A simple, fast, monitoring profiler for Clojure/Script.
Usage: wrap+name interesting body exprs with the p
macro. Then activate
profiling of these wrapped exprs using the profiled
or profile
macros:
(profiled {} (p :my-fn (my-fn))) ; Returns [<body-result> <?pstats>] (profile {} (p :my-fn (my-fn))) ; Returns <body-result>, dispatches ; ?pstats to any registered handlers.
Extensive facilities are provided for compile-time elision and runtime filtering.
See the relevant docstrings for more info:
p
, profiled
, profile
, add-handler!
; Core API
(p [opts & body] [id & body]) ; e.g. (p ::my-pid (do-work))
(profiled [opts & body]) ; e.g. (profiled {:level 2} (my-fn))
(profile [opts & body]) ; e.g. (profiled {:level 2} (my-fn))
(add-handler! [handler-id ns-pattern handler-fn])
How/where to use this library: Tufte profiling is highly optimized: even without elision, you can usually leave profiling enabled in production (e.g. for sampled profiling, or to detect unusual performance behaviour). Tufte's stats maps are well suited to programmatic monitoring.
Abbreviations, etc.
p
profile
A simple, fast, monitoring profiler for Clojure/Script. Usage: wrap+name interesting body exprs with the `p` macro. Then activate profiling of these wrapped exprs using the `profiled` or `profile` macros: (profiled {} (p :my-fn (my-fn))) ; Returns [<body-result> <?pstats>] (profile {} (p :my-fn (my-fn))) ; Returns <body-result>, dispatches ; ?pstats to any registered handlers. Extensive facilities are provided for compile-time elision and runtime filtering. See the relevant docstrings for more info: `p`, `profiled`, `profile`, `add-handler!` ; Core API (p [opts & body] [id & body]) ; e.g. `(p ::my-pid (do-work))` (profiled [opts & body]) ; e.g. `(profiled {:level 2} (my-fn))` (profile [opts & body]) ; e.g. `(profiled {:level 2} (my-fn))` (add-handler! [handler-id ns-pattern handler-fn]) How/where to use this library: Tufte profiling is highly optimized: even without elision, you can usually leave profiling enabled in production (e.g. for sampled profiling, or to detect unusual performance behaviour). Tufte's stats maps are well suited to programmatic monitoring. Abbreviations, etc. - form id = pid = id given in `p` - group id = gid = id given in `profile`
(-elide? level-form ns-str-form)
Returns true iff level or ns are compile-time filtered.
Returns true iff level or ns are compile-time filtered.
(add-accumulating-handler! {:keys [ns-pattern handler-id]
:or {handler-id :accumulating}})
Experimental, subject to change!
Creates a new StatsAccumulator and agent, then registers
a handler to accumulate profile
output to the StatsAccumulator
using the agent.
Returns the StatsAccumulator. Deref it to drain the accumulator and return {<group-id> <merged-pstats>}.
One common pattern is to deref the accumulator every n minutes/etc. to get a view of performance over the period, e.g.:
(defonce my-sacc (add-accumulating-handler! "*")) (defonce my-sacc-drainer ;; Will drain and print stats each 1 minute (future (while true (when-let [m (not-empty @my-sacc)] (println (format-grouped-pstats m)) (Thread/sleep 60000)))))
See also format-grouped-pstats
,
Experimental, subject to change! Creates a new StatsAccumulator and agent, then registers a handler to accumulate `profile` output to the StatsAccumulator using the agent. Returns the StatsAccumulator. Deref it to drain the accumulator and return {<group-id> <merged-pstats>}. One common pattern is to deref the accumulator every n minutes/etc. to get a view of performance over the period, e.g.: (defonce my-sacc (add-accumulating-handler! "*")) (defonce my-sacc-drainer ;; Will drain and print stats each 1 minute (future (while true (when-let [m (not-empty @my-sacc)] (println (format-grouped-pstats m)) (Thread/sleep 60000))))) See also `format-grouped-pstats`,
(add-basic-println-handler! {:keys [ns-pattern handler-id format-pstats-opts]
:or {ns-pattern "*" handler-id :basic-println}})
Adds a simple handler that logs profile
stats output with println
.
Adds a simple handler that logs `profile` stats output with `println`.
(add-handler! handler-id handler-fn)
(add-handler! handler-id ns-pattern handler-fn)
Use this to register interest in stats output produced by profile
calls.
Each registered handler-fn
will be called as:
(handler-fn {:ns-str _ :level _ :?id _ :?data _ :pstats _ :pstats-str_ _})
Map args:
:ns-str - Namespace string where profile
call took place
:level - Level e/o #{0 1 2 3 4 5}, given in (profile {:level _} ...)
:?id - Optional group id, given in (profile {:id _} ...)
