.. _cppcablecell-probesample: Cable cell probing and sampling =============================== .. _cppcablecell-probes: Cable cell probes ----------------- Various properties of a cable cell can be sampled. They fall into two classes: scalar probes are associated with a single real value, such as a membrane voltage or mechanism state value at a particular location; vector probes return multiple values corresponding to a quantity sampled at a set of points on the cell. The sample data associated with a cable cell probe will either be a ``double`` for scalar probes, or a ``cable_sample_range`` describing a half-open range of ``double`` values: .. code:: using cable_sample_range = std::pair The probe metadata passed to the sampler will be a const pointer to: * ``mlocation`` for most scalar probes; * ``cable_probe_point_info`` for point mechanism state queries; * ``mcable_list`` for most vector queries; * ``std::vector`` for cell-wide point mechanism state queries. The type ``cable_probe_point_info`` holds metadata for a single target on a cell: .. code:: struct cable_probe_point_info { // Target number of point process instance on cell. cell_lid_type target; // Number of combined instances at this site. unsigned multiplicity; // Point on cell morphology where instance is placed. mlocation loc; }; Note that the ``multiplicity`` will always be 1 if synapse coalescing is disabled. Cable cell probes that contingently do not correspond to a valid measurable quantity are ignored: samplers attached to them will receive no values. Mechanism state queries, however will throw a ``cable_cell_error`` exception at simulation initialization if the requested state variable does not exist on the mechanism. Cable cell probeset addresses that are described by a ``locset`` may generate more than one concrete probe: there will be one per location in the locset that is satisfiable. Sampler callback functions can distinguish between different probes with the same address and id by examining their index and/or probe-specific metadata found in the ``probe_metadata`` parameter. Membrane voltage ^^^^^^^^^^^^^^^^ .. code:: struct cable_probe_membrane_voltage { locset locations; }; Queries cell membrane potential at each site in ``locations``. * Sample value: ``double``. Membrane potential in millivolts. * Metadata: ``mlocation``. Location of probe. .. code:: struct cable_probe_membrane_voltage_cell {}; Queries cell membrane potential across the whole cell. * Sample value: ``cable_sample_range``. Each value is the average membrane potential in millivolts across an unbranched component of the cell, as determined by the discretisation. * Metadata: ``mcable_list``. Each cable in the cable list describes the unbranched component for the corresponding sample value. Axial current ^^^^^^^^^^^^^ .. code:: struct cable_probe_axial_current { locset locations; }; Estimate intracellular current at each site in ``locations``, in the distal direction. * Sample value: ``double``. Current in nanoamperes. * Metadata: ``mlocation``. Location as of probe. Transmembrane current ^^^^^^^^^^^^^^^^^^^^^ .. code:: struct cable_probe_ion_current_density { locset locations; std::string ion; }; Membrane current density attributed to a particular ion at each site in ``locations``. * Sample value: ``double``. Current density in amperes per square metre. * Metadata: ``mlocation``. Location of probe. .. code:: struct cable_probe_ion_current_cell { std::string ion; }; Membrane current attributed to a particular ion across components of the cell. * Sample value: ``cable_sample_range``. Each value is the current in nanoamperes across an unbranched component of the cell, as determined by the discretisation. * Metadata: ``mcable_list``. Each cable in the cable list describes the unbranched component for the corresponding sample value. .. code:: struct cable_probe_total_ion_current_density { locset locations; }; Membrane current density at given locations _excluding_ capacitive currents. * Sample value: ``double``. Current density in amperes per square metre. * Metadata: ``mlocation``. Location of probe. .. code:: struct cable_probe_total_ion_current_cell {}; Membrane current _excluding_ capacitive currents and stimuli across components of the cell. * Sample value: ``cable_sample_range``. Each value is the current in nanoamperes across an unbranched component of the cell, as determined by the discretisation. * Metadata: ``mcable_list``. Each cable in the cable list describes the unbranched component for the corresponding sample value. .. code:: struct cable_probe_total_current_cell {}; Total membrane current excluding current stimuli across components of the cell. * Sample value: ``cable_sample_range``. Each value is the current in nanoamperes across an unbranched component of the cell, as determined by the discretisation. * Metadata: ``mcable_list``. Each cable in the cable list describes the unbranched component for the corresponding sample value. .. code:: struct cable_probe_stimulus_current_cell {}; Total stimulus currents applied across components of the cell. * Sample value: ``cable_sample_range``. Each value is the current in nanoamperes across an unbranched component of the cell, as determined