The goal of this text is to provide an overview of RISC-V Vector extension (RVV), and compare โ when applicable โ with widespread SIMD vector instruction sets: SSE, AVX, AVX-512, ARM Neon and SVE.
The RISC-V architecture defines four basic modes (32-bit, 32-bit for embedded systems, 64-bit, 128-bit) and several extensions. For instance, the support for single precision floating-point numbers is added by the F extension.
The vector extension is quite a huge addition. It adds 302 instructions plus four highly configurable load & store operations. The RVV instructions can be split into three groups:
- related to masks,
- integer operations,
- and floating-point operations.
When a CPU does not support floating-point instructions, it still may provide the integer subset.
RVV introduces 32 vector registers v0, ..., v31, a concept of mask (similar to AVX-512), and nine control registers.
Unlike other SIMD ISAs, RVV does not explicitly define size of vector register. It is an implementation parameter (called VLEN): the size has to be a power of two, but not greater than 216 bits. Likewise, the maximum vector element size is an implementation parameter (called ELEN, also a power of two and not less than 8 bits). For example, a 32-bit CPU might not support vectors of 64-bit values.
But generally, we may expect that a decent 64-bit CPU would support elements having 8, 16, 32 or 64-bit, interpreted as integers or floats.