summaryrefslogtreecommitdiffstats
path: root/js/src/doc/Debugger/Debugger.Memory.md
diff options
context:
space:
mode:
authorMatt A. Tobin <mattatobin@localhost.localdomain>2018-02-02 04:16:08 -0500
committerMatt A. Tobin <mattatobin@localhost.localdomain>2018-02-02 04:16:08 -0500
commit5f8de423f190bbb79a62f804151bc24824fa32d8 (patch)
tree10027f336435511475e392454359edea8e25895d /js/src/doc/Debugger/Debugger.Memory.md
parent49ee0794b5d912db1f95dce6eb52d781dc210db5 (diff)
downloadUXP-5f8de423f190bbb79a62f804151bc24824fa32d8.tar
UXP-5f8de423f190bbb79a62f804151bc24824fa32d8.tar.gz
UXP-5f8de423f190bbb79a62f804151bc24824fa32d8.tar.lz
UXP-5f8de423f190bbb79a62f804151bc24824fa32d8.tar.xz
UXP-5f8de423f190bbb79a62f804151bc24824fa32d8.zip
Add m-esr52 at 52.6.0
Diffstat (limited to 'js/src/doc/Debugger/Debugger.Memory.md')
-rw-r--r--js/src/doc/Debugger/Debugger.Memory.md549
1 files changed, 549 insertions, 0 deletions
diff --git a/js/src/doc/Debugger/Debugger.Memory.md b/js/src/doc/Debugger/Debugger.Memory.md
new file mode 100644
index 000000000..a5ccd93cd
--- /dev/null
+++ b/js/src/doc/Debugger/Debugger.Memory.md
@@ -0,0 +1,549 @@
+Debugger.Memory
+===============
+
+The [`Debugger API`][debugger] can help tools observe the debuggee's memory use
+in various ways:
+
+- It can mark each new object with the JavaScript call stack at which it was
+ allocated.
+
+- It can log all object allocations, yielding a stream of JavaScript call stacks
+ at which allocations have occurred.
+
+- It can compute a *census* of items belonging to the debuggee, categorizing
+ items in various ways, and yielding item counts.
+
+If <i>dbg</i> is a [`Debugger`][debugger-object] instance, then the methods and
+accessor properties of <code><i>dbg</i>.memory</code> control how <i>dbg</i>
+observes its debuggees' memory use. The <code><i>dbg</i>.memory</code> object is
+an instance of `Debugger.Memory`; its inherited accesors and methods are
+described below.
+
+
+### Allocation Site Tracking
+
+The JavaScript engine marks each new object with the call stack at which it was
+allocated, if:
+
+- the object is allocated in the scope of a global object that is a debuggee of
+ some [`Debugger`][debugger-object] instance <i>dbg</i>; and
+
+- <code><i>dbg</i>.memory.[trackingAllocationSites][tracking-allocs]</code> is
+ set to `true`.
+
+- A [Bernoulli trial][bernoulli-trial] succeeds, with probability equal to the
+ maximum of
+ [`d.memory.allocationSamplingProbability`][alloc-sampling-probability] of all
+ `Debugger` instances `d` that are observing the global that this object is
+ allocated within the scope of.
+
+Given a [`Debugger.Object`][object] instance <i>dobj</i> referring to some
+object, <code><i>dobj</i>.[allocationSite][allocation-site]</code> returns a
+[saved call stack][saved-frame] indicating where <i>dobj</i>'s referent was
+allocated.
+
+
+### Allocation Logging
+
+If <i>dbg</i> is a [`Debugger`][debugger-object] instance, and
+<code><i>dbg</i>.memory.[trackingAllocationSites][tracking-allocs]</code> is set
+to `true`, then the JavaScript engine logs each object allocated by <i>dbg</i>'s
+debuggee code. You can retrieve the current log by calling
+<code><i>dbg</i>.memory.[drainAllocationsLog][drain-alloc-log]</code>. You can
+control the limit on the log's size by setting
+<code><i>dbg</i>.memory.[maxAllocationsLogLength][max-alloc-log]</code>.