by the discretisation. Components of CVs where no stimulus is present will report a corresponding stimulus value of zero. * Metadata: ``mcable_list``. Each cable in the cable list describes the unbranched component for the corresponding sample value. Ion concentration ^^^^^^^^^^^^^^^^^ .. code:: struct cable_probe_ion_int_concentration { locset locations; std::string ion; }; Ionic internal concentration of ion at each site in ``locations``. * Sample value: ``double``. Ion concentration in millimoles per litre. * Metadata: ``mlocation``. Location of probe. .. code:: struct cable_probe_ion_int_concentration_cell { std::string ion; }; Ionic external concentration of ion across components of the cell. * Sample value: ``cable_sample_range``. Each value is the concentration in millimoles per lire across an unbranched component of the cell, as determined by the discretisation. * Metadata: ``mcable_list``. Each cable in the cable list describes the unbranched component for the corresponding sample value. .. code:: struct cable_probe_ion_ext_concentration { mlocation location; std::string ion; }; Ionic external concentration of ion at each site in ``locations``. * Sample value: ``double``. Ion concentration in millimoles per litre. * Metadata: ``mlocation``. Location of probe. .. code:: struct cable_probe_ion_ext_concentration_cell { std::string ion; }; Ionic external concentration of ion across components of the cell. * Sample value: ``cable_sample_range``. Each value is the concentration in millimoles per lire across an unbranched component of the cell, as determined by the discretisation. * Metadata: ``mcable_list``. Each cable in the cable list describes the unbranched component for the corresponding sample value. Ionic diffusion concrentration. .. code:: struct cable_probe_ion_diff_concentration { locset locations; std::string ion; }; Diffusive ionic concentration of the given ``ion`` at the sites specified by ``locations``. .. code:: struct cable_probe_ion_diff_concentration_cell { std::string ion; }; Ionic diffusion concrentration attributed to a particular ``ion`` across CVs of the cell. Ionic reversal potential. .. code:: struct cable_probe_ion_reversal_potential { locset locations; std::string ion; }; Reversal potential of the given ``ion`` at the sites specified by ``locations``. .. code:: struct cable_probe_ion_reversal_potential_cell { std::string ion; }; Reversal potential attributed to a particular ``ion`` across CVs of the cell. Mechanism state ^^^^^^^^^^^^^^^ .. code:: struct cable_probe_density_state { locset locations; std::string mechanism; std::string state; }; Value of state variable in a density mechanism in each site in ``locations``. If the mechanism is not defined at a particular site, that site is ignored. * Sample value: ``double``. State variable value. * Metadata: ``mlocation``. Location as given in the probeset address. .. code:: struct cable_probe_density_state_cell { std::string mechanism; std::string state; }; Value of state variable in a density mechanism across components of the cell. * Sample value: ``cable_sample_range``. State variable values from the mechanism across unbranched components of the cell, as determined by the discretisation and mechanism extent. * Metadata: ``mcable_list``. Each cable in the cable list describes the unbranched component for the corresponding sample value. .. code:: struct cable_probe_point_state { cell_lid_type target; std::string mechanism; std::string state; }; Value of state variable in a point mechanism associated with the given target. If the mechanism is not associated with this target, the probe is ignored. * Sample value: ``double``. State variable value. * Metadata: ``cable_probe_point_info``. Target number, multiplicity and location. .. code:: struct cable_probe_point_state_cell { std::string mechanism; std::string state; }; Value of state variable in a point mechanism for each of the targets in the cell with which it is associated. * Sample value: ``cable_sample_range``. State variable values at each associated target. * Metadata: ``std::vector``. Target metadata for each associated target. .. _sampling_api: Sampling API ------------ The new API replaces the flexible but irreducibly inefficient scheme where the next sample time for a sampling was determined by the return value of the sampler callback. Definitions ^^^^^^^^^^^^^^^^^^^^^^^^^^^ probe A location or component of a cell that is available for monitoring. sample A record of data corresponding to the value at a specific *probe* at a specific time. sampler A function or function object that receives a sequence of *sample* records. schedule A function or function object that, given a time interval, returns a list of sample times within that interval. Probes ^^^^^^^^^^^^^^^^^^^^^^^^^^^ Probes are specified in the recipe objects that are used to initialize a simulation; the specification of the item or value that is subjected to a probe will be specific to a particular cell type. .. container:: api-code .. code-block:: cpp struct probe_info { cell_tag_type tag; // opaque key, returned in sample record any address; // cell-type specific location info template probe_info(X&& x, nullptr_t) = delete; template