| Tegra SoCs - Overview |
| ===================== |
| |
| - .. rubric:: T186 |
| :name: t186 |
| |
| The NVIDIA® Parker (T186) series system-on-chip (SoC) delivers a heterogeneous |
| multi-processing (HMP) solution designed to optimize performance and |
| efficiency. |
| |
| T186 has Dual NVIDIA Denver 2 ARM® CPU cores, plus Quad ARM Cortex®-A57 cores, |
| in a coherent multiprocessor configuration. The Denver 2 and Cortex-A57 cores |
| support ARMv8, executing both 64-bit Aarch64 code, and 32-bit Aarch32 code |
| including legacy ARMv7 applications. The Denver 2 processors each have 128 KB |
| Instruction and 64 KB Data Level 1 caches; and have a 2MB shared Level 2 |
| unified cache. The Cortex-A57 processors each have 48 KB Instruction and 32 KB |
| Data Level 1 caches; and also have a 2 MB shared Level 2 unified cache. A |
| high speed coherency fabric connects these two processor complexes and allows |
| heterogeneous multi-processing with all six cores if required. |
| |
| - .. rubric:: T210 |
| :name: t210 |
| |
| T210 has Quad Arm® Cortex®-A57 cores in a switched configuration with a |
| companion set of quad Arm Cortex-A53 cores. The Cortex-A57 and A53 cores |
| support Armv8-A, executing both 64-bit Aarch64 code, and 32-bit Aarch32 code |
| including legacy Armv7-A applications. The Cortex-A57 processors each have |
| 48 KB Instruction and 32 KB Data Level 1 caches; and have a 2 MB shared |
| Level 2 unified cache. The Cortex-A53 processors each have 32 KB Instruction |
| and 32 KB Data Level 1 caches; and have a 512 KB shared Level 2 unified cache. |
| |
| - .. rubric:: T132 |
| :name: t132 |
| |
| Denver is NVIDIA's own custom-designed, 64-bit, dual-core CPU which is |
| fully Armv8-A architecture compatible. Each of the two Denver cores |
| implements a 7-way superscalar microarchitecture (up to 7 concurrent |
| micro-ops can be executed per clock), and includes a 128KB 4-way L1 |
| instruction cache, a 64KB 4-way L1 data cache, and a 2MB 16-way L2 |
| cache, which services both cores. |
| |
| Denver implements an innovative process called Dynamic Code Optimization, |
| which optimizes frequently used software routines at runtime into dense, |
| highly tuned microcode-equivalent routines. These are stored in a |
| dedicated, 128MB main-memory-based optimization cache. After being read |
| into the instruction cache, the optimized micro-ops are executed, |
| re-fetched and executed from the instruction cache as long as needed and |
| capacity allows. |
| |
| Effectively, this reduces the need to re-optimize the software routines. |
| Instead of using hardware to extract the instruction-level parallelism |
| (ILP) inherent in the code, Denver extracts the ILP once via software |
| techniques, and then executes those routines repeatedly, thus amortizing |
| the cost of ILP extraction over the many execution instances. |
| |
| Denver also features new low latency power-state transitions, in addition |
| to extensive power-gating and dynamic voltage and clock scaling based on |
| workloads. |
| |
| Directory structure |
| =================== |
| |
| - plat/nvidia/tegra/common - Common code for all Tegra SoCs |
| - plat/nvidia/tegra/soc/txxx - Chip specific code |
| |
| Trusted OS dispatcher |
| ===================== |
| |
| Tegra supports multiple Trusted OS'. |
| |
| - Trusted Little Kernel (TLK): In order to include the 'tlkd' dispatcher in |
| the image, pass 'SPD=tlkd' on the command line while preparing a bl31 image. |
| - Trusty: In order to include the 'trusty' dispatcher in the image, pass |
| 'SPD=trusty' on the command line while preparing a bl31 image. |
| |
| This allows other Trusted OS vendors to use the upstream code and include |
| their dispatchers in the image without changing any makefiles. |
| |
| These are the supported Trusted OS' by Tegra platforms. |
| |
| Tegra132: TLK |
| Tegra210: TLK and Trusty |
| Tegra186: Trusty |
| |
| Scatter files |
| ============= |
| |
| Tegra platforms currently support scatter files and ld.S scripts. The scatter |
| files help support ARMLINK linker to generate BL31 binaries. For now, there |
| exists a common scatter file, plat/nvidia/tegra/scat/bl31.scat, for all Tegra |
| SoCs. The `LINKER` build variable needs to point to the ARMLINK binary for |
| the scatter file to be used. Tegra platforms have verified BL31 image generation |
| with ARMCLANG (compilation) and ARMLINK (linking) for the Tegra186 platforms. |
| |
| Preparing the BL31 image to run on Tegra SoCs |
| ============================================= |
| |
| .. code:: shell |
| |
| CROSS_COMPILE=<path-to-aarch64-gcc>/bin/aarch64-none-elf- make PLAT=tegra \ |
| TARGET_SOC=<target-soc e.g. t186|t210|t132> SPD=<dispatcher e.g. trusty|tlkd> |
| bl31 |
| |
| Platforms wanting to use different TZDRAM\_BASE, can add ``TZDRAM_BASE=<value>`` |
| to the build command line. |
| |
| The Tegra platform code expects a pointer to the following platform specific |
| structure via 'x1' register from the BL2 layer which is used by the |
| bl31\_early\_platform\_setup() handler to extract the TZDRAM carveout base and |
| size for loading the Trusted OS and the UART port ID to be used. The Tegra |
| memory controller driver programs this base/size in order to restrict NS |
| accesses. |
| |
| typedef struct plat\_params\_from\_bl2 { |
| /\* TZ memory size */ |
| uint64\_t tzdram\_size; |
| /* TZ memory base */ |
| uint64\_t tzdram\_base; |
| /* UART port ID \*/ |
| int uart\_id; |
| /* L2 ECC parity protection disable flag \*/ |
| int l2\_ecc\_parity\_prot\_dis; |
| /* SHMEM base address for storing the boot logs \*/ |
| uint64\_t boot\_profiler\_shmem\_base; |
| } plat\_params\_from\_bl2\_t; |
| |
| Power Management |
| ================ |
| |
| The PSCI implementation expects each platform to expose the 'power state' |
| parameter to be used during the 'SYSTEM SUSPEND' call. The state-id field |
| is implementation defined on Tegra SoCs and is preferably defined by |
| tegra\_def.h. |
| |
| Tegra configs |
| ============= |
| |
| - 'tegra\_enable\_l2\_ecc\_parity\_prot': This flag enables the L2 ECC and Parity |
| Protection bit, for Arm Cortex-A57 CPUs, during CPU boot. This flag will |
| be enabled by Tegrs SoCs during 'Cluster power up' or 'System Suspend' exit. |