Boot Sequence: Difference between revisions
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| SAFE_MODE | | SAFE_MODE | ||
| A flag | | A flag in sysroot buffer indicates device should enter safe mode. | ||
|- | |- | ||
| DEVELOPMENT_MODE | | DEVELOPMENT_MODE | ||
| [[SceSblACMgr]] is called to check if device is a development device. | | [[SceSblACMgr]] is called to check if device is a development device and is in DevMode. | ||
|} | |} | ||
Revision as of 06:57, 21 January 2019
The Vita main application processor is a Cortex A9 MPcore. It implements ARM TrustZone for execution in both a non-secure world and a sandboxed Secure World.
Boot Process
Boot ROM
It is likely that the F00D processor (MeP Core) is the actual secure boot device rather than the ARM CPU. The F00D processor is Toshiba MEP based and is the first secure device ("first loader") to start on the Vita. Once it starts it likely maps the eMMC and directly reads in the second_loader.enp or second_loader.enp_ from the eMMC slb2 partition. This is in the native load format of the F00D bootrom. There are likely 2 layers of encryption. First it decrypts the per-console layer that was added during the install. After that it will decrypt the factory-encrypted layer then begin execution.
The second_loader is primarily responsible for preparing the ARM processor. It initializes DRAM and decrypts slb2 kernel_boot_loader.self into DRAM. It also writes the ARM exception vector and some boot context information to the 32KB scratch buffer (mirror mapped to 0x00000000 on ARM). kernel_boot_loader.self contains both the secure world kernel bootloader and secure kernel, as well as the non-secure kernel boot loader. At this point the slb2 kprx_auth_sm.self and prog_rvk.srvk are both loaded into DRAM.
Finally, the second_loader resets itself with a pointer to the secure_kernel.enp or enp_. F00D processor then restarts and loads the secure_kernel.enp in and again decrypts the per-console layer that was added by the install, and the factory layer. At this point the F00D processor secure kernel is prepared and it resets the ARM CPU at 0x00000000 (F00D scratch buffer). This triggers the ARM secure boot process to begin.
Secure Kernel
The bootloader decompresses the ARZL secure kernel, loads it and sets up the VBAR and MVBAR. It then decompresses the ARZL non-secure kernel bootloader and sets NS in SCR and jumps into non-secure kernel bootloader. See Secure Bootloader for more information.
SceKblForKernel
The non-secure kernel bootloader contains an embedded and likely stripped version of SceSysmem, SceKernelModulemgr, SceSblSmschedProxy, and some other core drivers. The NS KBL sets up the eMMC device (again) and starts os0:psp2bootconfig.skprx
.
ScePsp2BootConfig
This kernel module does not export any library. It only has a module init function that has a hard coded list of core kernel modules (ex: sysmem.skprx) which are loaded with calls back into NSKBL through SceKblForKernel imports. Once the core initialization is done, the next module to run is SceSysStateMgr.
SceSysStateMgr
This kernel module also does not export any library. Its init function first maps all the SceKernelBootimage embedded modules and redirects them to os0:kd/. Then it decrypts os0:psp2config.skprx
or os0:psp2config_vita.skprx
or os0:psp2config_dolce.skprx
and parses the System Configuration Script to load the remaining modules and finally either SceSafemode or SceShell or ScePsp2Swu or ScePsp2Diag.
Boot Partition
The boot partition is SLB2 formatted. It contains entries these files:
Name | Earliest Known Version | Comments |
---|---|---|
kernel_boot_loader.self | 1.05 | Secure KBL and ARZL compressed non-secure KBL |
kprx_auth_sm.self | 1.05 | Used with F00D Processor to decrypt SELFs |
prog_rvk.srvk | 1.05 | SCE encrypted revocation data of some sort |
second_loader.enp | 1.05 | Possibly the secure bootloader |
second_loader.enp_ | 1.69 | Related to second_loader.enp in some way, likely for encryption |
secure_kernel.enp | 1.05 | Possibly the secure kernel ARZL compressed and loaded into memory by ROM |
secure_kernel.enp_ | 1.05 | Related to secure_kernel.enp in some way, likely for encryption |
System Configuration Script
os0:psp2config.skprx
once decrypted is a UTF-8 text file that is parsed by SceSysStateMgr. It is a very simple script format.
If "manufacturing mode" is enabled, then it is possible to load psp2config.skprx
from sd0:
(not present in any production device or devkits) or ux0:
. However, the files must still be signed and encrypted SELFs. In "manufacturing mode" with the default boot config, if sd0:psp2diag.self
or ux0:psp2diag.self
exists (and is a valid signed & encrypted SELF), then it will be launched. If "development mode" is enabled (note that this does not necessarily mean PDEL or devkit), then psp2config.skprx
can be a plaintext file instead.
Comments
Comments start out with #
, as an example, here's the header of 1.69 psp2config.skprx
# # PSP2 System Configuration for Release # # [NOTICE] # # This configuration is only for kernel_boot_loader_release.self. #
Conditionals
Conditionals start with if
and end with endif
. There are certain conditional constants defined in SceSysStateMgr. A table of known conditionals is below.
