corysanin/tubestation
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity
Files
38662e82c89140a4917bd901b26e2817b17686f3
tubestation/toolkit/components/telemetry/TelemetryScalar.cpp
Alessio Placitelli fdceb69955 Bug 1395835 - Rename "group" to "category" in the scalar code and docs. r=chutten 
MozReview-Commit-ID: HQ3I2cfEaa
2017-09-27 10:12:13 +02:00

2728 lines
83 KiB
C++
Raw Blame History

/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "nsITelemetry.h"
#include "nsIVariant.h"
#include "nsVariant.h"
#include "nsHashKeys.h"
#include "nsBaseHashtable.h"
#include "nsClassHashtable.h"
#include "nsDataHashtable.h"
#include "nsIXPConnect.h"
#include "nsContentUtils.h"
#include "nsThreadUtils.h"
#include "nsJSUtils.h"
#include "nsPrintfCString.h"
#include "mozilla/dom/ContentParent.h"
#include "mozilla/dom/PContent.h"
#include "mozilla/StaticMutex.h"
#include "mozilla/StaticPtr.h"
#include "mozilla/Unused.h"
#include "TelemetryCommon.h"
#include "TelemetryScalar.h"
#include "TelemetryScalarData.h"
#include "ipc/TelemetryComms.h"
#include "ipc/TelemetryIPCAccumulator.h"
using mozilla::StaticAutoPtr;
using mozilla::StaticMutex;
using mozilla::StaticMutexAutoLock;
using mozilla::Telemetry::Common::AutoHashtable;
using mozilla::Telemetry::Common::IsExpiredVersion;
using mozilla::Telemetry::Common::CanRecordDataset;
using mozilla::Telemetry::Common::IsInDataset;
using mozilla::Telemetry::Common::LogToBrowserConsole;
using mozilla::Telemetry::Common::GetNameForProcessID;
using mozilla::Telemetry::Common::RecordedProcessType;
using mozilla::Telemetry::Common::IsValidIdentifierString;
using mozilla::Telemetry::ScalarActionType;
using mozilla::Telemetry::ScalarID;
using mozilla::Telemetry::DynamicScalarDefinition;
using mozilla::Telemetry::ScalarVariant;
using mozilla::Telemetry::ProcessID;
namespace TelemetryIPCAccumulator = mozilla::TelemetryIPCAccumulator;
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
//
// Naming: there are two kinds of functions in this file:
//
// * Functions named internal_*: these can only be reached via an
// interface function (TelemetryScalar::*). They expect the interface
// function to have acquired |gTelemetryScalarsMutex|, so they do not
// have to be thread-safe.
//
// * Functions named TelemetryScalar::*. This is the external interface.
// Entries and exits to these functions are serialised using
// |gTelemetryScalarsMutex|.
//
// Avoiding races and deadlocks:
//
// All functions in the external interface (TelemetryScalar::*) are
// serialised using the mutex |gTelemetryScalarsMutex|. This means
// that the external interface is thread-safe, and many of the
// internal_* functions can ignore thread safety. But it also brings
// a danger of deadlock if any function in the external interface can
// get back to that interface. That is, we will deadlock on any call
// chain like this
//
// TelemetryScalar::* -> .. any functions .. -> TelemetryScalar::*
//
// To reduce the danger of that happening, observe the following rules:
//
// * No function in TelemetryScalar::* may directly call, nor take the
// address of, any other function in TelemetryScalar::*.
//
// * No internal function internal_* may call, nor take the address
// of, any function in TelemetryScalar::*.
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
//
// PRIVATE TYPES
namespace {
const uint32_t kMaximumNumberOfKeys = 100;
const uint32_t kMaximumKeyStringLength = 70;
const uint32_t kMaximumStringValueLength = 50;
// The category and scalar name maximum lengths are used by the dynamic
// scalar registration function and must match the constants used by
// the 'parse_scalars.py' script for static scalars.
const uint32_t kMaximumCategoryNameLength = 40;
const uint32_t kMaximumScalarNameLength = 40;
const uint32_t kScalarCount =
static_cast<uint32_t>(mozilla::Telemetry::ScalarID::ScalarCount);
enum class ScalarResult : uint8_t {
// Nothing went wrong.
Ok,
// General Scalar Errors
NotInitialized,
CannotUnpackVariant,
CannotRecordInProcess,
CannotRecordDataset,
KeyedTypeMismatch,
UnknownScalar,
OperationNotSupported,
InvalidType,
InvalidValue,
// Keyed Scalar Errors
KeyIsEmpty,
KeyTooLong,
TooManyKeys,
// String Scalar Errors
StringTooLong,
// Unsigned Scalar Errors
UnsignedNegativeValue,
UnsignedTruncatedValue,
// Dynamic Scalar Errors
AlreadyRegistered,
};
// A common identifier for both built-in and dynamic scalars.
struct ScalarKey {
uint32_t id;
bool dynamic;
};
/**
* Scalar information for dynamic definitions.
*/
struct DynamicScalarInfo : BaseScalarInfo {
nsCString mDynamicName;
bool mDynamicExpiration;
DynamicScalarInfo(uint32_t aKind, bool aRecordOnRelease,
bool aExpired, const nsACString& aName,
bool aKeyed)
: BaseScalarInfo(aKind,
aRecordOnRelease ?
nsITelemetry::DATASET_RELEASE_CHANNEL_OPTOUT :
nsITelemetry::DATASET_RELEASE_CHANNEL_OPTIN,
RecordedProcessType::All,
aKeyed)
, mDynamicName(aName)
, mDynamicExpiration(aExpired)
{}
// The following functions will read the stored text
// instead of looking it up in the statically generated
// tables.
const char *name() const;
const char *expiration() const;
};
const char *
DynamicScalarInfo::name() const
{
return mDynamicName.get();
}
const char *
DynamicScalarInfo::expiration() const
{
// Dynamic scalars can either be expired or not (boolean flag).
// Return an appropriate version string to leverage the scalar expiration
// logic.
return mDynamicExpiration ? "1.0" : "never";
}
typedef nsBaseHashtableET<nsDepCharHashKey, ScalarKey> CharPtrEntryType;
typedef AutoHashtable<CharPtrEntryType> ScalarMapType;
// Dynamic scalar definitions.
StaticAutoPtr<nsTArray<DynamicScalarInfo>> gDynamicScalarInfo;
const BaseScalarInfo&
internal_GetScalarInfo(const ScalarKey& aId)
{
if (!aId.dynamic) {
return gScalars[aId.id];
}
return (*gDynamicScalarInfo)[aId.id];
}
bool
IsValidEnumId(mozilla::Telemetry::ScalarID aID)
{
return aID < mozilla::Telemetry::ScalarID::ScalarCount;
}
// TODO: We should explicitly pass a lock here. Unfortunately this needs
// some refactoring of the callers as well. See bug 1362957.
bool
internal_IsValidId(const ScalarKey& aId)
{
// Please note that this function needs to be called with the scalar
// mutex being acquired: other functions might be messing with
// |gDynamicScalarInfo|.
return aId.dynamic ? (aId.id < gDynamicScalarInfo->Length()) :
IsValidEnumId(static_cast<mozilla::Telemetry::ScalarID>(aId.id));
}
/**
* Convert a nsIVariant to a mozilla::Variant, which is used for
* accumulating child process scalars.