probe_info(X&& x, const cell_tag_type& tag): tag(tag), address(std::forward(x)) {} }; std::vector recipe::get_probes(cell_gid_type gid); The ``tag`` field identifies the probe locally on this global id ``gid``, e.g. it is used in conjunction to attach samplers, as ``cell_address_type{gid, tag}``. Probeset addresses are decoupled from the cell descriptions themselves — this allows a recipe implementation to construct probes independently of the cells themselves. It is the responsibility of a cell group implementation to parse the probeset address objects wrapped in the ``any address`` field, thus the order of probes returned is important. One probeset address may describe more than one concrete probe, depending upon the interpretation of the probeset address by the cell group. In this instance, each of the concrete probes will be associated with the same probe-id. Samplers can distinguish between different probes with the same id by their probe index (see below). Samplers and sample records ^^^^^^^^^^^^^^^^^^^^^^^^^^^ Data collected from probes (according to a schedule described below) will be passed to a sampler function or function object: .. container:: api-code .. code-block:: cpp struct probe_metadata { cell_address_type id; // probeset id unsigned index; // index of probe source within those supplied by probeset id util::any_ptr meta; // probe-specific metadata }; using sampler_function = std::function; where the parameters are respectively the probe metadata, the number of samples, and finally a pointer to the sequence of sample records. The ``probeset_id``, identifies the probe by its probe-id (see above). The ``index`` identifies which of the possibly multiple probes associated with the probe-id is the source of the samples. The ``any_ptr`` value in the metadata points to const probe-specific metadata; the type of the metadata will depend upon the probeset address specified in the ``probe_info`` provided by the recipe. One ``sample_record`` struct contains one sample of the probe data at a given simulation time point: .. container:: api-code .. code-block:: cpp struct sample_record { time_type time; // simulation time of sample any_ptr data; // sample data }; The ``data`` field points to the sample data, wrapped in ``any_ptr`` for type-checked access. The exact representation will depend on the nature of the object that is being probed, but it should depend only on the cell type and probeset address. The data pointed to by ``data``, and the sample records themselves, are only guaranteed to be valid for the duration of the call to the sampler function. A simple sampler implementation for ``double`` data, assuming one probe per probeset id, might be as follows: .. container:: example-code .. code-block:: cpp using sample_data = std::map>>; struct scalar_sampler { sample_data& samples; explicit scalar_sample(sample_data& samples): samples(samples) {} void operator()(probe_metadata pm, size_t n, const sample_record* records) { for (size_t i=0; i(rec.data); assert(data); samples[pm.id].emplace_back(rec.time, *data); } } }; The use of ``any_ptr`` allows type-checked access to the sample data, which may differ in type from probe to probe. Model and cell group interface ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ Polling rates and sampler functions are set through the ``simulation`` interface, after construction from a recipe. .. container:: api-code .. code-block:: cpp using sampler_association_handle = std::size_t; using cell_member_predicate = std::function; sampler_association_handle simulation::add_sampler( cell_member_predicate probeset_ids, schedule sched, sampler_function fn) void simulation::remove_sampler(sampler_association_handle); void simulation::remove_all_samplers(); Multiple samplers can then be associated with the same probe locations. The handle returned is only used for managing the lifetime of the association. The ``cell_member_predicate`` parameter defines the set of probeset ids in terms of a membership test. We provide a few helper functions are provided for making ``cell_member_predicate`` objects: .. container:: api-code .. code-block:: cpp // Match all probeset ids. cell_member_predicate all_probes = [](const cell_address_type& pid) { return true; }; // Match just one probeset id. cell_member_predicate one_probe(const cell_address_type& pid) { return [pid](const auto& x) { return pid==x; }; } // Match all probes on a given ``gid``. cell_member_predicate one_gid(const cell_gid_type& gid) { return [gid](const auto& x) { return gid==x.gid; }; } // Match all probes with a given ``tag``. cell_member_predicate one_tag(const cell_tag_type& tag) { return [tag](const auto& x) { return tag==x.tag; }; } The simulation object will pass on the sampler setting request to the cell group that owns the given probeset id. The ``cell_group`` interface will be correspondingly extended: .. container:: api-code .. code-block:: cpp void cell_group::add_sampler(sampler_association_handle h, cell_member_predicate probeset_ids, sample_schedule sched, sampler_function fn); void cell_group::remove_sampler(sampler_association_handle); void cell_group::remove_all_samplers(); Cell groups will invoke the corresponding sampler function