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Cells is a mature, stable extension to CLOS[impl] allowing one to create classes
whose instances can have slot values determined by instance-specific formulas.
If you are like me and hate to read, try the slides from my ILC 2003 Talk.
In a text editor application we might have (condensed):
(make-instance 'menu-item
:label "Cut"
:enabled (c? (bwhen (f (focus *window*))
(and (typep f 'text-widget)
(selection-range f)))))
Translated, the enabled state of the Cut menu item follows
whether or not the user is focused on a text-edit widget and
whether they have in fact selected a range of text.
Meanwhile, the selection-range rule might be:
(let (start)
(c? (if (mouse-down? .w.)
(bwhen (c (mouse-pos-to-char self (mouse-pos .w.)))
(if start
(list start c)
(setf start c)))
(setf start nil))))
Now the only imperative code needed is some glue reading the OS event loop
converting raw mouse down and mouse move events into window (the .w. symbol-macro)
attributes such as mouse-down? and mouse-pos. The desired functionality is achieved
by declarative rules which (like selection-range above) are entirely responsible for
deciding the selection range.
A final trick comes from slot observers. Suppose we are thinly wrapping a C GUI and need to
do something in the C library to actually make menu items available or not.
It might look something like this:
(defobserver enabled ((self menu-item) new-value old-value old-value-bound?)
(menu-item-set (c-ptr self) (if new-value 1 0)))
ie, Some model attributes must be propagated outside the model as they change, and observers
are callbacks we can provide to handle change.
As a child I watched my father toil at home for hours over paper
spreadsheets with pencil and slide rule. After he changed one value,
he had to propagate that change to other cells by first remembering
which other ones included the changed cell in their computation.
Then he had to do the calculations for those, erase, enter…
and then repeat that process to propagate those changes in a
cascade across the paper.
VisiCalc let my father take the formula he had in mind and
put it into (declare it to) the electronic spreadsheet. Then VisiCalc
could do the tedious work: recalculating, knowing what to recalculate,
and knowing in what order to recalculate.
Cells do for programmers what electronic spreadsheets did for my father.
Without Cells, CLOS slots are like cells of a paper spreadsheet.
A single key-down event can cause a cascade of change throughout an
application. The programmer has to arrange for it all to happen,
all in the right order: delete any selected text, insert
the new character, re-wrap the text, update the undo mechanism, revisit
the menu statuses (“Cut” is no longer enabled), update the scroll bars,
possibly scroll the window, flag the file as unsaved…
Here is a real-world case study:
The last company I worked with made a product that was a control unit
for some mechanical devices, presenting both sensor readings coming in
from those devices and an interface to program the devices. Consider
it like a very sophisticated microwave oven, perhaps with a
temperature probe.The UI code was a frighteningly complex rat’s nest. Input data
arriving from the sensors changed certain state values, which caused
the display to update, but the system state also changed, and rules
had to be evaluated, the outcome of which might be tuning to the
running job or warning messages presented to the user, and in the
meantime the user may be adjusting the running job. I’m sure there are
even more interactions I’m leaving out.There was no “large idea” in this code to organize these dependencies
or orchestrate the data flow. The individual facilities were
well-formed enough: “message” input and output, GUI widgets and forms,
real-world entities modeled as entities in the code. However, the
connections between these things were ad-hoc and not formalized. Every
change to the system would provoke defects, and the failure usually
involved not propagating some event, propagating it at the wrong time,
or propagating it to the wrong recipients."
Steven Harris, on comp.lang.lisp
What Mr. Harris describes is what Fred Brooks [bullet] said was an essential property of software development, meaning by essential that there was no way around it, and thus his prediction that a software silver bullet was in principle impossible.
Which brings us to Cells. See also [axiom] Phillip Eby’s axiomatic definition developed in support of Ryan Forseth’s PyCells SoC project. Mr. Eby was inspired by his involvement to develop Trellis, his own Cells work-alike library for Python.
Classes, some of whose slots may be mediated by Cells, are defined by DEFMODEL, which is exactly
like DEFCLASS but adds support for two slot definition options, :cell and :unchanged-if. Classes
defined by DEFMODEL can inherit from normal CLOS classes.