*/
ScalarResult
GetVariantFromIVariant(nsIVariant* aInput, uint32_t aScalarKind,
mozilla::Maybe<ScalarVariant>& aOutput)
{
switch (aScalarKind) {
case nsITelemetry::SCALAR_TYPE_COUNT:
{
uint32_t val = 0;
nsresult rv = aInput->GetAsUint32(&val);
if (NS_FAILED(rv)) {
return ScalarResult::CannotUnpackVariant;
}
aOutput = mozilla::Some(mozilla::AsVariant(val));
break;
}
case nsITelemetry::SCALAR_TYPE_STRING:
{
nsString val;
nsresult rv = aInput->GetAsAString(val);
if (NS_FAILED(rv)) {
return ScalarResult::CannotUnpackVariant;
}
aOutput = mozilla::Some(mozilla::AsVariant(val));
break;
}
case nsITelemetry::SCALAR_TYPE_BOOLEAN:
{
bool val = false;
nsresult rv = aInput->GetAsBool(&val);
if (NS_FAILED(rv)) {
return ScalarResult::CannotUnpackVariant;
}
aOutput = mozilla::Some(mozilla::AsVariant(val));
break;
}
default:
MOZ_ASSERT(false, "Unknown scalar kind.");
return ScalarResult::UnknownScalar;
}
return ScalarResult::Ok;
}
// Implements the methods for ScalarInfo.
const char *
ScalarInfo::name() const
{
return &gScalarsStringTable[this->name_offset];
}
const char *
ScalarInfo::expiration() const
{
return &gScalarsStringTable[this->expiration_offset];
}
/**
* The base scalar object, that serves as a common ancestor for storage
* purposes.
*/
class ScalarBase
{
public:
virtual ~ScalarBase() = default;
// Set, Add and SetMaximum functions as described in the Telemetry IDL.
virtual ScalarResult SetValue(nsIVariant* aValue) = 0;
virtual ScalarResult AddValue(nsIVariant* aValue) { return ScalarResult::OperationNotSupported; }
virtual ScalarResult SetMaximum(nsIVariant* aValue) { return ScalarResult::OperationNotSupported; }
// Convenience methods used by the C++ API.
virtual void SetValue(uint32_t aValue) { mozilla::Unused << HandleUnsupported(); }
virtual ScalarResult SetValue(const nsAString& aValue) { return HandleUnsupported(); }
virtual void SetValue(bool aValue) { mozilla::Unused << HandleUnsupported(); }
virtual void AddValue(uint32_t aValue) { mozilla::Unused << HandleUnsupported(); }
virtual void SetMaximum(uint32_t aValue) { mozilla::Unused << HandleUnsupported(); }
// GetValue is used to get the value of the scalar when persisting it to JS.
virtual nsresult GetValue(nsCOMPtr<nsIVariant>& aResult) const = 0;
// To measure the memory stats.
virtual size_t SizeOfIncludingThis(mozilla::MallocSizeOf aMallocSizeOf) const = 0;
private:
ScalarResult HandleUnsupported() const;
};
ScalarResult
ScalarBase::HandleUnsupported() const
{
MOZ_ASSERT(false, "This operation is not support for this scalar type.");
return ScalarResult::OperationNotSupported;
}
/**
* The implementation for the unsigned int scalar type.
*/
class ScalarUnsigned : public ScalarBase
{
public:
using ScalarBase::SetValue;
ScalarUnsigned() : mStorage(0) {};
~ScalarUnsigned() override = default;
ScalarResult SetValue(nsIVariant* aValue) final;
void SetValue(uint32_t aValue) final;
ScalarResult AddValue(nsIVariant* aValue) final;
void AddValue(uint32_t aValue) final;
ScalarResult SetMaximum(nsIVariant* aValue) final;
void SetMaximum(uint32_t aValue) final;
nsresult GetValue(nsCOMPtr<nsIVariant>& aResult) const final;
size_t SizeOfIncludingThis(mozilla::MallocSizeOf aMallocSizeOf) const final;
private:
uint32_t mStorage;
ScalarResult CheckInput(nsIVariant* aValue);
// Prevent copying.
ScalarUnsigned(const ScalarUnsigned& aOther) = delete;
void operator=(const ScalarUnsigned& aOther) = delete;
};
ScalarResult
ScalarUnsigned::SetValue(nsIVariant* aValue)
{
ScalarResult sr = CheckInput(aValue);
if (sr == ScalarResult::UnsignedNegativeValue) {
return sr;
}
if (NS_FAILED(aValue->GetAsUint32(&mStorage))) {
return ScalarResult::InvalidValue;
}
return sr;
}
void
ScalarUnsigned::SetValue(uint32_t aValue)
{
mStorage = aValue;
}
ScalarResult
ScalarUnsigned::AddValue(nsIVariant* aValue)
{
ScalarResult sr = CheckInput(aValue);
if (sr == ScalarResult::UnsignedNegativeValue) {
return sr;
}
uint32_t newAddend = 0;
nsresult rv = aValue->GetAsUint32(&newAddend);
if (NS_FAILED(rv)) {
return ScalarResult::InvalidValue;
}
mStorage += newAddend;
return sr;
}
void
ScalarUnsigned::AddValue(uint32_t aValue)
{
mStorage += aValue;
}
ScalarResult
ScalarUnsigned::SetMaximum(nsIVariant* aValue)
{
ScalarResult sr = CheckInput(aValue);
if (sr == ScalarResult::UnsignedNegativeValue) {
return sr;
}
uint32_t newValue = 0;
nsresult rv = aValue->GetAsUint32(&newValue);
if (NS_FAILED(rv)) {
return ScalarResult::InvalidValue;
}
if (newValue > mStorage) {
mStorage = newValue;
}
return sr;
}
void
ScalarUnsigned::SetMaximum(uint32_t aValue)
{
if (aValue > mStorage) {
mStorage = aValue;
}
}
nsresult
ScalarUnsigned::GetValue(nsCOMPtr<nsIVariant>& aResult) const
{
nsCOMPtr<nsIWritableVariant> outVar(new nsVariant());
nsresult rv = outVar->SetAsUint32(mStorage);
if (NS_FAILED(rv)) {
return rv;
}
aResult = outVar.forget();
return NS_OK;
}
size_t
ScalarUnsigned::SizeOfIncludingThis(mozilla::MallocSizeOf aMallocSizeOf) const
{
return aMallocSizeOf(this);
}
ScalarResult
ScalarUnsigned::CheckInput(nsIVariant* aValue)
{
// If this is a floating point value/double, we will probably get truncated.
uint16_t type;
aValue->GetDataType(&type);
if (type == nsIDataType::VTYPE_FLOAT ||
type == nsIDataType::VTYPE_DOUBLE) {
return ScalarResult::UnsignedTruncatedValue;
}
int32_t signedTest;
// If we're able to cast the number to an int, check its sign.