:?data - Optional arb data, given in (profile {:data _} ...)
:pstats - As in (second (profiled ...))
. Derefable, mergeable.
:pstats-str_ - `(delay (format-pstats pstats))
Error handling (NB):
Handler errors will be silently swallowed. Please try
/catch
and
appropriately deal with (e.g. log) possible errors within handler-fn
.
Async/blocking:
handler-fn
should ideally be non-blocking, or reasonably cheap. Handler
dispatch occurs through a 1-thread 1k-buffer dropping queue.
Ns filtering:
Provide an optional ns-pattern
arg to only call handler for matching
namespaces. See compile-ns-filter
docstring for details on ns-pattern
.
Handler ideas:
Save to a db, log, put!
to an appropriate core.async
channel, filter,
aggregate, use for a realtime analytics dashboard, examine for outliers
or unexpected output, ...
Use this to register interest in stats output produced by `profile` calls. Each registered `handler-fn` will be called as: (handler-fn {:ns-str _ :level _ :?id _ :?data _ :pstats _ :pstats-str_ _}) Map args: :ns-str - Namespace string where `profile` call took place :level - Level e/o #{0 1 2 3 4 5}, given in `(profile {:level _} ...)` :?id - Optional group id, given in `(profile {:id _} ...)` :?data - Optional arb data, given in `(profile {:data _} ...)` :pstats - As in `(second (profiled ...))`. Derefable, mergeable. :pstats-str_ - `(delay (format-pstats pstats)) Error handling (NB): Handler errors will be silently swallowed. Please `try`/`catch` and appropriately deal with (e.g. log) possible errors *within* `handler-fn`. Async/blocking: `handler-fn` should ideally be non-blocking, or reasonably cheap. Handler dispatch occurs through a 1-thread 1k-buffer dropping queue. Ns filtering: Provide an optional `ns-pattern` arg to only call handler for matching namespaces. See `compile-ns-filter` docstring for details on `ns-pattern`. Handler ideas: Save to a db, log, `put!` to an appropriate `core.async` channel, filter, aggregate, use for a realtime analytics dashboard, examine for outliers or unexpected output, ...
(capture-time! id nano-secs-elapsed)
(capture-time! pdata id nano-secs-elapsed)
Note: this is a low-level primitive for advanced users! Can be useful when tracking time across arbitrary thread boundaries or for async jobs / callbacks / etc.
See new-pdata
for more info on low-level primitives.
Note: this is a low-level primitive for advanced users! Can be useful when tracking time across arbitrary thread boundaries or for async jobs / callbacks / etc. See `new-pdata` for more info on low-level primitives.
(chance p)
Returns true with 0<p
<1 probability.
Returns true with 0<`p`<1 probability.
(compile-ns-filter ns-pattern)
Returns (fn [?ns]) -> truthy. Some example patterns: "foo.bar", "foo.bar.", #{"foo" "bar"}, {:whitelist ["foo.bar."] :blacklist ["baz.*"]}
Returns (fn [?ns]) -> truthy. Some example patterns: "foo.bar", "foo.bar.*", #{"foo" "bar"}, {:whitelist ["foo.bar.*"] :blacklist ["baz.*"]}
(defnp name doc-string? attr-map? [params*] prepost-map? body)
(defnp name doc-string? attr-map? ([params*] prepost-map? body) + attr-map?)
(defnp & sigs)
Like defn
but wraps fn bodies with p
macro.
Like `defn` but wraps fn bodies with `p` macro.
(defnp- name doc-string? attr-map? [params*] prepost-map? body)
(defnp- name doc-string? attr-map? ([params*] prepost-map? body) + attr-map?)
(defnp- & sigs)
Like defn-
but wraps fn bodies with p
macro.
Like `defn-` but wraps fn bodies with `p` macro.
(fnp name? ([params*] prepost-map? body) +)
(fnp name? [params*] prepost-map? body)
(fnp & sigs)
Like fn
but wraps fn bodies with p
macro.
Like `fn` but wraps fn bodies with `p` macro.
(format-grouped-pstats m)
(format-grouped-pstats m
{:keys [group-sort-fn format-pstats-opts]
:or {group-sort-fn (fn [m]
(get-in m [:clock :total] 0))}})
Experimental, subject to change.
Experimental, subject to change.
(format-pstats ps)
(format-pstats ps opts)
Formats given pstats to a string table. Accounted < Clock => Some work was done that wasn't tracked by any p forms. Accounted > Clock => Nested p forms, and/or parallel threads.
Formats given pstats to a string table. Accounted < Clock => Some work was done that wasn't tracked by any p forms. Accounted > Clock => Nested p forms, and/or parallel threads.