:cell {nil | t | :ephemeral}
:cell is optional. The default is “:cell t”, meaning the Cells engine will manage the slot to give
it the spreadsheet-like characteristics. Specifying NIL signifies that this slot is entirely
outside any handling by the Cells engine; it is just a plain CLOS slot.
This next bit will not make sense until we have explained propagation of state change, but
specifying :ephemeral causes the Cells engine to reset the apparent slot
value to NIL immediately and only after fully propagating any value assumed by the slot, either
by assignment to an input Cell (the vastly more common case) or by a rule calculation.
Ephemeral cells are necessary to correctly model events in the otherwise steady-state
spreadsheet paradigm.
:unchanged-if
Specifying :unchanged-if is optional. [Come to think of it, it should be an error to specify
both :cell nil and :unchanged-if.] If specified, the named function is a predicate
of two arguments, the new and old value in that order. The predicate determines if a subsequent
slot value (either computed or assigned to an input) is unchanged in the sense that no propagation
is necessary, either to dependent ruled cells or (getting ahead of ourselves again) “on change” observers.
The default unchanged test is EQL.
The Cells library allows the programmer to specify at make-instance time that a Cell
slot of an instance be mediated for the life of that instance by one of:
- a so-called “input” Cell;
- a “ruled” Cell; or
- no Cell at all.
Note that different instances of the same class may do different things Cells-wise with the same slot.
One label widget may have a fixed width of 42 and text “Hi, Mom!”, where another might have
an input Cell mediating the text (so edit logic can assign new values as the user types) and a
rule mediating the width so the widget can have a minimum width of 42(so it does not disappear altogether)
yet grow based on text length and relevant font metrics to always leave room for one more character
(if the GUI design calls for that).
To summarize, the class specification supplied with DEFMODEL specifies whether a slot can /ever/
be managed by the Cells engine. For those that can, at and only at instance initialization time
different instances can have different Cell types and rules specified to mediate the same slot.
A slot mediated by an input Cell may be assigned new values at runtime. These are how Cell-based models
get data from the world outside the model — it cannot be rules all the way down. Typically, these
input assignements are made by code polling OS events via some GetNextEvent API call, or by callbacks
registered with an event system such as win32 WindowProc functions. Other code may poll sockets or
serial inputs from an external device.
Ruled Cells come with an instance-specific rule in the form of an anonymous function of two variables,
the instance owning the slot and the prior value (if any) computed by the rule. These rules consist of
arbitrarily complex Common Lisp code, and are invoked immediately after instance initialization (but see
the next bit on lazy cells).
When a rule runs, any dynamic read (either expressly in the rule source or during the execution of
some function invoked by the rule) of a slot of any instance mediated by a Cell of any type establishes a
runtime dependency of the ruled cell on the slot of the instance that was read. Note then that thanks
to code branching, dependencies can vary after every rule invocation.
Laziness is cell-specific, applies only to ruled cells, and comes in four varieties:
- once-asked: evaluated and “observed” on initialization, but not re-evaluated
immediately if dependencies change, rather only when read by application code. - until-asked: this does not get evaluated/observed until read by application code, but then it becomes
un-lazy, eagerly reevaluated as soon as any dependency changes (not waiting until asked). - always: not evaluated/observed until read, and not reevaluated after a dependency changes until read.
When application code assigns a new value to an input Cell (a quick way of saying an instance slot mediated by
an input Cell) — typically by code polling OS events or a socket or an input device — a cascade of recalculation
ensues to bring direct and indirect ruled dependents current with the new value assigned to the input Cell.
Because of all that, it is an error to assign a new value to a slot of an instance not mediated by any Cell.
The Cells engine can do a handy optimization by treating such slots as constants and not creating dependencies when ruled
Cells read these. But then we cannot let these Cells vary and still guarantee data integrity, because
we no longer know who else to update in light of such variation. The optimization, by the way, extends to
eliminating ruled Cells which, after any computation, end up not depending on any other cell.
Again, note that this is different from specifying “:cell nil” for some slot. Here, the Cells engine
has been told to manage some slot, but for some instance the slot has been authored to bear some value
for the lifetime of that instance.