// Warn the user if he's trying to set the unsigned scalar to a negative
// number.
if (NS_SUCCEEDED(aValue->GetAsInt32(&signedTest)) &&
signedTest < 0) {
return ScalarResult::UnsignedNegativeValue;
}
return ScalarResult::Ok;
}
/**
* The implementation for the string scalar type.
*/
class ScalarString : public ScalarBase
{
public:
using ScalarBase::SetValue;
ScalarString() : mStorage(EmptyString()) {};
~ScalarString() override = default;
ScalarResult SetValue(nsIVariant* aValue) final;
ScalarResult SetValue(const nsAString& aValue) final;
nsresult GetValue(nsCOMPtr<nsIVariant>& aResult) const final;
size_t SizeOfIncludingThis(mozilla::MallocSizeOf aMallocSizeOf) const final;
private:
nsString mStorage;
// Prevent copying.
ScalarString(const ScalarString& aOther) = delete;
void operator=(const ScalarString& aOther) = delete;
};
ScalarResult
ScalarString::SetValue(nsIVariant* aValue)
{
// Check that we got the correct data type.
uint16_t type;
aValue->GetDataType(&type);
if (type != nsIDataType::VTYPE_CHAR &&
type != nsIDataType::VTYPE_WCHAR &&
type != nsIDataType::VTYPE_DOMSTRING &&
type != nsIDataType::VTYPE_CHAR_STR &&
type != nsIDataType::VTYPE_WCHAR_STR &&
type != nsIDataType::VTYPE_STRING_SIZE_IS &&
type != nsIDataType::VTYPE_WSTRING_SIZE_IS &&
type != nsIDataType::VTYPE_UTF8STRING &&
type != nsIDataType::VTYPE_CSTRING &&
type != nsIDataType::VTYPE_ASTRING) {
return ScalarResult::InvalidType;
}
nsAutoString convertedString;
nsresult rv = aValue->GetAsAString(convertedString);
if (NS_FAILED(rv)) {
return ScalarResult::InvalidValue;
}
return SetValue(convertedString);
};
ScalarResult
ScalarString::SetValue(const nsAString& aValue)
{
mStorage = Substring(aValue, 0, kMaximumStringValueLength);
if (aValue.Length() > kMaximumStringValueLength) {
return ScalarResult::StringTooLong;
}
return ScalarResult::Ok;
}
nsresult
ScalarString::GetValue(nsCOMPtr<nsIVariant>& aResult) const
{
nsCOMPtr<nsIWritableVariant> outVar(new nsVariant());
nsresult rv = outVar->SetAsAString(mStorage);
if (NS_FAILED(rv)) {
return rv;
}
aResult = outVar.forget();
return NS_OK;
}
size_t
ScalarString::SizeOfIncludingThis(mozilla::MallocSizeOf aMallocSizeOf) const
{
size_t n = aMallocSizeOf(this);
n+= mStorage.SizeOfExcludingThisIfUnshared(aMallocSizeOf);
return n;
}
/**
* The implementation for the boolean scalar type.
*/
class ScalarBoolean : public ScalarBase
{
public:
using ScalarBase::SetValue;
ScalarBoolean() : mStorage(false) {};
~ScalarBoolean() override = default;
ScalarResult SetValue(nsIVariant* aValue) final;
void SetValue(bool aValue) final;
nsresult GetValue(nsCOMPtr<nsIVariant>& aResult) const final;
size_t SizeOfIncludingThis(mozilla::MallocSizeOf aMallocSizeOf) const final;
private:
bool mStorage;
// Prevent copying.
ScalarBoolean(const ScalarBoolean& aOther) = delete;
void operator=(const ScalarBoolean& aOther) = delete;
};
ScalarResult
ScalarBoolean::SetValue(nsIVariant* aValue)
{
// Check that we got the correct data type.
uint16_t type;
aValue->GetDataType(&type);
if (type != nsIDataType::VTYPE_BOOL &&
type != nsIDataType::VTYPE_INT8 &&
type != nsIDataType::VTYPE_INT16 &&
type != nsIDataType::VTYPE_INT32 &&
type != nsIDataType::VTYPE_INT64 &&
type != nsIDataType::VTYPE_UINT8 &&
type != nsIDataType::VTYPE_UINT16 &&
type != nsIDataType::VTYPE_UINT32 &&
type != nsIDataType::VTYPE_UINT64) {
return ScalarResult::InvalidType;
}
if (NS_FAILED(aValue->GetAsBool(&mStorage))) {
return ScalarResult::InvalidValue;
}
return ScalarResult::Ok;
};
void
ScalarBoolean::SetValue(bool aValue)
{
mStorage = aValue;
}
nsresult
ScalarBoolean::GetValue(nsCOMPtr<nsIVariant>& aResult) const
{
nsCOMPtr<nsIWritableVariant> outVar(new nsVariant());
nsresult rv = outVar->SetAsBool(mStorage);
if (NS_FAILED(rv)) {
return rv;
}
aResult = outVar.forget();
return NS_OK;
}
size_t
ScalarBoolean::SizeOfIncludingThis(mozilla::MallocSizeOf aMallocSizeOf) const
{
return aMallocSizeOf(this);
}
/**
* Allocate a scalar class given the scalar info.
*
* @param aInfo The informations for the scalar coming from the definition file.
* @return nullptr if the scalar type is unknown, otherwise a valid pointer to the
* scalar type.
*/
ScalarBase*
internal_ScalarAllocate(uint32_t aScalarKind)
{
ScalarBase* scalar = nullptr;
switch (aScalarKind) {
case nsITelemetry::SCALAR_TYPE_COUNT:
scalar = new ScalarUnsigned();
break;
case nsITelemetry::SCALAR_TYPE_STRING:
scalar = new ScalarString();
break;
case nsITelemetry::SCALAR_TYPE_BOOLEAN:
scalar = new ScalarBoolean();
break;
default:
MOZ_ASSERT(false, "Invalid scalar type");
}
return scalar;
}
/**
* The implementation for the keyed scalar type.
*/
class KeyedScalar
{
public:
typedef mozilla::Pair<nsCString, nsCOMPtr<nsIVariant>> KeyValuePair;
explicit KeyedScalar(uint32_t aScalarKind) : mScalarKind(aScalarKind) {};
~KeyedScalar() = default;
// Set, Add and SetMaximum functions as described in the Telemetry IDL.
// These methods implicitly instantiate a Scalar[*] for each key.
