the new SMC vector and instead use the one installed by the primary core. | ||
| − | + | Firmware changes from October 2020 disable the ability to perform the SMC instruction from non secure mode which means this technique will no longer work with the default firmware. To allow continued support for returning to the Secure world a custom ARM boot stub is now included with Ultibo that allows the SMC instruction to be performed. | |
| + | |||
| + | This custom stub contains a marker that allows the boot process to detect it and disable the attempt to switch back to the Secure world if the default boot stub is used instead. | ||
| + | |||
| + | As the default boot stub continues to evolve in response to demands from the Linux community this technique will allow Ultibo to continue to provide the features we want without having to make frequent changes to combat items that are beyond our control. | ||
| + | |||
| + | Thanks to the Circle project for introducing the custom boot stub technique to work around these changes. | ||
=== Constants === | === Constants === | ||
---- | ---- | ||
| − | '' | + | ''None defined'' |
=== Type definitions === | === Type definitions === | ||
---- | ---- | ||
| − | '' | + | ''None defined'' |
=== Public variables === | === Public variables === | ||
---- | ---- | ||
| − | '' | + | ''None defined'' |
=== Function declarations === | === Function declarations === | ||
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<div class="toccolours mw-collapsible mw-collapsed" style="border: 1; font-family: arial; padding-top: 0px; padding-bottom: 15px;"> | <div class="toccolours mw-collapsible mw-collapsed" style="border: 1; font-family: arial; padding-top: 0px; padding-bottom: 15px;"> | ||
| − | <pre style="border: 0; padding-bottom:0px;">procedure Startup; assembler; nostackframe; | + | <pre style="border: 0; padding-bottom:0px;">procedure Startup; assembler; nostackframe; public name '_START';</pre> |
<div style="font-size: 14px; padding-left: 12px;">'''Description:''' Entry point of Ultibo on Raspberry Pi 2, this will be the very first byte executed and will be loaded by the GPU at address 0x00008000</div> | <div style="font-size: 14px; padding-left: 12px;">'''Description:''' Entry point of Ultibo on Raspberry Pi 2, this will be the very first byte executed and will be loaded by the GPU at address 0x00008000</div> | ||
<div class="mw-collapsible-content" style="text-align: left; padding-left: 5px;"> | <div class="mw-collapsible-content" style="text-align: left; padding-left: 5px;"> | ||
{| class="wikitable" style="font-size: 14px; background: white;" | {| class="wikitable" style="font-size: 14px; background: white;" | ||
|- | |- | ||
| − | ! | + | ! Note |
| None documented | | None documented | ||
|- | |- | ||
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{| class="wikitable" style="font-size: 14px; background: white;" | {| class="wikitable" style="font-size: 14px; background: white;" | ||
|- | |- | ||
| − | ! | + | ! Note |
| See A2.6 "Exceptions" of the ARM Architecture Reference Manual | | See A2.6 "Exceptions" of the ARM Architecture Reference Manual | ||
|- | |- | ||
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{| class="wikitable" style="font-size: 14px; background: white;" | {| class="wikitable" style="font-size: 14px; background: white;" | ||
|- | |- | ||
| − | ! | + | ! Note |
| See A2.6 "Exceptions" of the ARM Architecture Reference Manual | | See A2.6 "Exceptions" of the ARM Architecture Reference Manual | ||
|- | |- | ||
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{| class="wikitable" style="font-size: 14px; background: white;" | {| class="wikitable" style="font-size: 14px; background: white;" | ||
|- | |- | ||
| − | ! | + | ! Note |
| None documented | | None documented | ||
|- | |- | ||
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{| class="wikitable" style="font-size: 14px; background: white;" | {| class="wikitable" style="font-size: 14px; background: white;" | ||
|- | |- | ||
| − | ! | + | ! Note |
| None documented | | None documented | ||
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{| class="wikitable" style="font-size: 14px; background: white;" | {| class="wikitable" style="font-size: 14px; background: white;" | ||
|- | |- | ||
| − | ! | + | ! Note |
| None documented | | None documented | ||
|- | |- | ||
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{| class="wikitable" style="font-size: 14px; background: white;" | {| class="wikitable" style="font-size: 14px; background: white;" | ||
|- | |- | ||
| − | ! | + | ! Note |
| None documented | | None documented | ||
|- | |- | ||
Latest revision as of 01:18, 22 April 2022
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Description
Ultibo Initialization code for Raspberry Pi 2 unit
Raspberry Pi 2
SoC: Broadcom BCM2836
CPU: Cortex A7 (ARMv7) (4 @ 900MHz) Cache: L1 32KB (Per Core)/L2 512KB (Shared by all Cores)
FPU: VFPV3
GPU: Broadcom VideoCore IV (VC4)
RAM: 1GB
USB: Synopsys DesignWare Hi-Speed USB 2.0 On-The-Go Controller (DWCOTG)
LAN: SMSC LAN9514 (SMSC95XX)
SD/MMC: Arasan (BCM2709)
WiFi: (None)
Bluetooth: (None)
Other: GPIO/SPI/I2C/I2S/PL011 (UART)/PWM/SMI/Watchdog (PM)/Random(RNG)/Timer
Boot RPi2
The boot loader on the Raspberry Pi 2 will load this code at address 0x00008000 onwards and set the following registers before jumping to this code.