+
+
+### Censuses
+
+A *census* is a complete traversal of the graph of all reachable memory items
+belonging to a particular `Debugger`'s debuggees. It produces a count of those
+items, broken down by various criteria. If <i>dbg</i> is a
+[`Debugger`][debugger-object] instance, you can call
+<code><i>dbg</i>.memory.[takeCensus][take-census]</code> to conduct a census of
+its debuggees' possessions.
+
+
+Accessor Properties of the `Debugger.Memory.prototype` Object
+-------------------------------------------------------------
+
+If <i>dbg</i> is a [`Debugger`][debugger-object] instance, then
+`<i>dbg</i>.memory` is a `Debugger.Memory` instance, which inherits the
+following accessor properties from its prototype:
+
+<code id='trackingallocationsites'>trackingAllocationSites</code>
+: A boolean value indicating whether this `Debugger.Memory` instance is
+ capturing the JavaScript execution stack when each Object is allocated. This
+ accessor property has both a getter and setter: assigning to it enables or
+ disables the allocation site tracking. Reading the accessor produces `true`
+ if the Debugger is capturing stacks for Object allocations, and `false`
+ otherwise. Allocation site tracking is initially disabled in a new Debugger.
+
+ Assignment is fallible: if the Debugger cannot track allocation sites, it
+ throws an `Error` instance.
+
+ You can retrieve the allocation site for a given object with the
+ [`Debugger.Object.prototype.allocationSite`][allocation-site] accessor
+ property.
+
+<code id='alloc-sampling-probability'>allocationSamplingProbability</code>
+: A number between 0 and 1 that indicates the probability with which each new
+ allocation should be entered into the allocations log. 0 is equivalent to
+ "never", 1 is "always", and .05 would be "one out of twenty".
+
+ The default is 1, or logging every allocation.
+
+ Note that in the presence of multiple <code>Debugger</code> instances
+ observing the same allocations within a global's scope, the maximum
+ <code>allocationSamplingProbability</code> of all the
+ <code>Debugger</code>s is used.
+
+<code id='max-alloc-log'>maxAllocationsLogLength</code>
+: The maximum number of allocation sites to accumulate in the allocations log
+ at a time. This accessor can be both fetched and stored to. Its default
+ value is `5000`.
+
+<code id='allocationsLogOverflowed'>allocationsLogOverflowed</code>
+: Returns `true` if there have been more than
+ [`maxAllocationsLogLength`][#max-alloc-log] allocations since the last time
+ [`drainAllocationsLog`][#drain-alloc-log] was called and some data has been
+ lost. Returns `false` otherwise.
+
+Debugger.Memory Handler Functions
+---------------------------------
+
+Similar to [`Debugger`'s handler functions][debugger], `Debugger.Memory`
+inherits accessor properties that store handler functions for SpiderMonkey to
+call when given events occur in debuggee code.
+
+Unlike `Debugger`'s hooks, `Debugger.Memory`'s handlers' return values are not
+significant, and are ignored. The handler functions receive the
+`Debugger.Memory`'s owning `Debugger` instance as their `this` value. The owning
+`Debugger`'s `uncaughtExceptionHandler` is still fired for errors thrown in
+`Debugger.Memory` hooks.
+
+On a new `Debugger.Memory` instance, each of these properties is initially
+`undefined`. Any value assigned to a debugging handler must be either a function
+or `undefined`; otherwise a `TypeError` is thrown.
+
+Handler functions run in the same thread in which the event occurred.
+They run in the compartment to which they belong, not in a debuggee
+compartment.
+
+<code>onGarbageCollection(<i>statistics</i>)</code>
+: A garbage collection cycle spanning one or more debuggees has just been
+ completed.