ScalarResult SetValue(const nsAString& aKey, nsIVariant* aValue);
ScalarResult AddValue(const nsAString& aKey, nsIVariant* aValue);
ScalarResult SetMaximum(const nsAString& aKey, nsIVariant* aValue);
// Convenience methods used by the C++ API.
void SetValue(const nsAString& aKey, uint32_t aValue);
void SetValue(const nsAString& aKey, bool aValue);
void AddValue(const nsAString& aKey, uint32_t aValue);
void SetMaximum(const nsAString& aKey, uint32_t aValue);
// GetValue is used to get the key-value pairs stored in the keyed scalar
// when persisting it to JS.
nsresult GetValue(nsTArray<KeyValuePair>& aValues) const;
// To measure the memory stats.
size_t SizeOfIncludingThis(mozilla::MallocSizeOf aMallocSizeOf);
private:
typedef nsClassHashtable<nsCStringHashKey, ScalarBase> ScalarKeysMapType;
ScalarKeysMapType mScalarKeys;
const uint32_t mScalarKind;
ScalarResult GetScalarForKey(const nsAString& aKey, ScalarBase** aRet);
};
ScalarResult
KeyedScalar::SetValue(const nsAString& aKey, nsIVariant* aValue)
{
ScalarBase* scalar = nullptr;
ScalarResult sr = GetScalarForKey(aKey, &scalar);
if (sr != ScalarResult::Ok) {
return sr;
}
return scalar->SetValue(aValue);
}
ScalarResult
KeyedScalar::AddValue(const nsAString& aKey, nsIVariant* aValue)
{
ScalarBase* scalar = nullptr;
ScalarResult sr = GetScalarForKey(aKey, &scalar);
if (sr != ScalarResult::Ok) {
return sr;
}
return scalar->AddValue(aValue);
}
ScalarResult
KeyedScalar::SetMaximum(const nsAString& aKey, nsIVariant* aValue)
{
ScalarBase* scalar = nullptr;
ScalarResult sr = GetScalarForKey(aKey, &scalar);
if (sr != ScalarResult::Ok) {
return sr;
}
return scalar->SetMaximum(aValue);
}
void
KeyedScalar::SetValue(const nsAString& aKey, uint32_t aValue)
{
ScalarBase* scalar = nullptr;
ScalarResult sr = GetScalarForKey(aKey, &scalar);
if (sr != ScalarResult::Ok) {
MOZ_ASSERT(false, "Key too long or too many keys are recorded in the scalar.");
return;
}
return scalar->SetValue(aValue);
}
void
KeyedScalar::SetValue(const nsAString& aKey, bool aValue)
{
ScalarBase* scalar = nullptr;
ScalarResult sr = GetScalarForKey(aKey, &scalar);
if (sr != ScalarResult::Ok) {
MOZ_ASSERT(false, "Key too long or too many keys are recorded in the scalar.");
return;
}
return scalar->SetValue(aValue);
}
void
KeyedScalar::AddValue(const nsAString& aKey, uint32_t aValue)
{
ScalarBase* scalar = nullptr;
ScalarResult sr = GetScalarForKey(aKey, &scalar);
if (sr != ScalarResult::Ok) {
MOZ_ASSERT(false, "Key too long or too many keys are recorded in the scalar.");
return;
}
return scalar->AddValue(aValue);
}
void
KeyedScalar::SetMaximum(const nsAString& aKey, uint32_t aValue)
{
ScalarBase* scalar = nullptr;
ScalarResult sr = GetScalarForKey(aKey, &scalar);
if (sr != ScalarResult::Ok) {
MOZ_ASSERT(false, "Key too long or too many keys are recorded in the scalar.");
return;
}
return scalar->SetMaximum(aValue);
}
/**
* Get a key-value array with the values for the Keyed Scalar.
* @param aValue The array that will hold the key-value pairs.
* @return {nsresult} NS_OK or an error value as reported by the
* the specific scalar objects implementations (e.g.
* ScalarUnsigned).
*/
nsresult
KeyedScalar::GetValue(nsTArray<KeyValuePair>& aValues) const
{
for (auto iter = mScalarKeys.ConstIter(); !iter.Done(); iter.Next()) {
ScalarBase* scalar = static_cast<ScalarBase*>(iter.Data());
// Get the scalar value.
nsCOMPtr<nsIVariant> scalarValue;
nsresult rv = scalar->GetValue(scalarValue);
if (NS_FAILED(rv)) {
return rv;
}
// Append it to value list.
aValues.AppendElement(mozilla::MakePair(nsCString(iter.Key()), scalarValue));
}
return NS_OK;
}
/**
* Get the scalar for the referenced key.
* If there's no such key, instantiate a new Scalar object with the
* same type of the Keyed scalar and create the key.
*/
ScalarResult
KeyedScalar::GetScalarForKey(const nsAString& aKey, ScalarBase** aRet)
{
if (aKey.IsEmpty()) {
return ScalarResult::KeyIsEmpty;
}
if (aKey.Length() >= kMaximumKeyStringLength) {
return ScalarResult::KeyTooLong;
}
if (mScalarKeys.Count() >= kMaximumNumberOfKeys) {
return ScalarResult::TooManyKeys;
}
NS_ConvertUTF16toUTF8 utf8Key(aKey);
ScalarBase* scalar = nullptr;
if (mScalarKeys.Get(utf8Key, &scalar)) {
*aRet = scalar;
return ScalarResult::Ok;
}
scalar = internal_ScalarAllocate(mScalarKind);
if (!scalar) {
return ScalarResult::InvalidType;
}
mScalarKeys.Put(utf8Key, scalar);
*aRet = scalar;
return ScalarResult::Ok;
}
size_t
KeyedScalar::SizeOfIncludingThis(mozilla::MallocSizeOf aMallocSizeOf)
{
size_t n = aMallocSizeOf(this);
for (auto iter = mScalarKeys.Iter(); !iter.Done(); iter.Next()) {
ScalarBase* scalar = static_cast<ScalarBase*>(iter.Data());
n += scalar->SizeOfIncludingThis(aMallocSizeOf);
}
return n;
}
typedef nsUint32HashKey ScalarIDHashKey;
typedef nsUint32HashKey ProcessIDHashKey;
typedef nsClassHashtable<ScalarIDHashKey, ScalarBase> ScalarStorageMapType;
typedef nsClassHashtable<ScalarIDHashKey, KeyedScalar> KeyedScalarStorageMapType;
typedef nsClassHashtable<ProcessIDHashKey, ScalarStorageMapType> ProcessesScalarsMapType;
typedef nsClassHashtable<ProcessIDHashKey, KeyedScalarStorageMapType> ProcessesKeyedScalarsMapType;
} // namespace
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
//
// PRIVATE STATE, SHARED BY ALL THREADS
namespace {
// Set to true once this global state has been initialized.
bool gInitDone = false;
bool gCanRecordBase;
bool gCanRecordExtended;
// The Name -> ID cache map.
ScalarMapType gScalarNameIDMap(kScalarCount);
// The (Process Id -> (Scalar ID -> Scalar Object)) map. This is a nsClassHashtable,
// it owns the scalar instances and takes care of deallocating them when they are
// removed from the map.