To allow the emergent animated data model to operate usefully on the world outside the model—if only to
update the screen—programmers may specify so-called observer callbacks dispatched according to: slot name,
instance, new value, old value, and whether the old value actually existed (false only on the first go).
Observers are inherited according to the rules of CLOS class inheritance. If multiple primary observer
methods apply because of inheritance, they all get run, most specific last.
ie, observers are a GF with PROGN method combination.
Observers get called in two circumstances: as part of Model object initialization, in a processing step
just after CLOS instance initialization, and when a slot changes value. Any observer of a Cell slot
is guaranteed to be called at least once during intialization even if a cell slot is bound to a constant
or if it is an input or ruled Cell that never changes value.
It is legal for observer code to assign to input Cells, but (a) special syntax is required to defer execution
until the observed state change has fully propagated; and (b) doing so compromises the declarative
quality of an application — one can no longer look to one rule to see how a slot (in this case the
input slot being assigned by the observer) gets its value. A reasonable usage might be one with
a cycle, where changing slot A requires a change to slot B, and changing slot B requires a change to
slot A, such as the scroll thumb position and the amount a document has been scrolled.
Finally, to make it possible for such a declarative model to talk intelligibly to imperative systems such as Tcl/Tk which sometimes requires a precise sequence of commands for something to work at all, a mechanism exists by which client code can (a) queue tasks for execution after a data change has fully propagated and (b) process those tasks with a client-supplied handler. Tasks are queued with arbitrary keying data which can be used by the handler to sort or compress the queued tasks.
When application code assigns to some input cell X, the Cells engine guarantees:
- recomputation exactly once of all and only state affected by the change to X, directly or indirectly through some intermediate datapoint. note that if A depends on B, and B depends on X, when B gets recalculated it may come up with the same value as before. In this case A is not considered to have been affected by the change to X and will not be recomputed.
- recomputations, when they read other datapoints, must see only values current with the new value of X. Example: if A depends on B and X, and B depends on X, when X changes and A reads B and X to compute a new value, B must return a value recomputed from the new value of X.
- similarly, client observer callbacks must see only values current with the new value of X; and
- a corollary: should a client observer SETF a datapoint Y, all the above must happen with values current with not just X, but also with the value of Y /prior/ to the change to Y.
- Deferred “client” code must see only values current with X and not any values current with some subsequent change to Y queued by an observer
Program state guaranteed to be self-consistent, without programmer effort.Dependencies are identified by the engine, and change propagation happens automatically.
Greater object re-use. Slots of instances can be authored with rules, not just literal values. In a sense,
we get greater reuse by allowing instances to override slot derivations instance by instance. But not slot
expressions, which are still class-oriented. By this I mean the observers expressing changes in value are
dispatched by the class of the instance and so are not instance-specific. (Such a thing has been
suggested, however.) Another strong bit of class-orientation comes from the fact that code reading
slot X of some instance Y obviously does so without knowing how the returned value was derived. It knows
only that the slot is named X, and will do things with that value assuming only that it has the
X attribute of the instance Y. So again: the derivation of a slot value is potentially instance-oriented
under Cells, but its expression or manifestation is still class-oriented.
Natural decomposition of overall application complexity into so many simple rules and slot observers. Let’s return for a moment to VisiCalc and its descendants. In even the most complex financial spreadsheet model, no one cell rule accesses more than a relatively few other spreadsheet cells (counting a row or column range as one reference). Yet the complex model emerges. All the work of tracking dependencies is handled by the spreadsheet software, which requires no special declaration by the modeller. They simply write the Cell rule. In writing the rule, they are concerned only with the derivation of one datapoint from a population of other datapoints. No effort goes into arranging for the rule to get run at the right time, and certainly no energy is spent worrying about what other cells might be using the authored cell. That cell has certain semantics — “account balance”, perhaps — and the modeller need only worry about writing a correct, static computation of those semantics. Same with Cells. The only difference is that VisiCalc has one “observer” requirement for all cells: update the screen. In Cells applications, a significant amount of application functionality — indeed, all its outputs — end up in cell observers. But as discussed above, this additional burden falls only on the class designer when they decide to add a slot to a class. As instances are created and different rules specified for different slots to achieve custom behavior, the effort is the same as for the VisiCalc user.
