Nsight Visual Studio Edition 2.1 and 2.2 Issue Efficiency experiments provides the information you are requesting. These counters/metrics should be added to the Visual Profiler in a release after CUDA 5.0.
Nsight Visual Studio Edition
From Nsight Visual Studio Edition 2.2 User Guide | Analysis Tools | Other Analysis Reports | Profiler CUDA Settings | Issue Efficiency Section
Issue Efficiency provides information about the device's ability to
issue the instructions of the kernel. The data reported includes
execution dependencies, eligible warps, and SM stall reasons.
For devices of compute capability 2.x, a multiprocessor has two warp
schedulers. Each warp scheduler manages at most 24 warps, for a total
of 48 warps per multiprocessor. The kernel execution configuration may
reduce the runtime limit. For information on occupancy, see the
Achieved Occupancy experiment. The first scheduler is in charge of the
warps with an odd ID, and the second scheduler is in charge of warps
with an even ID.
KEPLER UPDATE: For compute capability 3.x, a multiprocessor has four warp schedulers. Each warp scheduler manages at most 16 warps, for a total of 64 warps per multiprocessor.
At every instruction issue time, each scheduler will pick an eligible
warp from its list of active warps and issue an instruction. A warp is
eligible if the instruction has been fetched, the execution unit
required by the instruction is available, and the instruction has no
dependencies that have not been met.
The schedulers report the following statistics on the warps in the
Active Warps – A warp is active from the time it is scheduled on a
multiprocessor until it completes the last instruction. The active
warps counter increments by 0-48 per cycle. The maximum increment per
cycle is defined by the theoretical occupancy.
KEPLER UPDATE Range is 0-64 per cycle.
Eligible Warps – An active warp is eligible if it is able to issue the next instruction.
Warps that are not eligible will report an Issue Stall Reason. This
counter will increment by 0-ActiveWarps per cycle.
UPDATE On Fermi the Issue Stall Reason counters are updated only on cycles that the warp scheduler had not eligible warps. On Kepler the Issue Stall Reason counters are updated every cycle even if the warp scheduler issues an instruction.
Zero Eligible Warps – This counter increments each cycle by 1 if
neither scheduler has a
warp that can be issued.
One Eligible Warp – This counter increments
each cycle by 1 if only one of the two schedulers has a warp that can
KEPLER UPDATE: On Kepler the counters are per scheduler so the One Eligible Warp means that the warp scheduler could issue an instruction. On Fermi there is a single counter for both schedulers so on Fermi you want One Eligible Warp counter to be as small as possible.
Warp Issue Holes – This counter increments each cycle by
the number of active warps that are not eligible. This is the same as
Active Warps minus Eligible Warps.
Long Warp Issue Holes – This
counter increment each cycle by the number of active warps that have
not been eligible to issue an instruction for more than 32 clock
cycles. Long holes indicate that warps are stalled on long latency
reasons such as barriers and memory operations.
Issue Stall Reasons –
Each cycle each ineligible warp will increment one of the issue stall
reason counters. The sum of all issue stall reason counters is equal
to warp issue holes. A ineligible warp will increment the Instruction Fetch
stall reason if the next assembly instruction has not yet been
fetched. Execution Dependency stall reason if an input dependency is
not yet available. This can be reduced by increasing the number of
independent instructions. Data Requests stall reasons if the request
cannot currently be made as the required resources are not available,
or are fully utilized, or too many operations of that type are already
outstanding. In case data requests make up a large portion of the
stall reasons, you should also run the memory experiments to determine
if you can optimize existing transactions per request or if you need
to revisit your algorithm. Texture stall reason if the texture
sub-system is already fully utilized and currently not able to accept
further operations. Synchronization stall reason if the warp is
blocked at a __syncthreads(). If this reason is large and the kernel
execution configuration is limited to a small number of blocks then
consider dividing the kernel grid into more thread blocks.
Visual Profiler 5.0
The Visual Profiler does not have counters that address your question. Until the counters are added you can use the following counters:
The target and max IPCs for compute capabilities are:
Compute Target Max
Capability IPC IPC
2.0 1.7 2.0
2.x 2.3 4.0
3.x 4.4 7.0
The target IPC is for ALU limited computation. The target IPC for memory bound kernels will be less. For compute capability 2.1 devices and higher it is harder to use IPC as each warp scheduler can dual-issue.