Supported Processors: Difference between revisions
(Reorganize, remove obsolete MontaVista specific verbiage, clarify a bit more.) |
No edit summary |
||
(14 intermediate revisions by 2 users not shown) | |||
Line 2: | Line 2: | ||
[[image:chip.jpg|right]] | [[image:chip.jpg|right]] | ||
The Xtensa processor architecture is a configurable | The Xtensa processor architecture is a configurable and extensible synthesizable 32-bit RISC processor core. SoC and processor designers can select from a variety of options, such as instruction-set extensions (for example, narrow instructions, floating point instructions, etc.), memory, cache, and interrupt configurations. Moreover, Xtensa processors also support custom-defined instructions and registers. Nevertheless, all Xtensa processors share a common base instruction set architecture, thereby ensuring compatibility of third party application software and development tools. | ||
Tensilica’s Diamond Standard Series processor family consists of a number of ready-to-use synthesizable cores and is based on the Xtensa processor architecture. The Diamond Standard | Tensilica’s Diamond Standard Series processor family consists of a number of ready-to-use synthesizable cores and is based on the Xtensa processor architecture. The Diamond Standard 233L processor, for example, contains an MMU and fully supports running Linux. | ||
== Automatic Support for Custom Xtensa Cores == | == Automatic Support for Custom Xtensa Cores == | ||
Despite the endless possibilities provided by the configurability and extensibility of the Xtensa architecture, | Despite the endless possibilities provided by the configurability and extensibility of the Xtensa architecture, generating an open source toolchain and kernel that fully support a specific configured Xtensa processor is straightforward. It only requires to update a small set of files inside the toolchain and kernel sources before the actual build process. All necessary files are typically provided by the processor vendor or directly from Tensilica in the form of a single ''overlay'' file. This mostly automated process (scripted) avoids having to ''manually'' port the kernel to a new processor variant, which would be typical for a fixed processor architecture. | ||
Note that a ''processor configuration'' is also often referred to as a ''core variant'' in Linux. The following list shows processor configurations already included in the kernel: | |||
* Diamond 232L | |||
* Diamond 233L | |||
* Stretch S6000 (without MMU) | |||
* 'FSF' default configuration (only for tool verification) | |||
Latest revision as of 20:50, 11 November 2013
Xtensa Processor Architecture
The Xtensa processor architecture is a configurable and extensible synthesizable 32-bit RISC processor core. SoC and processor designers can select from a variety of options, such as instruction-set extensions (for example, narrow instructions, floating point instructions, etc.), memory, cache, and interrupt configurations. Moreover, Xtensa processors also support custom-defined instructions and registers. Nevertheless, all Xtensa processors share a common base instruction set architecture, thereby ensuring compatibility of third party application software and development tools.
Tensilica’s Diamond Standard Series processor family consists of a number of ready-to-use synthesizable cores and is based on the Xtensa processor architecture. The Diamond Standard 233L processor, for example, contains an MMU and fully supports running Linux.
Automatic Support for Custom Xtensa Cores
Despite the endless possibilities provided by the configurability and extensibility of the Xtensa architecture, generating an open source toolchain and kernel that fully support a specific configured Xtensa processor is straightforward. It only requires to update a small set of files inside the toolchain and kernel sources before the actual build process. All necessary files are typically provided by the processor vendor or directly from Tensilica in the form of a single overlay file. This mostly automated process (scripted) avoids having to manually port the kernel to a new processor variant, which would be typical for a fixed processor architecture.
Note that a processor configuration is also often referred to as a core variant in Linux. The following list shows processor configurations already included in the kernel:
- Diamond 232L
- Diamond 233L
- Stretch S6000 (without MMU)
- 'FSF' default configuration (only for tool verification)