(may-profile? level)
(may-profile? level ns)
Returns true iff level and ns are runtime unfiltered.
Returns true iff level and ns are runtime unfiltered.
(merge-pstats)
(merge-pstats ps0)
(merge-pstats ps0 ps1)
Statistics are lossless unless data to merge are very large. Total clock time is exact iff merges are done in strictly increasing order of pstats completion (:t1) time.
Statistics are lossless unless data to merge are very large. Total clock time is exact iff merges are done in strictly increasing order of pstats completion (:t1) time.
(new-pdata)
(new-pdata {:keys [dynamic? nmax] :or {dynamic? true nmax default-nmax}})
Note: this is a low-level primitive for advanced users!
Returns a new pdata object for use with with-profiling
and/or capture-time!
.
Deref to get pstats:
(let [pd (new-pdata) t0 (System/nanoTime)] (with-profiling pd {} (p :foo (Thread/sleep 100)) (capture-time! pd :bar (- t0 (System/nanoTime)))) @pd)
Dynamic (thread-safe) by default. WARNING: don't change this default unless you're very sure the resulting pdata object will not be concurrently modified across threads. Concurrent modification will lead to bad data and/or exceptions!
Note: this is a low-level primitive for advanced users! Returns a new pdata object for use with `with-profiling` and/or `capture-time!`. Deref to get pstats: (let [pd (new-pdata) t0 (System/nanoTime)] (with-profiling pd {} (p :foo (Thread/sleep 100)) (capture-time! pd :bar (- t0 (System/nanoTime)))) @pd) Dynamic (thread-safe) by default. *WARNING*: don't change this default unless you're very sure the resulting pdata object will not be concurrently modified across threads. Concurrent modification will lead to bad data and/or exceptions!
(p id & body)
(p opts & body)
Profiling spy. Always executes body, and always returns <body-result>.
When [ns level] unelided and profiling is active, records execution time of body.
Compile-time opts:
:id - Form id for this body in stats output (e.g. ::my-fn-call
)
:level - e/o #{0 1 2 3 4 5} ; Default is 5
Profiling spy. Always executes body, and always returns <body-result>. When [ns level] unelided and profiling is active, records execution time of body. Compile-time opts: :id - Form id for this body in stats output (e.g. `::my-fn-call`) :level - e/o #{0 1 2 3 4 5} ; Default is `5`
(profile opts & body)
Always executes body, and always returns <body-result>.
When [ns level] unelided and [ns level when
] unfiltered, executes body
with profiling active and dispatches stats to any registered handlers
(see add-handler!
).
Handy if you'd like to consume/aggregate stats output later/elsewhere.
Otherwise see profiled
.
Compile-time opts:
:level - e/o #{0 1 2 3 4 5} ; Default is 5
:dynamic? - Use multi-threaded profiling? ; Default is false
:nmax - ~Max captures per id before compaction ; Default is 8e5
:when - Optional arbitrary conditional form (e.g. boolean expr)
:id - Optional group id provided to handlers (e.g. ::my-stats-1
)
:data - Optional arbitrary data provided to handlers
Note on laziness: Please note that lazy seqs and other forms of laziness (e.g. delays) will only contribute to profiling results if/when evaluation actually occurs. This is intentional and a useful property. Compare:
(profile {} (delay (Thread/sleep 2000))) ; Doesn't count sleep (profile {} @(delay (Thread/sleep 2000))) ; Does count sleep
Always executes body, and always returns <body-result>. When [ns level] unelided and [ns level `when`] unfiltered, executes body with profiling active and dispatches stats to any registered handlers (see `add-handler!`). Handy if you'd like to consume/aggregate stats output later/elsewhere. Otherwise see `profiled`. Compile-time opts: :level - e/o #{0 1 2 3 4 5} ; Default is `5` :dynamic? - Use multi-threaded profiling? ; Default is `false` :nmax - ~Max captures per id before compaction ; Default is 8e5 :when - Optional arbitrary conditional form (e.g. boolean expr) :id - Optional group id provided to handlers (e.g. `::my-stats-1`) :data - Optional arbitrary data provided to handlers Note on laziness: Please note that lazy seqs and other forms of laziness (e.g. delays) will only contribute to profiling results if/when evaluation actually occurs. This is intentional and a useful property. Compare: (profile {} (delay (Thread/sleep 2000))) ; Doesn't count sleep (profile {} @(delay (Thread/sleep 2000))) ; Does count sleep
(profiled opts & body)
Always executes body, and always returns [<body-result> <?pstats>].
When [ns level] unelided and [ns level when
] unfiltered, executes body
with profiling active.
Handy if you'd like to consume stats output directly.
