Call graph addressing library.
Project description
Ptera
Note: This is super alpha. A lot of the features are implemented very inefficiently and the error reporting is not very good. That will be fixed in due time, and then this note will disappear into the mists of git history.
What is Ptera?
Ptera is a way to probe arbitrary variables in arbitrary functions in your program, for instance to plot their values over time, to get the maximum or minimum value during execution.
- Keep your program clean: Queries can be defined outside of your main function, so there is no need to pollute your code with logging or debug code.
- Debug and analyze across scopes: Easily write queries that collect variables at various points in the call stack, or even across different calls. Then, you can analyze them all together.
- Tag variables and functions: Categorize parts of your program to make more general queries.
from ptera import probing, op
def fact(n):
if n <= 1:
return n
else:
return n * fact(n - 1)
with probing("fact(n) as v") as probe:
probe.pipe(op.format("fact({n}) = {v}")).subscribe(print)
fact(3)
# prints fact(1) = 1; fact(2) = 2; fact(3) = 6
probing
Usage: with ptera.probing(selector) as probe: ...
The selector is a specification of which variables in which functions we want to stream through the probe. One of the variables must be the focus of the selector, meaning that the probe is triggered when that variable is set. The focus may be indicated either as f(!x)
or f > x
.
The probe is an instance of rx.Observable. All of the rx
operators should therefore work with ptera's probes (map, reduce, min, max, debounce, etc.)
Example 1: intermediate variables
Ptera is capable of capturing any variable in a function, not just inputs and return values:
def fact2(n):
curr = 1
for i in range(n):
curr = curr * (i + 1)
return curr
with probing("fact2(i, !curr)") as probe:
probe.subscribe(print)
fact2(3)
# {'curr': 1}
# {'curr': 1, 'i': 0}
# {'curr': 2, 'i': 1}
# {'curr': 6, 'i': 2}
The "!" in the selector above means that the focus is curr
. This means it is triggered when curr
is set. This is why the first result does not have a value for i
. You can use the selector fact2(!i, curr)
to focus on i
instead:
with probing("fact2(!i, curr)") as probe:
probe.subscribe(print)
fact2(3)
# {'i': 0, 'curr': 1}
# {'i': 1, 'curr': 1}
# {'i': 2, 'curr': 2}
You can see that the associations are different (curr is 2 when i is 2, whereas it was 6 with the other selector), but this is simply because they are now triggered when i
is set.
Example 2: multiple scopes
A selector may act on several nested scopes in a call graph. For example, the selector f(x) >> g(y) >> h > z
would capture variables x
, y
and z
from the scopes of three different functions, but only when f
calls g
and g
calls h
(either directly or indirectly). (Note: f(x) > g(y) > h > z
is also legal and is supposed to represent direct calls, but it may behave in confusing ways depending on which functions are instrumented globally, so avoid it for the time being).
def f(x):
return g(x + 1) * g(-x - 1)
def g(x):
return x * 2
# Use "as" to rename a variable if there is a name conflict
with probing("f(x) >> g > x as gx") as probe:
probe.subscribe(print)
f(5)
# {'gx': 6, 'x': 5}
# {'gx': -6, 'x': 5}
g(10)
# Prints nothing
Example 3: sibling calls
Selectors can also specify variables on different paths in the call graph. For example:
def f(x):
v = g(x + 1) * h(-x - 1)
return v
def g(y):
return y * 2
def h(z):
return z * 3
with probing("f(x, g(y), h(!z))") as probe:
probe.subscribe(print)
f(10)
# {'z': -11, 'x': 10, 'y': 11}
Remember to set the focus with !
. It should ideally be on the last variable to be set.
There is currently no error if you don't set a focus, it will simply do nothing, so beware of that for the time being.
Example 4: tagging variables
Using annotations, variables can be given various tags, and probes can use these tags instead of variable names.
def fishy(x):
a: "@fish" = x + 1
b: "@fish & @trout" = x + 2
return a * b
with probing("fishy > $x:@trout") as probe:
probe.subscribe(print)
fishy(10)
# {'x': 12}
with probing("fishy > $x:@fish") as probe:
probe.subscribe(print)
fishy(10)
# {'x': 11}
# {'x': 12}
Probe
Probe
works more or less the same way as probing
, but it is not a context manager: it just works globally from the moment of its creation. This means that streams created with Probe
never actually end, so operators that wait for the full stream before triggering, such as ptera.op.min
, will not work.