+
+ The *statistics* parameter is an object containing information about the GC
+ cycle. It has the following properties:
+
+ `collections`
+ : The `collections` property's value is an array. Because SpiderMonkey's
+ collector is incremental, a full collection cycle may consist of
+ multiple discrete collection slices with the JS mutator running
+ interleaved. For each collection slice that occurred, there is an entry
+ in the `collections` array with the following form:
+
+ <pre class='language-js'><code>
+ {
+ "startTimestamp": <i>timestamp</i>,
+ "endTimestamp": <i>timestamp</i>,
+ }
+ </code></pre>
+
+ Here the *timestamp* values are [timestamps][] of the GC slice's start
+ and end events.
+
+ `reason`
+ : A very short string describing the reason why the collection was
+ triggered. Known values include the following:
+
+ * "API"
+ * "EAGER_ALLOC_TRIGGER"
+ * "DESTROY_RUNTIME"
+ * "LAST_DITCH"
+ * "TOO_MUCH_MALLOC"
+ * "ALLOC_TRIGGER"
+ * "DEBUG_GC"
+ * "COMPARTMENT_REVIVED"
+ * "RESET"
+ * "OUT_OF_NURSERY"
+ * "EVICT_NURSERY"
+ * "FULL_STORE_BUFFER"
+ * "SHARED_MEMORY_LIMIT"
+ * "PERIODIC_FULL_GC"
+ * "INCREMENTAL_TOO_SLOW"
+ * "DOM_WINDOW_UTILS"
+ * "COMPONENT_UTILS"
+ * "MEM_PRESSURE"
+ * "CC_WAITING"
+ * "CC_FORCED"
+ * "LOAD_END"
+ * "PAGE_HIDE"
+ * "NSJSCONTEXT_DESTROY"
+ * "SET_NEW_DOCUMENT"
+ * "SET_DOC_SHELL"
+ * "DOM_UTILS"
+ * "DOM_IPC"
+ * "DOM_WORKER"
+ * "INTER_SLICE_GC"
+ * "REFRESH_FRAME"
+ * "FULL_GC_TIMER"
+ * "SHUTDOWN_CC"
+ * "FINISH_LARGE_EVALUATE"
+ * "USER_INACTIVE"
+
+ `nonincrementalReason`
+ : If SpiderMonkey's collector determined it could not incrementally
+ collect garbage, and had to do a full GC all at once, this is a short
+ string describing the reason it determined the full GC was necessary.
+ Otherwise, `null` is returned. Known values include the following:
+
+ * "GC mode"
+ * "malloc bytes trigger"
+ * "allocation trigger"
+ * "requested"
+
+ `gcCycleNumber`
+ : The GC cycle's "number". Does not correspond to the number
+ of GC cycles that have run, but is guaranteed to be monotonically
+ increasing.
+
+Function Properties of the `Debugger.Memory.prototype` Object
+-------------------------------------------------------------
+
+<code id='drain-alloc-log'>drainAllocationsLog()</code>
+: When `trackingAllocationSites` is `true`, this method returns an array of
+ recent `Object` allocations within the set of debuggees. *Recent* is
+ defined as the `maxAllocationsLogLength` most recent `Object` allocations
+ since the last call to `drainAllocationsLog`. Therefore, calling this
+ method effectively clears the log.
+
+ Objects in the array are of the form:
+
+ <pre class='language-js'><code>
+ {
+ "timestamp": <i>timestamp</i>,
+ "frame": <i>allocationSite</i>,
+ "class": <i>className</i>,
+ "constructor": <i>constructorName</i>,
+ "size": <i>byteSize</i>,
+ "inNursery": <i>inNursery</i>,
+ }
+ </code></pre>
+
+ Where
+
+ * *timestamp* is the [timestamp][timestamps] of the allocation event.
+
+ * *allocationSite* is an allocation site (as a
+ [captured stack][saved-frame]). Note that this property can be null if the
+ object was allocated with no JavaScript frames on the stack.
+
+ * *className* is the string name of the allocated object's internal
+ `[[Class]]` property, for example "Array", "Date", "RegExp", or (most
+ commonly) "Object".
+
+ * *constructorName* is the constructor function's display name for objects
+ created by `new Ctor`. If that data is not available, or the object was
+ not created with a `new` expression, this property is `null`.
