CPU: Difference between revisions
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* Designed by: ARM | * Designed by: ARM | ||
* Common manufacturer(s): TSMC | * Common manufacturer(s): TSMC | ||
* CPU clock rate: | * CPU clock rate: 111 MHz to 500 MHz (Clockrate can be manually changed if the handheld is modded) | ||
* Instruction set: ARMv7 | * Instruction set: ARMv7 | ||
* Cores: 1-4 | * Cores: 1-4 |
Latest revision as of 08:37, 23 March 2018
4 core ARM Cortex-A9 MPCore[edit | edit source]
The ARM Cortex-A9 MPCore is a multicore processor providing up to 4 cache-coherent Cortex-A9 cores, each implementing the ARM v7 instruction set architecture.
Specifications[edit | edit source]
- Designed by: ARM
- Common manufacturer(s): TSMC
- CPU clock rate: 111 MHz to 500 MHz (Clockrate can be manually changed if the handheld is modded)
- Instruction set: ARMv7
- Cores: 1-4
- L1 cache: 32 kB I/32 kB D
- L2 cache controller: (0-4 MB)
The actual application processor cores are Cortex A9, which is common in modern high performance embedded devices like cell phones and tablets. The Technical Reference Manual gives a good overview of the specific processor features and is a good reference for what ARMv7 implementation specific features are enabled. The Vita cores have a MIDR value of 0x412FC09A
, meaning it is Cortex A9 r2p10. Indeed there are usage of undocumented CP15 registers.
Another manual that's important is the MPCore Technical Reference Manual which is specific to the multi-core system the Vita uses. The main information of use are descriptors for the private memory region defined with the PERIPHBASE
signal. This is mapped to physical address 0x1A000000
.
Interrupt Controller[edit | edit source]
As part of the Cortex A9 MPcore, the Vita also implements the Generic Interrupt Controller Architecture. More information on interrupts can be found here.
PL310 L2 Cache[edit | edit source]
The Vita uses the PL310 L2 cache is is mapped to 0x1A002000
.
Debugging/Tracing[edit | edit source]
CoreSight for Cortex-A series processors enable developers to control (debug) and observe (trace) their Cortex-A processor-based SoC with fewer pins. Cortex-A processor debug and run time control can be performed with only 2 pins using the Serial Wire Debug technology or alternatively using JTAG, when highly compressed real-time trace of the cores and others system trace can be captured on-chip (ETB) or exported through a dedicated trace port (TPIU).