Name | Description |
---|---|
MANUFACTURING_MODE | Unknown. Depends on some condition set on boot by some bootloader |
EXTERNAL_BOOT_MODE | Unknown. Depends on some condition set on boot by some bootloader |
UPDATE_MODE | Set by Syscon when an update is about to be performed. |
USB_ENUM_WAKEUP | Unknown. Could be CMA connection while device is turned off or IDU mode USB boot. |
KERMIT_REV_ES1_X | Unknown. GPU hardware revision related. |
KERMIT_REV_ES2_X | Unknown. GPU hardware revision related. |
KERMIT_REV_ES3_X | Unknown. GPU hardware revision related. |
KERMIT_REV_ES4_X | Unknown. GPU hardware revision related. |
UD0_EXIST | Does the ud0: Partition exist? |
DEMO_MODE | Is the Vita a IDU/ShowMode flagged? |
SAFE_MODE | A flag in sysroot buffer indicates device should enter safe mode. |
DEVELOPMENT_MODE | SceSblACMgr is called to check if device is a development device and is in DevMode. |
Example:
if SAFE_MODE spawn os0:ue/safemode.self end endif
Load
load path
will load the kernel module at path
.
tload path
possibly stands for "test load." Possibly used in development units to load to module to dedicated devkit RAM.
Example:
load os0:kd/ngs.skprx
Spawn
spawn path
will spawn an app and continue processing the script in the background.
spawnwait path
will spawn an app and wait for it to exit before continuing processing the script.
appspawn path param
is used to spawn vs0:vsh/shell/shell.self
. Specify a paramater to pass.
Known param constants:
Name | Description |
---|---|
SHELL_BUDGET_ID | Unknown. |
Example:
if UPDATE_MODE if UD0_EXIST spawn ud0:PSP2UPDATE/psp2swu.self else spawn ur0:PSP2UPDATE/psp2swu.self endif end endif
Include
include path
will include and process a config script located at path
.
Example:
include ur0:temp/bcfg2.txt
End
end
will end script processing
Ignore Error
Any line that starts with -
will not fail the boot sequence if the line fails. For example, you can specify an optional module to load such that boot continues if the module does not exist or errors on load.
All codes (from 0.990)
load, unload, loadonly, start, stop, unloadonly, spawn, spawnwait, wait, kill, loadconfig, ifmodel, ifnmodel, setenv, setmodfile, repeat, endrepeat, appspawn, tload
+ include, if, endif, end
Boot Debug Checkpoint Codes
During the boot sequence, the various bootloaders will update a GPIO register specifying the progress into boot. This can be used to debug where in the boot process something fails.
GPIO
The GPIO registers are registered at 0xE20A000C
(turn off bits) and 0xE20A0008
(turn on bits). On PDEL units, this maps to the LED lights.
Known Codes
Code | Location | Description |
---|---|---|
72 | ? | ? |
84 | ? | ? |
85 | ? | ? |
86 | ? | ? |
96 | ? | ? |
129 | Secure Kernel Loader | Core 0 (secure world) pre-init complete |
130 | Secure Kernel Loader | Secure world interrupts registered (?) |
131 | Secure Kernel Loader | Serial console ready, boot message printed |
132 | Secure Kernel Loader | Some device init |
133 | Secure Kernel Loader | Some co-processor init. Starting point for other cores. |
134 | Secure Kernel Loader | MMU enabled, VBAR/MVBAR set up |
135 | Secure Kernel Loader | Nothing since 134 |
136 | Secure Kernel Loader | Boot setup complete, secure kernel loading begin |
137 | Secure Kernel Loader | Secure kernel loaded. About to load NS KBL at 0x51000000
|
138 | Secure Kernel Loader | Secure kernel loaded. About to resume context at 0x1F000000 . Or undefined instruction exception.
|
139 | Secure Kernel Loader | SVC exception (should not happen, error) |
140 | Secure Kernel Loader | Prefetch abort exception |
141 | Secure Kernel Loader | Data abort exception |
142 | Secure Kernel Loader | IRQ exception (should not happen, error) |
143 | Secure Kernel Loader | FIQ exception (should not happen, error) |
161 | NS Kernel Loader | Core 0 (non-secure world) pre-init complete |
162 | NS Kernel Loader | Some interrupts registered (?) |
163 | NS Kernel Loader | Serial console ready, boot message printed (if enabled) |
164 | NS Kernel Loader | Some buffer is initialized to device addresses |
165 | NS Kernel Loader | Some co-processor init. Starting point for other cores. |
166 | NS Kernel Loader | MMU enabled, VBAR set up |
167 | NS Kernel Loader | Nothing since 166 |
168 | NS Kernel Loader | Boot setup complete, NS kernel loading begin |
169 | NS Kernel Loader | Kernel pre-init (setup stacks, interrupts, etc) done. Right before first external loading. |
170 | NS Kernel Loader | Undefined instruction exception |
171 | NS Kernel Loader | SVC exception (should not happen, error) |
172 | NS Kernel Loader | Prefetch abort exception |
173 | NS Kernel Loader | Data abort exception |
174 | NS Kernel Loader | IRQ exception (should not happen, error) |
175 | NS Kernel Loader | FIQ exception (should not happen, error) |
Suspend and Resume
Upon suspension, context is written to memory and a syscon command is issued to save the context pointer as well as other information (for example, if it should restart into update mode). When resuming, the boot process is the same as cold boot up until the secure kernel bootloader. After secure kernel loads, instead of decompressing and jumping to the non-secure kernel bootloader, it restores the saved context and returns to the kernel resume code.
See Suspend.