Everything above could describe one instance of one class defined by DEFMODEL. A real application has
multiple instances of multiple classes. So…
- cells can depend on other cells from any other instance. Since a rule gets passed only “self”, Cell users
need something like the Family class included with the Cells package effectively to turn a collection of
instances into a network searchable by name or type. - The overall model population must be maintainable by Cell slots such as the “kids” slot of the Family class. The burden here is on the Cells engine to allow one cell of one child to ask for the value of a cell of another child and vice versa (with different Cells), when both children are the product of the same rule, or different rules when “cousins” are exchanging information. So we must gracefully traverse the parent/kids tree dispatching kids rules just in time to produce the other instance sought.
- kid-slotting: used almost exclusively so far for orderly GUI layout, a parent must be able to specify rules for specific slots of kids. Example: a “stack” class wants to provide rules for child geometry specifying left, right, or centered alignment and vertical stacking (with optional spacing) one below the other. The idea is that we want to author classes of what might be GUI subcomponents without worrying
about how they will be arranged in some container. - finalization: when an instance appears in the “old kids” but not in the “new kids”, a Cells engine may need to arrange for all Cells to “unsubscribe” from their dependents. Cells takes care of that if one calls “not-to-be” on an instance.
Any application that must maintain an interesting, long-lived data model incorporating a stream of unpredictable data. Two examples: any GUI application and a RoboCup soccer client.
An application needing to shadow data between two systems. Examples: a Lisp GUI imlemented by thinly wrapping a C GUI library, where Lisp-land activity must be propagated to the C GUI, and C GUI events must propagate to Lisp-land. See the qooxlisp, Cells-Gtk, or Celtk projects. Also, a persistent CLOS implementation that must echo CLOS instance data into, say, SQL tables.
Functional reactive programming:
This looks to be the most active, current, and vibrant subset of folks working on this sort of stuff.
Links:
FlapJax (FRP-powered web apps) http://www.flapjax-lang.org/
http://lambda-the-ultimate.org/node/1771
http://www.haskell.org/frp/
FrTime (scheme FRP implementation, no great links) http://pre.plt-scheme.org/plt/collects/frtime/doc.txt
Adobe Adam, originally developed only to manage complex GUIs. [Adam]
COSI, a class-based Cells-alike used at STSCI in software used to
schedule Hubble telescope viewing time. [COSI]
Garnet’s KR: http://www.cs.cmu.edu/~garnet/
Also written in Lisp. Cells looks much like KR, though Cells was
developed in ignorance of KR (or any other prior art). KR has
an astonishing number of backdoors to its constraint
engine, none of which have turned out to be necessary for Cells.
The entire constraint programming field, beginning I guess with Guy Steele’s
PhD Thesis in which he develops a constraint programming language or two:
http://portal.acm.org/citation.cfm?id=889490&dl=ACM&coll=ACM
http://www.cs.utk.edu/~bvz/quickplan.html
Flow-based programming, developed by J. Paul Morrison at IBM, 1971.
http://en.wikipedia.org/wiki/Flow-based_programming
Sutherland, I. Sketchpad: A Man Machine Graphical Communication System. PhD thesis, MIT, 1963.
Steele himself cites Sketchpad as inexplicably unappreciated prior
art to his Constraints system:
See also:
The spreadsheet paradigm: http://www.cs.utk.edu/~bvz/active-value-spreadsheet.html
The dataflow paradigm: http://en.wikipedia.org/wiki/Dataflow
Frame-based programming
Definitive-programming
Cells provides the plumbing for data dependency management which every
non-trivial program must have; a developer using Cells can focus on
computing program state and reacting to state changes, leaving Cells to worry about
how that state is propagated. Cells does this by enabling a declarative
mechanism built via an extension to CLOS, and hence achieves its goal in a way
that meshes well with with typical Common Lisp programming style.