Probe("fact() as result").subscribe(print)
fact(2)
# {'result': 1}
# {'result': 2}
fact(3)
# {'result': 1}
# {'result': 2}
# {'result': 6}
Absolute probes
Here is a notation to probe a function using an "absolute path" in the module system:
Probe("/xyz.submodule/Klass/method > x")
# is mostly equivalent to:
from xyz.submodule import Klass
Probe("Klass.method > x")
The slashes represent a physical nesting rather than object attributes. For example, /module.submodule/x/y
means:
- Go in the file that defines
module.submodule
- Enter
def x
orclass x
(it will not work ifx
is imported from elsewhere) - Within that definition, enter
def y
orclass y
Note:
- Unlike the normal notation, the absolute notation bypasses decorators:
/module/function
will probe the function inside thedef function(): ...
inmodule.py
, so it will work even if the function was wrapped by a decorator (unless the decorator does not actually call the function). - Although the
/module/function/closure
notation can theoretically point to closures, this does not work yet. (It will, eventually.) - Use
/module.submodule/func
, not/module/submodule/func
. The former roughly corresponds tofrom module.submodule import func
and the latter tofrom module import submodule; func = submodule.func
, which can be different in Python. It's a bit odd, but it works that way to properly address Python quirks.
Operators
All the existing operators defined in the rx
package should be compatible with Probe
and probing
. They may be imported as ptera.operators
or ptera.op
In addition to this, ptera.operators
defines the following operators:
Utility
format(string)
: format each item of the stream (like str.format)getitem(name)
: extract an item from a stream of dictskeymap(fn)
: calls a function using kwargs from a stream of dictsthrottle(duration)
: alias forrx.operators.throttle_first
Arithmetic
roll(n, reduce=None, key_mapper=None, seed=None)
: transform a stream into rolling windows of size at most n. Successive windows overlap completely except for the first and last elements.- If reduce is provided, it is called with arguments
(last, add, drop, last_size, current_size)
- If transform is provided, it is called on each element
- If reduce is provided, it is called with arguments
rolling_average(n, key_mapper=None)
: efficient implementation of a rolling average (mean of the last n elements)rolling_average_and_variance(n, key_mapper=None)
: efficient implementation of a rolling average and (sample) variance of the last n elements, returned as a tuple.
Query language
Here is some code annotated with queries that will match various variables. The queries are not exhaustive, just examples.
- The semicolon ";" is used to separate queries and it is not part of any query.
- The hash character "#" is part of the query if there is no space after it, otherwise it starts a comment.
from ptera import ptera, tag
Animal = tag.Animal
Thing = tag.Thing
@tooled
def art(a, b): # art > a ; art > b ; art(!a, b) ; art(a, !b)
a1: Animal = bee(a) # a1 ; art > a1 ; art(!a1) ; art > $x
# a1:Animal ; $x:Animal
# art(!a1) > bee > d # Focus on a1, also includes d
# art > bee # This refers to the bee function
# * > a1 ; *(!a1)
a2: Thing = cap(b) # a2 ; art > a2 ; art(!a2) ; art > $x
# a2:Thing ; $x:Thing
return a1 + a2 # art > #value ; art(#value as art_result)
# art() as art_result
# art > $x
@tooled
def bee(c):
c1 = c + 1 # bee > c1 ; art >> c1 ; art(a2) > bee > c1
# bee > c1 as xyz
return c1 # bee > #value ; bee(c) as bee_value
@tooled
def cap(d: Thing & int): # cap > d ; $x:Thing ; cap > $x
# art(bee(c)) > cap > d
return d * d
- The
!
operator marks the focus of the query. There will be one result for each time the focus is triggered, and when usingtweak
orrewrite
the focus is what is being tweaked or rewritten.- Other variables are supplemental information, available along with the focus in query results. They can also be used to compute a value for the focus if they are available by the time the focus is reached.
- The nesting operators
>
and>>
automatically set the focus to the right hand side if the rhs is a single variable and the operator is not inside(...)
.
- The wildcard
*
stands in for any function. - The
>>
operator represents deep nesting. For example,art >> c1
encompasses the patternart > bee > c1
.- In general,
a >> z
encompassesa > z
,a > b > z
,a > b > c > z
,a > * > z
, and so on.
- In general,
- A function's return value corresponds to a special variable named
#value
. $x
will match any variable name. Getting the variable name for the capture is possible but requires themap_full
method. For example:- Query:
art > $x
- Getting the names:
results.map_full(lambda x: x.name) == ["a1", "a2", "#value"]
- Other fields accessible from
map_full
arevalue
,names
andvalues
, the latter two being needed if multiple results are captured together.
- Query:
- Variable annotations are preserved and can be filtered on, using the
:
operator. However, Ptera only recognizes tags created usingptera.Tag("XYZ")
orptera.tag.XYZ
. It will not filter over types. art(bee(c)) > cap > d
triggers on the variabled
in calls tocap
, but it will also include the value ofc
for all calls tobee
insideart
.- If there are multiple calls to
bee
, all values ofc
will be pooled together, and it will be necessary to usemap_all
to retrieve the values (ormap_full
).
- If there are multiple calls to
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