multithreading

Simultaneous multithreading is a processor's ability to process more than one data thread at a time.

Houdini's smoke system is great but it's badly in need of better multithreading.

Coarse-grain multithreading is more common for less context switch between threads.

Simultaneous multithreading by multiple cores and hyper-threading (2x per core).

It is not exactly the same thing as simultaneous multithreading as found on later Pentium 4 processors.

These considerations are claimed to be the reason Intel dropped simultaneous multithreading from the following microarchitecture.

It also has a solid multithreading and multitasking model, meaning that one errant program can't bring the whole computer to its knees.

In coarse-grained temporal multithreading, the main processor pipeline contains only one thread at a time.

There are two ways that a processor can perform such a feat: simultaneous multithreading, and using multiple cores.

A further enhancement is simultaneous multithreading.

Cooperative multithreading, on the other hand, relies on the threads themselves to relinquish control once they are at a stopping point.

The purpose of interleaved multithreading is to remove all data dependency stalls from the execution pipeline.

In temporal multithreading, only one thread of instructions can execute in any given pipeline stage at a time.

Like its predecessor, EKA1, it has pre-emptive multithreading and full memory protection.

The adoption of multithreading has been slow going, and part of the reason has been language support.

Intel claims up to a 30% performance improvement compared with an otherwise identical, non-simultaneous multithreading Pentium 4.

New features included improved multithreading, regular expression syntax and the ability to query remote databases.

There are many possible variations of temporal multithreading, but most can be classified into two sub-forms: coarse-grained and fine-grained.

SOP provides a built-in opportunity for automated multithreading.

Each core features 4-way simultaneous multithreading, which means that the 8-core will support a total of 32 simultaneous threads per socket.

Hardware-based multithreading.

The Niagara has 8 cores, but each core has only one pipeline, so actually it uses fine-grained multithreading.

Each A2 core is capable of four-way multithreading and have 16k+16k instruction and data cache per core.

The signature catch phrase for BeOS was "pervasive multithreading."

Scouting and simultaneous multithreading (SMT) both use hardware threads to fight the memory wall.