+
+ * *byteSize* is the size of the object in bytes.
+
+ * *inNursery* is true if the allocation happened inside the nursery. False
+ if the allocation skipped the nursery and started in the tenured heap.
+
+ When `trackingAllocationSites` is `false`, `drainAllocationsLog()` throws an
+ `Error`.
+
+<code id='take-census'>takeCensus(<i>options</i>)</code>
+: Carry out a census of the debuggee compartments' contents. A *census* is a
+ complete traversal of the graph of all reachable memory items belonging to a
+ particular `Debugger`'s debuggees. The census produces a count of those
+ items, broken down by various criteria.
+
+ The <i>options</i> argument is an object whose properties specify how the
+ census should be carried out.
+
+ If <i>options</i> has a `breakdown` property, that determines how the census
+ categorizes the items it finds, and what data it collects about them. For
+ example, if `dbg` is a `Debugger` instance, the following performs a simple
+ count of debuggee items:
+
+ dbg.memory.takeCensus({ breakdown: { by: 'count' } })
+
+ That might produce a result like:
+
+ { "count": 1616, "bytes": 93240 }
+
+ Here is a breakdown that groups JavaScript objects by their class name, and
+ non-string, non-script items by their C++ type name:
+
+ {
+ by: "coarseType",
+ objects: { by: "objectClass" },
+ other: { by: "internalType" }
+ }
+
+ which produces a result like this:
+
+ {
+ "objects": {
+ "Function": { "count": 404, "bytes": 37328 },
+ "Object": { "count": 11, "bytes": 1264 },
+ "Debugger": { "count": 1, "bytes": 416 },
+ "ScriptSource": { "count": 1, "bytes": 64 },
+ // ... omitted for brevity...
+ },
+ "scripts": { "count": 1, "bytes": 0 },
+ "strings": { "count": 701, "bytes": 49080 },
+ "other": {
+ "js::Shape": { "count": 450, "bytes": 0 },
+ "js::BaseShape": { "count": 21, "bytes": 0 },
+ "js::ObjectGroup": { "count": 17, "bytes": 0 }
+ }
+ }
+
+ In general, a `breakdown` value has one of the following forms:
+
+ <code>{ by: "count", count:<i>count<i>, bytes:<i>bytes</i> }</code>
+ : The trivial categorization: none whatsoever. Simply tally up the items
+ visited. If <i>count</i> is true, count the number of items visited; if
+ <i>bytes</i> is true, total the number of bytes the items use directly.
+ Both <i>count</i> and <i>bytes</i> are optional; if omitted, they
+ default to `true`. In the result of the census, this breakdown produces
+ a value of the form:
+
+ { "count":<i>n</b>, "bytes":<i>b</i> }
+
+ where the `count` and `bytes` properties are present as directed by the
+ <i>count</i> and <i>bytes</i> properties on the breakdown.
+
+ Note that the census can produce byte sizes only for the most common
+ types. When the census cannot find the byte size for a given type, it
+ returns zero.
+
+ <code>{ by: "bucket" }</code>
+ : Do not do any filtering or categorizing. Instead, accumulate a bucket of
+ each node's ID for every node that matches. The resulting report is an
+ array of the IDs.
+
+ For example, to find the ID of all nodes whose internal object
+ `[[class]]` property is named "RegExp", you could use the following code:
+
+ const report = dbg.memory.takeCensus({
+ breakdown: {
+ by: "objectClass",
+ then: { by: "bucket" }
+ }
+ });
+ doStuffWithRegExpIDs(report.RegExp);
+
+ <code>{ by: "allocationStack", then:<i>breakdown</i>, noStack:<i>noStackBreakdown</i> }</code>
+ : Group items by the full JavaScript stack trace at which they were
+ allocated.
+
+ Further categorize all the items allocated at each distinct stack using
+ <i>breakdown</i>.