ProcessesScalarsMapType gScalarStorageMap;
// As above, for the keyed scalars.
ProcessesKeyedScalarsMapType gKeyedScalarStorageMap;
} // namespace
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
//
// PRIVATE: Function that may call JS code.
// NOTE: the functions in this section all run without protection from
// |gTelemetryScalarsMutex|. If they held the mutex, there would be the
// possibility of deadlock because the JS_ calls that they make may call
// back into the TelemetryScalar interface, hence trying to re-acquire the mutex.
//
// This means that these functions potentially race against threads, but
// that seems preferable to risking deadlock.
namespace {
/**
* Converts the error code to a human readable error message and prints it to the
* browser console.
*
* @param aScalarName The name of the scalar that raised the error.
* @param aSr The error code.
*/
void
internal_LogScalarError(const nsACString& aScalarName, ScalarResult aSr)
{
nsAutoString errorMessage;
AppendUTF8toUTF16(aScalarName, errorMessage);
switch (aSr) {
case ScalarResult::NotInitialized:
errorMessage.AppendLiteral(u" - Telemetry was not yet initialized.");
break;
case ScalarResult::CannotUnpackVariant:
errorMessage.AppendLiteral(u" - Cannot convert the provided JS value to nsIVariant.");
break;
case ScalarResult::CannotRecordInProcess:
errorMessage.AppendLiteral(u" - Cannot record the scalar in the current process.");
break;
case ScalarResult::KeyedTypeMismatch:
errorMessage.AppendLiteral(u" - Attempting to manage a keyed scalar as a scalar (or vice-versa).");
break;
case ScalarResult::UnknownScalar:
errorMessage.AppendLiteral(u" - Unknown scalar.");
break;
case ScalarResult::OperationNotSupported:
errorMessage.AppendLiteral(u" - The requested operation is not supported on this scalar.");
break;
case ScalarResult::InvalidType:
errorMessage.AppendLiteral(u" - Attempted to set the scalar to an invalid data type.");
break;
case ScalarResult::InvalidValue:
errorMessage.AppendLiteral(u" - Attempted to set the scalar to an incompatible value.");
break;
case ScalarResult::StringTooLong:
errorMessage.AppendLiteral(u" - Truncating scalar value to 50 characters.");
break;
case ScalarResult::KeyIsEmpty:
errorMessage.AppendLiteral(u" - The key must not be empty.");
break;
case ScalarResult::KeyTooLong:
errorMessage.AppendLiteral(u" - The key length must be limited to 70 characters.");
break;
case ScalarResult::TooManyKeys:
errorMessage.AppendLiteral(u" - Keyed scalars cannot have more than 100 keys.");
break;
case ScalarResult::UnsignedNegativeValue:
errorMessage.AppendLiteral(u" - Trying to set an unsigned scalar to a negative number.");
break;
case ScalarResult::UnsignedTruncatedValue:
errorMessage.AppendLiteral(u" - Truncating float/double number.");
break;
default:
// Nothing.
return;
}
LogToBrowserConsole(nsIScriptError::warningFlag, errorMessage);
}
} // namespace
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
//
// PRIVATE: thread-unsafe helpers for the external interface
namespace {
bool
internal_CanRecordBase()
{
return gCanRecordBase;
}
bool
internal_CanRecordExtended()
{
return gCanRecordExtended;
}
/**
* Check if the given scalar is a keyed scalar.
*
* @param aId The scalar identifier.
* @return true if aId refers to a keyed scalar, false otherwise.
*/
bool
internal_IsKeyedScalar(const ScalarKey& aId)
{
return internal_GetScalarInfo(aId).keyed;
}
/**
* Check if we're allowed to record the given scalar in the current
* process.
*
* @param aId The scalar identifier.
* @return true if the scalar is allowed to be recorded in the current process, false
* otherwise.
*/
bool
internal_CanRecordProcess(const ScalarKey& aId)
{
const BaseScalarInfo &info = internal_GetScalarInfo(aId);
return CanRecordInProcess(info.record_in_processes, XRE_GetProcessType());
}
bool
internal_CanRecordForScalarID(const ScalarKey& aId)
{
// Get the scalar info from the id.
const BaseScalarInfo &info = internal_GetScalarInfo(aId);
// Can we record at all?
bool canRecordBase = internal_CanRecordBase();
if (!canRecordBase) {
return false;
}
bool canRecordDataset = CanRecordDataset(info.dataset,
canRecordBase,
internal_CanRecordExtended());
if (!canRecordDataset) {
return false;
}
return true;
}
/**
* Check if we are allowed to record the provided scalar.
*
* @param aId The scalar identifier.
* @param aKeyed Are we attempting to write a keyed scalar?
* @return ScalarResult::Ok if we can record, an error code otherwise.
*/
ScalarResult
internal_CanRecordScalar(const ScalarKey& aId, bool aKeyed)
{
// Make sure that we have a keyed scalar if we are trying to change one.
if (internal_IsKeyedScalar(aId) != aKeyed) {
return ScalarResult::KeyedTypeMismatch;
}
// Are we allowed to record this scalar based on the current Telemetry
// settings?
if (!internal_CanRecordForScalarID(aId)) {
return ScalarResult::CannotRecordDataset;
}
// Can we record in this process?
if (!internal_CanRecordProcess(aId)) {
return ScalarResult::CannotRecordInProcess;
}
return ScalarResult::Ok;
}
/**
* Get the scalar enum id from the scalar name.
*
* @param aName The scalar name.
* @param aId The output variable to contain the enum.
* @return
* NS_ERROR_FAILURE if this was called before init is completed.
* NS_ERROR_INVALID_ARG if the name can't be found in the scalar definitions.
* NS_OK if the scalar was found and aId contains a valid enum id.
*/
nsresult
internal_GetEnumByScalarName(const nsACString& aName, ScalarKey* aId)
{
if (!gInitDone) {
return NS_ERROR_FAILURE;
}
CharPtrEntryType *entry = gScalarNameIDMap.GetEntry(PromiseFlatCString(aName).get());
if (!entry) {
return NS_ERROR_INVALID_ARG;
}
*aId = entry->mData;
return NS_OK;
}
/**
* Get a scalar object by its enum id. This implicitly allocates the scalar
* object in the storage if it wasn't previously allocated.
*
* @param aId The scalar identifier.
* @param aProcessStorage This drives the selection of the map to use to store
* the scalar data coming from child processes. This is only meaningful when
* this function is called in parent process. If that's the case, if
* this is not |GeckoProcessType_Default|, the process id is used to
* allocate and store the scalars.
* @param aRes The output variable that stores scalar object.
* @return
* NS_ERROR_INVALID_ARG if the scalar id is unknown.
* NS_ERROR_NOT_AVAILABLE if the scalar is expired.
* NS_OK if the scalar was found. If that's the case, aResult contains a
* valid pointer to a scalar type.