directly, and may aggregate multiple samples with the same probeset id in one call to the sampler. Calls to the sampler are synchronous, in the sense that processing of the cell group state does not proceed while the sampler function is being executed, but the times of the samples given to the sampler will typically precede the time corresponding to the current state of the cell group. It should be expected that this difference in time should be no greater the the duration of the integration period (i.e. ``mindelay/2``). Schedules ^^^^^^^^^ Schedules represent a non-negative, monotonically increasing sequence of time points, and are used to specify the sampling schedule in any given association of a sampler function to a set of probes. A ``schedule`` object has two methods: .. container:: api-code .. code-block:: cpp void schedule::reset(); time_event_span events(time_type t0, time_type t1) A ``time_event_span`` is a ``std::pair`` of pointers `const time_type*`, representing a view into an internally maintained collection of generated time values. The ``events(t0, t1)`` method returns a view of monotonically increasing time values in the half-open interval ``[t0, t1)``. Successive calls to ``events`` — without an intervening call to ``reset()`` — must request strictly subsequent intervals. The data represented by the returned ``time_event_span`` view is valid for the lifetime of the ``schedule`` object, and is invalidated by any subsequent call to ``reset()`` or ``events()``. The ``reset()`` method resets the state such that events can be retrieved from again from time zero. A schedule that is reset must then produce the same sequence of time points, that is, it must exhibit repeatable and deterministic behaviour. The ``schedule`` object itself uses type-erasure to wrap any schedule implementation class, which can be any copy--constructible class that provides the methods ``reset()`` and ``events(t0, t1)`` above. Three schedule implementations are provided by the engine: .. container:: api-code .. code-block:: cpp // Schedule at integer multiples of dt: schedule regular_schedule(time_type dt); // Schedule at a predetermined (sorted) sequence of times: template schedule explicit_schedule(const Seq& seq); // Schedule according to Poisson process with lambda = 1/mean_dt template schedule poisson_schedule(time_type mean_dt, const RandomNumberEngine& rng); The ``schedule`` class and its implementations are found in ``schedule.hpp``. Helper classes for probe/sampler management ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ The ``simulation`` and ``cable_cell_group`` classes use classes defined in ``scheduler_map.hpp`` to simplify the management of sampler--probe associations and probe metadata. ``sampler_association_map`` wraps an ``unordered_map`` between sampler association handles and tuples (*schedule*, *sampler*, *probe set*), with thread-safe accessors. Batched sampling in ``cable_cell_group`` ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ The ``fvm_multicell`` implementations for CPU and GPU simulation of multi-compartment cable neurons perform sampling in a batched manner: when their integration is initialized, they take a sequence of ``sample_event`` objects which are used to populate an implementation-specific ``event_stream`` that describes for each cell the sample times and what to sample over the integration interval. When an integration step for a cell covers a sample event on that cell, the sample is satisfied with the value from the cell state at the beginning of the time step, after any postsynaptic spike events have been delivered. It is the responsibility of the ``cable_cell_group::advance()`` method to create the sample events from the entries of its ``sampler_association_map``, and to dispatch the sampled values to the sampler callbacks after the integration is complete. Given an association tuple (*schedule*, *sampler*, *probe set*) where the *schedule* has (non-zero) *n* sample times in the current integration interval, the ``cable_cell_group`` will call the *sampler* callback once for probe in *probe set*, with *n* sample values. .. note:: When the time values returned by a call to a schedule's ``events(t0, t1)`` method do not perfectly coincide with the boundaries of the numerical time step grid, :math:`[t_0, t_0 + dt, t_0 + 2\, dt, \, \cdots \, , t_1)`, the samples will be taken at the closest possible point in time. In particular, any sample times :math:`t_s \in \left( t_i - dt/2,~ t_i + dt/2\right]` are attributed to simulation time step :math:`t_i = t_0 + i\,dt`. LIF cell probing and sampling =============================== Membrane voltage ---------------- .. code:: struct lif_probe_voltage {}; Queries cell membrane potential. * Sample value: ``double``. Membrane potential (mV). * Metadata: none AdEx cell probing and sampling =============================== Membrane voltage ---------------- .. code:: struct adex_probe_voltage {}; Queries cell membrane potential. * Sample value: ``double``. Membrane potential (mV). * Metadata: none Adaption Variable ----------------- .. code:: struct adex_probe_adaption {}; Queries cell adaption variable :math:`w`. * Sample value: ``double``. (nA). * Metadata: none