Otherwise see profile
.
pstats
objects are derefable and mergeable:
Full set of :stats
keys:
:n :min :max :mean :mad :sum :p50 :p90 :p95 :p99
Compile-time opts:
:level - e/o #{0 1 2 3 4 5} ; Default is 5
:dynamic? - Use multi-threaded profiling? ; Default is false
:nmax - ~Max captures per id before compaction ; Default is 8e5
:when - Optional arbitrary conditional form (e.g. boolean expr)
Note on laziness: Please note that lazy seqs and other forms of laziness (e.g. delays) will only contribute to profiling results if/when evaluation actually occurs. This is intentional and a useful property. Compare:
(profiled {} (delay (Thread/sleep 2000))) ; Doesn't count sleep (profiled {} @(delay (Thread/sleep 2000))) ; Does count sleep
Always executes body, and always returns [<body-result> <?pstats>]. When [ns level] unelided and [ns level `when`] unfiltered, executes body with profiling active. Handy if you'd like to consume stats output directly. Otherwise see `profile`. `pstats` objects are derefable and mergeable: - @pstats -> {:stats {:n _ :min _ ...} :clock {:t0 _ :t1 _ :total _}} - @(merge-pstats ps1 ps2) -> {:stats {:n _ :min _ ...} :clock {:t0 _ :t1 _ :total _}} Full set of `:stats` keys: :n :min :max :mean :mad :sum :p50 :p90 :p95 :p99 Compile-time opts: :level - e/o #{0 1 2 3 4 5} ; Default is `5` :dynamic? - Use multi-threaded profiling? ; Default is `false` :nmax - ~Max captures per id before compaction ; Default is 8e5 :when - Optional arbitrary conditional form (e.g. boolean expr) Note on laziness: Please note that lazy seqs and other forms of laziness (e.g. delays) will only contribute to profiling results if/when evaluation actually occurs. This is intentional and a useful property. Compare: (profiled {} (delay (Thread/sleep 2000))) ; Doesn't count sleep (profiled {} @(delay (Thread/sleep 2000))) ; Does count sleep
(profiling?)
Returns e/o #{nil :thread :dynamic}.
Returns e/o #{nil :thread :dynamic}.
(refer-tufte)
(require '[taoensso.tufte :as tufte :refer [defnp p profiled profile]])
(require '[taoensso.tufte :as tufte :refer [defnp p profiled profile]])
(set-min-level! level)
Sets root binding of minimum profiling level, e/o #{0 1 2 3 4 5 6}. 0 => Enable all profiling. 6 => Disable all profiling.
Sets root binding of minimum profiling level, e/o #{0 1 2 3 4 5 6}. 0 => Enable all profiling. 6 => Disable all profiling.
(set-ns-pattern! ns-pattern)
Sets root binding of namespace filter.
See compile-ns-filter
docstring for details on ns-pattern
arg.
Sets root binding of namespace filter. See `compile-ns-filter` docstring for details on `ns-pattern` arg.
(stats-accumulator)
Experimental, subject to change! Small util to help merge pstats from multiple runs or threads.
Returns a stateful StatsAccumulator (sacc
) with:
(sacc <group-id> <pstats>)
; Merges given pstats under given group id@sacc
; Drains accumulator and returns {<group-id> <merged-pstats>}Note that you may want some kind of async/buffer/serialization mechanism in front of merge calls (e.g. an agent).
See also add-accumulating-handler!
.
Experimental, subject to change! Small util to help merge pstats from multiple runs or threads. Returns a stateful StatsAccumulator (`sacc`) with: - `(sacc <group-id> <pstats>)` ; Merges given pstats under given group id - `@sacc` ; Drains accumulator and returns {<group-id> <merged-pstats>} Note that you may want some kind of async/buffer/serialization mechanism in front of merge calls (e.g. an agent). See also `add-accumulating-handler!`.
(with-min-level level & body)
Executes body with dynamic minimum profiling level, e/o #{0 1 2 3 4 5 6}. 0 => Enable all profiling. 6 => Disable all profiling.
Executes body with dynamic minimum profiling level, e/o #{0 1 2 3 4 5 6}. 0 => Enable all profiling. 6 => Disable all profiling.
(with-ns-pattern ns-pattern & body)
Executes body with dynamic namespace filter.
See compile-ns-filter
docstring for details on ns-pattern
arg.
Executes body with dynamic namespace filter. See `compile-ns-filter` docstring for details on `ns-pattern` arg.
(with-profiling pdata {:keys [dynamic? nmax] :or {nmax default-nmax}} & body)
Note: this is a low-level primitive for advanced users!
Enables p
forms in body and returns body's result.
See new-pdata
for more info on low-level primitives.
Note: this is a low-level primitive for advanced users! Enables `p` forms in body and returns body's result. See `new-pdata` for more info on low-level primitives.
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