*/
nsresult
internal_GetScalarByEnum(const ScalarKey& aId,
ProcessID aProcessStorage,
ScalarBase** aRet)
{
if (!internal_IsValidId(aId)) {
MOZ_ASSERT(false, "Requested a scalar with an invalid id.");
return NS_ERROR_INVALID_ARG;
}
const BaseScalarInfo &info = internal_GetScalarInfo(aId);
// Dynamic scalars fixup: they are always stored in the "dynamic" process.
if (aId.dynamic) {
aProcessStorage = ProcessID::Dynamic;
}
ScalarBase* scalar = nullptr;
ScalarStorageMapType* scalarStorage = nullptr;
// Initialize the scalar storage to the parent storage. This will get
// set to the child storage if needed.
uint32_t storageId = static_cast<uint32_t>(aProcessStorage);
// Get the process-specific storage or create one if it's not
// available.
if (!gScalarStorageMap.Get(storageId, &scalarStorage)) {
scalarStorage = new ScalarStorageMapType();
gScalarStorageMap.Put(storageId, scalarStorage);
}
// Check if the scalar is already allocated in the parent or in the child storage.
if (scalarStorage->Get(aId.id, &scalar)) {
*aRet = scalar;
return NS_OK;
}
if (IsExpiredVersion(info.expiration())) {
return NS_ERROR_NOT_AVAILABLE;
}
scalar = internal_ScalarAllocate(info.kind);
if (!scalar) {
return NS_ERROR_INVALID_ARG;
}
scalarStorage->Put(aId.id, scalar);
*aRet = scalar;
return NS_OK;
}
/**
* Update the scalar with the provided value. This is used by the JS API.
*
* @param aName The scalar name.
* @param aType The action type for updating the scalar.
* @param aValue The value to use for updating the scalar.
* @return a ScalarResult error value.
*/
ScalarResult
internal_UpdateScalar(const nsACString& aName, ScalarActionType aType,
nsIVariant* aValue)
{
ScalarKey uniqueId;
nsresult rv = internal_GetEnumByScalarName(aName, &uniqueId);
if (NS_FAILED(rv)) {
return (rv == NS_ERROR_FAILURE) ?
ScalarResult::NotInitialized : ScalarResult::UnknownScalar;
}
ScalarResult sr = internal_CanRecordScalar(uniqueId, false);
if (sr != ScalarResult::Ok) {
if (sr == ScalarResult::CannotRecordDataset) {
return ScalarResult::Ok;
}
return sr;
}
// Accumulate in the child process if needed.
if (!XRE_IsParentProcess()) {
const BaseScalarInfo &info = internal_GetScalarInfo(uniqueId);
// Convert the nsIVariant to a Variant.
mozilla::Maybe<ScalarVariant> variantValue;
sr = GetVariantFromIVariant(aValue, info.kind, variantValue);
if (sr != ScalarResult::Ok) {
MOZ_ASSERT(false, "Unable to convert nsIVariant to mozilla::Variant.");
return sr;
}
TelemetryIPCAccumulator::RecordChildScalarAction(
uniqueId.id, uniqueId.dynamic, aType, variantValue.ref());
return ScalarResult::Ok;
}
// Finally get the scalar.
ScalarBase* scalar = nullptr;
rv = internal_GetScalarByEnum(uniqueId, ProcessID::Parent, &scalar);
if (NS_FAILED(rv)) {
// Don't throw on expired scalars.
if (rv == NS_ERROR_NOT_AVAILABLE) {
return ScalarResult::Ok;
}
return ScalarResult::UnknownScalar;
}
if (aType == ScalarActionType::eAdd) {
return scalar->AddValue(aValue);
}
if (aType == ScalarActionType::eSet) {
return scalar->SetValue(aValue);
}
return scalar->SetMaximum(aValue);
}
} // namespace
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
//
// PRIVATE: thread-unsafe helpers for the keyed scalars
namespace {
/**
* Get a keyed scalar object by its enum id. This implicitly allocates the keyed
* scalar object in the storage if it wasn't previously allocated.
*
* @param aId The scalar identifier.
* @param aProcessStorage This drives the selection of the map to use to store
* the scalar data coming from child processes. This is only meaningful when
* this function is called in parent process. If that's the case, if
* this is not |GeckoProcessType_Default|, the process id is used to
* allocate and store the scalars.
* @param aRet The output variable that stores scalar object.
* @return
* NS_ERROR_INVALID_ARG if the scalar id is unknown or a this is a keyed string
* scalar.
* NS_ERROR_NOT_AVAILABLE if the scalar is expired.
* NS_OK if the scalar was found. If that's the case, aResult contains a
* valid pointer to a scalar type.
*/
nsresult
internal_GetKeyedScalarByEnum(const ScalarKey& aId,
ProcessID aProcessStorage,
KeyedScalar** aRet)
{
if (!internal_IsValidId(aId)) {
MOZ_ASSERT(false, "Requested a keyed scalar with an invalid id.");
return NS_ERROR_INVALID_ARG;
}
const BaseScalarInfo &info = internal_GetScalarInfo(aId);
// Dynamic scalars fixup: they are always stored in the "dynamic" process.
if (aId.dynamic) {
aProcessStorage = ProcessID::Dynamic;
}
KeyedScalar* scalar = nullptr;
KeyedScalarStorageMapType* scalarStorage = nullptr;
// Initialize the scalar storage to the parent storage. This will get
// set to the child storage if needed.
uint32_t storageId = static_cast<uint32_t>(aProcessStorage);
// Get the process-specific storage or create one if it's not
// available.
if (!gKeyedScalarStorageMap.Get(storageId, &scalarStorage)) {
scalarStorage = new KeyedScalarStorageMapType();
gKeyedScalarStorageMap.Put(storageId, scalarStorage);
}
if (scalarStorage->Get(aId.id, &scalar)) {
*aRet = scalar;
return NS_OK;
}
if (IsExpiredVersion(info.expiration())) {
return NS_ERROR_NOT_AVAILABLE;
}
// We don't currently support keyed string scalars. Disable them.
if (info.kind == nsITelemetry::SCALAR_TYPE_STRING) {
MOZ_ASSERT(false, "Keyed string scalars are not currently supported.");
return NS_ERROR_INVALID_ARG;
}
scalar = new KeyedScalar(info.kind);
if (!scalar) {
return NS_ERROR_INVALID_ARG;
}
scalarStorage->Put(aId.id, scalar);
*aRet = scalar;
return NS_OK;
}
/**
* Update the keyed scalar with the provided value. This is used by the JS API.
*
* @param aName The scalar name.
* @param aKey The key name.
* @param aType The action type for updating the scalar.
* @param aValue The value to use for updating the scalar.
* @return a ScalarResult error value.
*/
ScalarResult
internal_UpdateKeyedScalar(const nsACString& aName, const nsAString& aKey,
ScalarActionType aType, nsIVariant* aValue)
{
ScalarKey uniqueId;
nsresult rv = internal_GetEnumByScalarName(aName, &uniqueId);
if (NS_FAILED(rv)) {
return (rv == NS_ERROR_FAILURE) ?