+
+ In the result of the census, this breakdown produces a JavaScript `Map`
+ value whose keys are `SavedFrame` values, and whose values are whatever
+ sort of result <i>breakdown</i> produces. Objects allocated on an empty
+ JavaScript stack appear under the key `null`.
+
+ SpiderMonkey only tracks allocation sites for items if requested via the
+ [`trackingAllocationSites`][tracking-allocs] flag; even then, it does
+ not record allocation sites for every kind of item that appears in the
+ heap. Items that lack allocation site information are counted using
+ <i>noStackBreakdown</i>. These appear in the result `Map` under the key
+ string `"noStack"`.
+
+ <code>{ by: "objectClass", then:<i>breakdown</i>, other:<i>otherBreakdown</i> }</code>
+ : Group JavaScript objects by their ECMAScript `[[Class]]` internal property values.
+
+ Further categorize JavaScript objects in each class using
+ <i>breakdown</i>. Further categorize items that are not JavaScript
+ objects using <i>otherBreakdown</i>.
+
+ In the result of the census, this breakdown produces a JavaScript object
+ with no prototype whose own property names are strings naming classes,
+ and whose values are whatever sort of result <i>breakdown</i> produces.
+ The results for non-object items appear as the value of the property
+ named `"other"`.
+
+ <code>{ by: "coarseType", objects:<i>objects</i>, scripts:<i>scripts</i>, strings:<i>strings</i>, other:<i>other</i> }</code>
+ : Group items by their coarse type.
+
+ Use the breakdown value <i>objects</i> for items that are JavaScript
+ objects.
+
+ Use the breakdown value <i>scripts</i> for items that are
+ representations of JavaScript code. This includes bytecode, compiled
+ machine code, and saved source code.
+
+ Use the breakdown value <i>strings</i> for JavaScript strings.
+
+ Use the breakdown value <i>other</i> for items that don't fit into any of
+ the above categories.
+
+ In the result of the census, this breakdown produces a JavaScript object
+ of the form:
+
+ <pre class='language-js'><code>
+ {
+ "objects": <i>result</i>,
+ "scripts": <i>result</i>,
+ "strings": <i>result</i>,
+ "other": <i>result</i>
+ }
+ </code></pre>
+
+ where each <i>result</i> is a value of whatever sort the corresponding
+ breakdown value produces. All breakdown values are optional, and default
+ to `{ type: "count" }`.
+
+ <code>{ by: "internalType", then:<i>breakdown</i> }</code>
+ : Group items by the names given their types internally by SpiderMonkey.
+ These names are not meaningful to web developers, but this type of
+ breakdown does serve as a catch-all that can be useful to Firefox tool
+ developers.
+
+ For example, a census of a pristine debuggee global broken down by
+ internal type name typically looks like this:
+
+ {
+ "JSString": { "count": 701, "bytes": 49080 },
+ "js::Shape": { "count": 450, "bytes": 0 },
+ "JSObject": { "count": 426, "bytes": 44160 },
+ "js::BaseShape": { "count": 21, "bytes": 0 },
+ "js::ObjectGroup": { "count": 17, "bytes": 0 },
+ "JSScript": { "count": 1, "bytes": 0 }
+ }
+
+ In the result of the census, this breakdown produces a JavaScript object
+ with no prototype whose own property names are strings naming types,
+ and whose values are whatever sort of result <i>breakdown</i> produces.
+
+ <code>[ <i>breakdown</i>, ... ]</code>
+ : Group each item using all the given breakdown values. In the result of
+ the census, this breakdown produces an array of values of the sort
+ produced by each listed breakdown.
+
+ To simplify breakdown values, all `then` and `other` properties are optional.
+ If omitted, they are treated as if they were `{ type: "count" }`.
