HT is symmetric (in terms of basic resources, the system-mode may be asymmetric).
So, if the HT is turned on, large resources of Physical core will be shared between two threads. Some additional hardware is turned on to save state of both threads. Both threads have symmetric access to physical core.
There is a difference between HT-disabled core and HT-enabled core; but no difference between 1st half of HT-enabled core and 2nd half of HT-enabled core.
At single moment of time, one HT-thread may use more resources than other, but this resource balancing is dynamic. CPU will balance threads as it can and as it wants if both threads want to use the same resource. You can only do a
rep nop or
pause in one thread to let CPU give more resources to other thread.
I wish to find out this information and use set_affinity() to bind a process to hyper-threaded thread or non-hyper-threaded thread to profile its performance.
Okay, you actually can measure performance without knowing a fact. Just do a profile when the only thread in system is binded to CPU0; and repeat it when it is binded to CPU1. I think, the results will be almost the same (OS can generate noise if it binds some interrupts to CPU0; so try to lower number of interrupts when do testing and try to use CPU2 and CPU3 if you have such).
Agner (he is the Guru in x86) recommends to use even-numbered cores in the case when you want not to use HT, but it is enabled in BIOS:
If hyperthreading is detected then lock the process to use the even-numbered logical processors only. This will make one of the two threads in each processor core idle so that there is no contention for resources.
PPS About New-reincarnation HT (not a P4 one, but Nehalem and Sandy) - based on Agner's research on microarchitecture
The new bottlenecks that require attention in the Sandy Bridge are the following:
5. Sharing of resources between threads. Many of the critical resources are shared
between the two threads of a core when hyperthreading is on. It may be wise to turn
off hyperthreading when multiple threads depend on the same execution resources.
A half-way solution was introduced in the NetBurst and again in the Nehalem and Sandy Bridge with the so-called
hyperthreading technology. The hyperthreading processor has two logical processors
sharing the same execution core. The advantage of this is limited if the two threads
compete for the same resources, but hyperthreading can be quite advantageous if the
performance is limited by something else, such as memory access.
Both Intel and AMD are making hybrid solutions where some or all of the
execution units are shared between two processor cores (hyperthreading in Intel
PPPS: Intel Optimization book lists resource sharing in second-generation HT: (page 93, this list is for nehalem, but there is no changes of this list in Sandy section)
Deeper buffering and enhanced resource sharing/partition policies:
- — Replicated resource for HT operation: register state, renamed return stack
buffer, large-page ITLB //comment by me: there are 2 sets of this HW
- — Partitioned resources for HT operation: load buffers, store buffers, re-order
buffers, small-page ITLB are statically allocated between two logical
processors. // comment by me: there is single set of this HW; it is statically splitted between two HT-virtual cores in two halfs
- — Competitively-shared resource during HT operation: the reservation station,
cache hierarchy, fill buffers, both DTLB0 and STLB. // comment: Single set, but divided not in half. CPU will dynamically redivide resources.
- — Alternating during HT operation: front-end operation generally alternates
between two logical processors to ensure fairness. // comment: there is single Frontend (instruction decoder), so threads will be decoded in order: 1, 2, 1, 2.
- — HT unaware resources: execution units. // comment: there are actual hw devices which will do computations, memory accesses. There is only single set. If one of threads is capable of using a lot of execution units and if it has a low number of memory waits, it will consume all exec units and second thread performance will be low (but HT will switch sometimes to second thread. How often??? ). If both threads are not heavy-optimized and/or have memory waits, execution units will be splitted between two threads.
There are also pictures at page 112 (Figure 2-13), which shows that both logical cores are symmetric.
The performance potential due to HT Technology is due to:
- • The fact that operating systems and user programs can schedule processes or
threads to execute simultaneously on the logical processors in each physical
- • The ability to use on-chip execution resources at a higher level than when only a
single thread is consuming the execution resources; higher level of resource
utilization can lead to higher system throughput
Although instructions originating from two programs or two threads execute simultaneously
and not necessarily in program order in the execution core and memory hierarchy,
the front end and back end contain several selection points to select between
instructions from the two logical processors. All selection points alternate between
the two logical processors unless one logical processor cannot make use of a pipeline
stage. In this case, the other logical processor has full use of every cycle of the pipeline
stage. Reasons why a logical processor may not use a pipeline stage include
cache misses, branch mispredictions, and instruction dependencies.