ScalarResult::NotInitialized : ScalarResult::UnknownScalar;
}
ScalarResult sr = internal_CanRecordScalar(uniqueId, true);
if (sr != ScalarResult::Ok) {
if (sr == ScalarResult::CannotRecordDataset) {
return ScalarResult::Ok;
}
return sr;
}
// Accumulate in the child process if needed.
if (!XRE_IsParentProcess()) {
const BaseScalarInfo &info = internal_GetScalarInfo(uniqueId);
// Convert the nsIVariant to a Variant.
mozilla::Maybe<ScalarVariant> variantValue;
sr = GetVariantFromIVariant(aValue, info.kind, variantValue);
if (sr != ScalarResult::Ok) {
MOZ_ASSERT(false, "Unable to convert nsIVariant to mozilla::Variant.");
return sr;
}
TelemetryIPCAccumulator::RecordChildKeyedScalarAction(
uniqueId.id, uniqueId.dynamic, aKey, aType, variantValue.ref());
return ScalarResult::Ok;
}
// Finally get the scalar.
KeyedScalar* scalar = nullptr;
rv = internal_GetKeyedScalarByEnum(uniqueId, ProcessID::Parent, &scalar);
if (NS_FAILED(rv)) {
// Don't throw on expired scalars.
if (rv == NS_ERROR_NOT_AVAILABLE) {
return ScalarResult::Ok;
}
return ScalarResult::UnknownScalar;
}
if (aType == ScalarActionType::eAdd) {
return scalar->AddValue(aKey, aValue);
}
if (aType == ScalarActionType::eSet) {
return scalar->SetValue(aKey, aValue);
}
return scalar->SetMaximum(aKey, aValue);
}
/**
* Helper function to convert an array of |DynamicScalarInfo|
* to |DynamicScalarDefinition| used by the IPC calls.
*/
void
internal_DynamicScalarToIPC(const nsTArray<DynamicScalarInfo>& aDynamicScalarInfos,
nsTArray<DynamicScalarDefinition>& aIPCDefs)
{
for (auto info : aDynamicScalarInfos) {
DynamicScalarDefinition stubDefinition;
stubDefinition.type = info.kind;
stubDefinition.dataset = info.dataset;
stubDefinition.expired = info.mDynamicExpiration;
stubDefinition.keyed = info.keyed;
stubDefinition.name = info.mDynamicName;
aIPCDefs.AppendElement(stubDefinition);
}
}
/**
* Broadcasts the dynamic scalar definitions to all the other
* content processes.
*/
void
internal_BroadcastDefinitions(const nsTArray<DynamicScalarInfo>& scalarInfos)
{
nsTArray<mozilla::dom::ContentParent*> parents;
mozilla::dom::ContentParent::GetAll(parents);
if (!parents.Length()) {
return;
}
// Convert the internal scalar representation to a stripped down IPC one.
nsTArray<DynamicScalarDefinition> ipcDefinitions;
internal_DynamicScalarToIPC(scalarInfos, ipcDefinitions);
// Broadcast the definitions to the other content processes.
for (auto parent : parents) {
mozilla::Unused << parent->SendAddDynamicScalars(ipcDefinitions);
}
}
ScalarResult
internal_RegisterScalars(const StaticMutexAutoLock& lock,
const nsTArray<DynamicScalarInfo>& scalarInfos)
{
// Check that none of the events are already registered.
for (auto& info : scalarInfos) {
if (gScalarNameIDMap.GetEntry(info.name())) {
return ScalarResult::AlreadyRegistered;
}
}
// Register the new scalars.
if (!gDynamicScalarInfo) {
gDynamicScalarInfo = new nsTArray<DynamicScalarInfo>();
}
for (auto scalarInfo : scalarInfos) {
gDynamicScalarInfo->AppendElement(scalarInfo);
uint32_t scalarId = gDynamicScalarInfo->Length() - 1;
CharPtrEntryType *entry = gScalarNameIDMap.PutEntry(scalarInfo.name());
entry->mData = ScalarKey{scalarId, true};
}
return ScalarResult::Ok;
}
} // namespace
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
//
// EXTERNALLY VISIBLE FUNCTIONS in namespace TelemetryScalars::
// This is a StaticMutex rather than a plain Mutex (1) so that
// it gets initialised in a thread-safe manner the first time
// it is used, and (2) because it is never de-initialised, and
// a normal Mutex would show up as a leak in BloatView. StaticMutex
// also has the "OffTheBooks" property, so it won't show as a leak
// in BloatView.
// Another reason to use a StaticMutex instead of a plain Mutex is
// that, due to the nature of Telemetry, we cannot rely on having a
// mutex initialized in InitializeGlobalState. Unfortunately, we
// cannot make sure that no other function is called before this point.
static StaticMutex gTelemetryScalarsMutex;
void
TelemetryScalar::InitializeGlobalState(bool aCanRecordBase, bool aCanRecordExtended)
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
MOZ_ASSERT(!gInitDone, "TelemetryScalar::InitializeGlobalState "
"may only be called once");
gCanRecordBase = aCanRecordBase;
gCanRecordExtended = aCanRecordExtended;
// Populate the static scalar name->id cache. Note that the scalar names are
// statically allocated and come from the automatically generated TelemetryScalarData.h.
uint32_t scalarCount = static_cast<uint32_t>(mozilla::Telemetry::ScalarID::ScalarCount);
for (uint32_t i = 0; i < scalarCount; i++) {
CharPtrEntryType *entry = gScalarNameIDMap.PutEntry(gScalars[i].name());
entry->mData = ScalarKey{i, false};
}
gInitDone = true;
}
void
TelemetryScalar::DeInitializeGlobalState()
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
gCanRecordBase = false;
gCanRecordExtended = false;
gScalarNameIDMap.Clear();
gScalarStorageMap.Clear();
gKeyedScalarStorageMap.Clear();
gDynamicScalarInfo = nullptr;
gInitDone = false;
}
void
TelemetryScalar::SetCanRecordBase(bool b)
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
gCanRecordBase = b;
}
void
TelemetryScalar::SetCanRecordExtended(bool b) {
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
gCanRecordExtended = b;
}
/**
* Adds the value to the given scalar.
*
* @param aName The scalar name.
* @param aVal The numeric value to add to the scalar.
* @param aCx The JS context.
* @return NS_OK (always) so that the JS API call doesn't throw. In case of errors,
* a warning level message is printed in the browser console.
*/
nsresult
TelemetryScalar::Add(const nsACString& aName, JS::HandleValue aVal, JSContext* aCx)
{
// Unpack the aVal to nsIVariant. This uses the JS context.
nsCOMPtr<nsIVariant> unpackedVal;
nsresult rv =
nsContentUtils::XPConnect()->JSToVariant(aCx, aVal, getter_AddRefs(unpackedVal));
if (NS_FAILED(rv)) {
internal_LogScalarError(aName, ScalarResult::CannotUnpackVariant);
return NS_OK;
}
ScalarResult sr;
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
sr = internal_UpdateScalar(aName, ScalarActionType::eAdd, unpackedVal);
}
// Warn the user about the error if we need to.
if (sr != ScalarResult::Ok) {
internal_LogScalarError(aName, sr);
}
return NS_OK;
}
/**
* Adds the value to the given scalar.