+
+ If the `options` argument has no `breakdown` property, `takeCensus` defaults
+ to the following:
+
+ <pre class='language-js'><code>
+ {
+ by: "coarseType",
+ objects: { by: "objectClass" },
+ other: { by: "internalType" }
+ }
+ </code></pre>
+
+ which produces results of the form:
+
+ <pre class='language-js'><code>
+ {
+ objects: { <i>class</i>: <i>count</i>, ... },
+ scripts: <i>count</i>,
+ strings: <i>count</i>,
+ other: { <i>type name</i>: <i>count</i>, ... }
+ }
+ </code></pre>
+
+ where each <i>count</i> has the form:
+
+ <pre class='language-js'><code>
+ { "count": <i>count</i>, bytes:<i>bytes</i> }
+ </code></pre>
+
+ Because performing a census requires traversing the entire graph of objects
+ in debuggee compartments, it is an expensive operation. On developer
+ hardware in 2014, traversing a memory graph containing roughly 130,000 nodes
+ and 410,000 edges took roughly 100ms. The traversal itself temporarily
+ allocates one hash table entry per node (roughly two address-sized words) in
+ addition to the per-category counts, whose size depends on the number of
+ categories.
+
+
+Memory Use Analysis Exposes Implementation Details
+--------------------------------------------------
+
+Memory analysis may yield surprising results, because browser implementation
+details that are transparent to content JavaScript often have visible effects on
+memory consumption. Web developers need to know their pages' actual memory
+consumption on real browsers, so it is correct for the tool to expose these
+behaviors, as long as it is done in a way that helps developers make decisions
+about their own code.
+
+This section covers some areas where Firefox's actual behavior deviates from
+what one might expect from the specified behavior of the web platform.
+
+
+### Objects
+
+SpiderMonkey objects usually use less memory than the naïve "table of properties
+with attributes" model would suggest. For example, it is typical for many
+objects to have identical sets of properties, with only the properties' values
+varying from one object to the next. To take advantage of this regularity,
+SpiderMonkey objects with identical sets of properties may share their property
+metadata; only property values are stored directly in the object.
+
+Array objects may also be optimized, if the set of live indices is dense.
+
+
+### Strings
+
+SpiderMonkey has three representations of strings:
+
+- Normal: the string's text is counted in its size.
+
+- Substring: the string is a substring of some other string, and points to that
+ string for its storage. This representation may result in a small string
+ retaining a very large string. However, the memory consumed by the string
+ itself is a small constant independent of its size, since it is simply a
+ reference to the larger string, a start position, and a length.
+
+- Concatenations: When asked to concatenate two strings, SpiderMonkey may elect
+ to delay copying the strings' data, and represent the result simply as a
+ pointer to the two original strings. Again, such a string retains other
+ strings, but the memory consumed by the string itself is a small constant
+ independent of its size, since it is simply a pair of pointers.
+
+SpiderMonkey converts strings from the more complex representations to the
+simpler ones when it pleases. Such conversions usually increase memory
+consumption.
+
+SpiderMonkey shares some strings amongst all web pages and browser JS. These
+shared strings, called *atoms*, are not included in censuses' string counts.
+
+
+### Scripts
+
+SpiderMonkey has a complex, hybrid representation of JavaScript code. There
+are four representations kept in memory:
+
+- _Source code_. SpiderMonkey retains a copy of most JavaScript source code.
+
+- _Compressed source code_. SpiderMonkey compresses JavaScript source code,
+ and de-compresses it on demand. Heuristics determine how long to retain the
+ uncompressed code.
+
+- _Bytecode_. This is SpiderMonkey's parsed representation of JavaScript.
+ Bytecode can be interpreted directly, or used as input to a just-in-time
+ compiler. Source is parsed into bytecode on demand; functions that are never
+ called are never parsed.
+
+- _Machine code_. SpiderMonkey includes several just-in-time compilers, each of
+ which translates JavaScript source or bytecode to machine code. Heuristics
+ determine which code to compile, and which compiler to use. Machine code may
+ be dropped in response to memory pressure, and regenerated as needed.
+
+Furthermore, SpiderMonkey tracks which types of values have appeared in
+variables and object properties. This type information can be large.
+
+In a census, all the various forms of JavaScript code are placed in the
+`"script"` category. Type information is accounted to the `"types"` category.