Jack Unrue, comp.lang.lisp
Kenny Tilton has been talking about his Cells implementation on comp.lang.lisp for some time but I’ve only just had a look at it over the past few evenings. It’s actually pretty neat. Kenny describes Cells as, conceptually, analogous to a spreadsheet cell (e.g. — something in which you can put a value or a formula and have it updated automatically based on changes in other “cell” values). Another way of saying this might be that Cells allows you to define classes whose slots can be dynamically (and automatically) updated and for which standard observers can be defined that react to changes in those slots.
Bill Clementson, http://bc.tech.coop/blog/030911.html
If you are at all familiar with developing moderately complex software that is operated through a GUI, then you have probably learned this lesson: Keeping what is presented through the GUI in-sync with what the user is allowed to do, and in-sync with the computational state of the program is often tedious, complicated work. Cells-GTK helps with these tasks by providing an abstraction over the details; each of the tasks just listed can be controlled by (a) formula that specify the value of attributes of graphic features in the part-subpart declaration (that declaration is called ‘defpart’ in cells-gtk); and, (b) formula that specify the value of CLOS slots.“What is Cells?”, Cells-GTk FAQ, http://common-lisp.net/project/cells-gtk/faq.html#q2
What I discovered is quite cool. The Cells system automatically discovers dynamic dependencies, without having to explicitly specify that X depends on Y, as long as X and Y are both implemented using cell objects. The system knows when you are computing a value for X, and registers the fact that Y was read during this computation, thus allowing it to automatically invalidate the X calculation if Y changes….Aside from the automatic dependency detection, the cells system has another trick that is able to significantly reduce the complexity of event cascades, similar to what I was trying (but failing) to do using the “scheduled thread” concept in peak.events. Specifically, the cells system understands how to make event-based updates orderly and deterministic, in a way that peak.events cannot. It effectively divides time into “propagation” and “non-propagation” states. Instead of simply making callbacks whenever a computed value changes, the system makes orderly updates by queueing invalidated cells for updating. Also, if you write code that sets a new value imperatively (as opposed to it being pulled declaratively), the actual set operation is deferred until all computed cells are up-to-date with the current state of the universe.
— Phillip Eby, PyCells and peak.events,
http://www.eby-sarna.com/pipermail/peak/2006-May/002545.html
[Adam] “Adam is a modeling engine and declarative language for describing constraints and
relationships on a collection of values, typically the parameters to an
application command. When bound to a human interface (HI) Adam provides
the logic that controls the HI behavior. Adam is similar in concept to a spreadsheet
or a forms manager. Values are set and dependent values are recalculated.
Adam provides facilities to resolve interrelated dependencies and to track
those dependencies, beyond what a spreadsheet provides.”
http://opensource.adobe.com/group__asl__overview.html#asl_overview_intro_to_adam_and_eve
________
[bullet] This resolves a problem Fred Brooks identified in 1987: ""The essence of a software
entity is a construct of interlocking concepts: data sets, relationships among data items, algorithms,
and invocations of functions… Software systems have orders-of-magnitude more states than
computers do…a scaling-up of a software entity is not merely a repetition of the same elements
in larger sizes; it is necessarily an increase in the number of different elements. In most cases,
the elements interact with each other in some nonlinear fashion, and the complexity of the whole
increases much more than linearly."
— http://www.virtualschool.edu/mon/SoftwareEngineering/BrooksNoSilverBullet.html
______
[COSI] "The Constraint Sequencing Infrastructure (COSI) is an extension to
the Common Lisp Object System (*(CLOS)) which supports a constraint
based object-oriented programming model. …..
“A constraint is a specialized method which will be automatically
re-run by the COSI infrastructure whenever any of its input values
change. Input values are any of the object attributes that are
accessed by the constraint, and which are therefore assumed to
alter the processing within the constraint.
“Whenever a state change occurs those constraints which depend upon
that state are added to a propagation queue. When the system is
queried a propagation cycle runs ensuring that the state of the
system is consistent with all constraints prior to returning a value.”
— http://www.cliki.net/ACL2/COSI?source
______
[impl] The Cells library as it stands is all about doing interesting things
with slots of CLOS instances, but Cells is not only about CLOS or even Lisp.