R0 - Zero
R1 - Machine Type (Raspberry Pi 2 or BCM2709 = 0x0C42)
R2 - Address of the ARM Tags structure (Normally 0x0100)
On entry to this code the processor will be in the following state:
World - Non Secure (Firmware causes a switch to Non Secure before jumping to Startup code)
Mode - Supervisor (ARM_MODE_SVC) Note: Firmware later than 2/10/2015 will boot in Hypervisor mode (ARM_MODE_HYP)
MMU - Disabled
FPU - Disabled
L1 Data Cache - Enabled (Firmware enabled prior to Non Secure switch)
L1 Instruction Cache - Enabled (Firmware enabled prior to Non Secure switch)
Branch Predication - Disabled
Unaligned Data Access - Enabled (Always enabled on ARMv7)
SMP Coherence - Enabled (Firmware enabled prior to Non Secure switch)
If the processor is in Hypervisor mode (Firmware behaviour after 2/10/2015) then Ultibo switches it to Supervisor mode during initial boot.
If the configuration option ARMSecureBoot is set to 1 then Ultibo switches the processor back to Secure world during initial boot (see note below).
Ultibo then switches the processor to System mode for all operations and remains in either the Secure or Non Secure World as per the option above.
The initialization process enables the MMU, FPU, L1 Cache and other performance optimizations.
Returning to Secure World:
The Raspberry Pi 2 firmware always switches to Non Secure world in order to:
a) Reset CNTVOFF (Virtual Offset register) to zero
b) Switch to Hypervisor mode (Firmware later than 2/10/2015)
It is not normally possible (by design) to return from the Non Secure world to the Secure world except by invoking the Secure Monitor which then handles any requests in the Secure world.
However due to the fact that this switch is performed by the boot loader code (loaded between 0x00000000 and 0x000000FF by the firmware) and that the code appears to set the secure, non secure and monitor vector base addresses to 0x00000000 and because all memory is writable from non secure at boot (the MMU is disabled) then the option exists to return to the Secure world as follows:
- Install a new Secure Monitor Call vector at the appropriate point in the vector table
- Clean the data cache by Modified Virtual Address at address 0x00000000
- Perform a data synchronisation barrier
- Invalidate the entire instruction cache
- Perform a data synchronisation barrier
- Perform an instruction synchronisation barrier
- Perform a Secure Monitor Call (SMC)
- From within the newly installed Secure Monitor Call read the Secure Configuration Register (SCR) mask off the Non Secure (NS) bit, rewrite the SCR and then return to Supervisor mode.
Secondary cores also switch back to the Secure world using the same technique however they do not need to install the new SMC vector and instead use the one installed by the primary core.
Firmware changes from October 2020 disable the ability to perform the SMC instruction from non secure mode which means this technique will no longer work with the default firmware. To allow continued support for returning to the Secure world a custom ARM boot stub is now included with Ultibo that allows the SMC instruction to be performed.
This custom stub contains a marker that allows the boot process to detect it and disable the attempt to switch back to the Secure world if the default boot stub is used instead.
As the default boot stub continues to evolve in response to demands from the Linux community this technique will allow Ultibo to continue to provide the features we want without having to make frequent changes to combat items that are beyond our control.
Thanks to the Circle project for introducing the custom boot stub technique to work around these changes.
Constants
None defined
Type definitions
None defined
Public variables
None defined
Function declarations
Boot functions
procedure Startup; assembler; nostackframe; public name '_START';
| Note | None documented |
|---|
procedure Vectors; assembler; nostackframe;
| Note | See A2.6 "Exceptions" of the ARM Architecture Reference Manual |
|---|
procedure SecureVectors; assembler; nostackframe;
| Note | See A2.6 "Exceptions" of the ARM Architecture Reference Manual |
|---|
procedure SecureMonitor; assembler; nostackframe;
| Note | None documented |
|---|
procedure StartupSwitch; assembler; nostackframe;
| Note | None documented |
|---|
procedure StartupSecure; assembler; nostackframe;
| Note | None documented |
|---|
procedure StartupHandler; assembler; nostackframe;
| Note | None documented |
|---|
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