One Cells user is known to have mediated a global variable with a Cell, some work
was done on having slots of DEFSTRUCTs mediated by Cells, and ports to C++, Java, and
Python have been explored.
[axiom] Phillip Eby’s axiomatic specification of Cells:
Data Pulse Axioms
=====Overview: updates must be synchronous (all changed cells are updated at
once), consistent (no cell rule sees out of date values), and minimal (only
necessary rules run).1. Global Update Counter:
There is a global update counter. (Guarantees that there is a
globally-consistent notion of the “time” at which updates occur.)2. Per-Cell “As Of” Value:
Every cell has a “current-as-of” update count, that is initialized with
a value that is less than the global update count will ever be.3. Out-of-dateness:
A cell is out of date if its update count is lower than the update
count of any of the cells it depends on.4. Out-of-date Before:
When a rule-driven cell’s value is queried, its rule is only run if the
cell is out of date; otherwise a cached previous value is
returned. (Guarantees that a rule is not run unless its dependencies have
changed since the last time the rule was run.)5. Up-to-date After:
Once a cell’s rule is run (or its value is changed, if it is an input
cell), its update count must be equal to the global update
count. (Guarantees that a rule cannot run more than once per update.)6. Inputs Move The System Forward
When an input cell changes, it increments the global update count and
stores the new value in its own update count.Dependency Discovery Axioms
=======Overview: cells automatically notice when other cells depend on them, then
notify them at most once if there is a change.1. Thread-local “current rule cell”:
There is a thread-local variable that always contains the cell whose
rule is currently being evaluated in the corresponding thread. This
variable can be empty (e.g. None).2. “Currentness” Maintenance:
While a cell rule’s is being run, the variable described in #1 must be
set to point to the cell whose rule is being run. When the rule is
finished, the variable must be restored to whatever value it had before the
rule began. (Guarantees that cells will be able to tell who is asking for
their values.)3. Dependency Creation:
When a cell is read, it adds the “currently-being evaluated” cell as a
listener that it will notify of changes.4. Dependency Creation Order:
New listeners are added only after the cell being read has brought
itself up-to-date, and notified any previous listeners of the
change. (Ensures that the listening cell does not receive redundant
notification if the listened-to cell has to be brought up-to-date first.)5. Dependency Minimalism:
A listener should only be added if it does not already present in the
cell’s listener collection. (This isn’t strictly mandatory, the system
behavior will be correct but inefficient if this requirement isn’t met.)6. Dependency Removal:
Just before a cell’s rule is run, it must cease to be a listener for
any other cells. (Guarantees that a dependency from a previous update
cannot trigger an unnecessary repeated calculation.)7. Dependency Notification
Whenever a cell’s value changes (due to a rule change or input change),
it must notify all of its listeners that it has changed, in such a way that
none of the listeners are asked to recalculate their value until all of
the listeners have first been notified of the change. (This guarantees
that inconsistent views cannot occur.)7a. Deferred Recalculation
The recalculation of listeners (not the notification of the listeners’
out-of-dateness) must be deferred if a cell’s value is currently being
calculated. As soon as there are no cells being calculated, the deferred
recalculations must occur. (This guarantees that in the absence of
circular dependencies, no cell can ask for a value that’s in the process of
being calculated.)8. One-Time Notification Only
A cell’s listeners are removed from its listener collection as soon as
they have been notified. In particular, the cell’s collection of listeners
must be cleared before any of the listeners are asked to recalculate
themselves. (This guarantees that listeners reinstated as a side effect of
recalculation will not get a duplicate notification in the current update,
or miss a notification in a future update.)9. Conversion to Constant
If a cell’s rule is run and no dependencies were created, the cell must
become a “constant” cell, and do no further listener additions or
notification, once any necessary notifications to existing listeners are
completed. (That is, if the rule’s run changed the cell’s value, it must
notify its existing listeners, but then the listener collection must be
cleared — again, in addition to the clearing described in #8.)10. No Changes During Notification:
It is an error to change an input cell’s value while change
notifications are taking place.11. Weak Notification
Automatically created inter-cell links must not inhibit garbage
collection of either cell. (Technically optional, but very easy to do.)