*
* @param aName The scalar name.
* @param aKey The key name.
* @param aVal The numeric value to add to the scalar.
* @param aCx The JS context.
* @return NS_OK (always) so that the JS API call doesn't throw. In case of errors,
* a warning level message is printed in the browser console.
*/
nsresult
TelemetryScalar::Add(const nsACString& aName, const nsAString& aKey, JS::HandleValue aVal,
JSContext* aCx)
{
// Unpack the aVal to nsIVariant. This uses the JS context.
nsCOMPtr<nsIVariant> unpackedVal;
nsresult rv =
nsContentUtils::XPConnect()->JSToVariant(aCx, aVal, getter_AddRefs(unpackedVal));
if (NS_FAILED(rv)) {
internal_LogScalarError(aName, ScalarResult::CannotUnpackVariant);
return NS_OK;
}
ScalarResult sr;
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
sr = internal_UpdateKeyedScalar(aName, aKey, ScalarActionType::eAdd, unpackedVal);
}
// Warn the user about the error if we need to.
if (sr != ScalarResult::Ok) {
internal_LogScalarError(aName, sr);
}
return NS_OK;
}
/**
* Adds the value to the given scalar.
*
* @param aId The scalar enum id.
* @param aVal The numeric value to add to the scalar.
*/
void
TelemetryScalar::Add(mozilla::Telemetry::ScalarID aId, uint32_t aValue)
{
if (NS_WARN_IF(!IsValidEnumId(aId))) {
MOZ_ASSERT_UNREACHABLE("Scalar usage requires valid ids.");
return;
}
ScalarKey uniqueId{static_cast<uint32_t>(aId), false};
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
if (internal_CanRecordScalar(uniqueId, false) != ScalarResult::Ok) {
// We can't record this scalar. Bail out.
return;
}
// Accumulate in the child process if needed.
if (!XRE_IsParentProcess()) {
TelemetryIPCAccumulator::RecordChildScalarAction(uniqueId.id, uniqueId.dynamic,
ScalarActionType::eAdd,
ScalarVariant(aValue));
return;
}
ScalarBase* scalar = nullptr;
nsresult rv = internal_GetScalarByEnum(uniqueId, ProcessID::Parent, &scalar);
if (NS_FAILED(rv)) {
return;
}
scalar->AddValue(aValue);
}
/**
* Adds the value to the given keyed scalar.
*
* @param aId The scalar enum id.
* @param aKey The key name.
* @param aVal The numeric value to add to the scalar.
*/
void
TelemetryScalar::Add(mozilla::Telemetry::ScalarID aId, const nsAString& aKey,
uint32_t aValue)
{
if (NS_WARN_IF(!IsValidEnumId(aId))) {
MOZ_ASSERT_UNREACHABLE("Scalar usage requires valid ids.");
return;
}
ScalarKey uniqueId{static_cast<uint32_t>(aId), false};
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
if (internal_CanRecordScalar(uniqueId, true) != ScalarResult::Ok) {
// We can't record this scalar. Bail out.
return;
}
// Accumulate in the child process if needed.
if (!XRE_IsParentProcess()) {
TelemetryIPCAccumulator::RecordChildKeyedScalarAction(uniqueId.id, uniqueId.dynamic,
aKey, ScalarActionType::eAdd, ScalarVariant(aValue));
return;
}
KeyedScalar* scalar = nullptr;
nsresult rv = internal_GetKeyedScalarByEnum(uniqueId, ProcessID::Parent, &scalar);
if (NS_FAILED(rv)) {
return;
}
scalar->AddValue(aKey, aValue);
}
/**
* Sets the scalar to the given value.
*
* @param aName The scalar name.
* @param aVal The value to set the scalar to.
* @param aCx The JS context.
* @return NS_OK (always) so that the JS API call doesn't throw. In case of errors,
* a warning level message is printed in the browser console.
*/
nsresult
TelemetryScalar::Set(const nsACString& aName, JS::HandleValue aVal, JSContext* aCx)
{
// Unpack the aVal to nsIVariant. This uses the JS context.
nsCOMPtr<nsIVariant> unpackedVal;
nsresult rv =
nsContentUtils::XPConnect()->JSToVariant(aCx, aVal, getter_AddRefs(unpackedVal));
if (NS_FAILED(rv)) {
internal_LogScalarError(aName, ScalarResult::CannotUnpackVariant);
return NS_OK;
}
ScalarResult sr;
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
sr = internal_UpdateScalar(aName, ScalarActionType::eSet, unpackedVal);
}
// Warn the user about the error if we need to.
if (sr != ScalarResult::Ok) {
internal_LogScalarError(aName, sr);
}
return NS_OK;
}
/**
* Sets the keyed scalar to the given value.
*
* @param aName The scalar name.
* @param aKey The key name.
* @param aVal The value to set the scalar to.
* @param aCx The JS context.
* @return NS_OK (always) so that the JS API call doesn't throw. In case of errors,
* a warning level message is printed in the browser console.
*/
nsresult
TelemetryScalar::Set(const nsACString& aName, const nsAString& aKey, JS::HandleValue aVal,
JSContext* aCx)
{
// Unpack the aVal to nsIVariant. This uses the JS context.
nsCOMPtr<nsIVariant> unpackedVal;
nsresult rv =
nsContentUtils::XPConnect()->JSToVariant(aCx, aVal, getter_AddRefs(unpackedVal));
if (NS_FAILED(rv)) {
internal_LogScalarError(aName, ScalarResult::CannotUnpackVariant);
return NS_OK;
}
ScalarResult sr;
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
sr = internal_UpdateKeyedScalar(aName, aKey, ScalarActionType::eSet, unpackedVal);
}
// Warn the user about the error if we need to.
if (sr != ScalarResult::Ok) {
internal_LogScalarError(aName, sr);
}
return NS_OK;
}
/**
* Sets the scalar to the given numeric value.
*
* @param aId The scalar enum id.
* @param aValue The numeric, unsigned value to set the scalar to.
*/
void
TelemetryScalar::Set(mozilla::Telemetry::ScalarID aId, uint32_t aValue)
{
if (NS_WARN_IF(!IsValidEnumId(aId))) {
MOZ_ASSERT_UNREACHABLE("Scalar usage requires valid ids.");
return;
}
ScalarKey uniqueId{static_cast<uint32_t>(aId), false};
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
if (internal_CanRecordScalar(uniqueId, false) != ScalarResult::Ok) {
// We can't record this scalar. Bail out.
return;
}
// Accumulate in the child process if needed.
if (!XRE_IsParentProcess()) {
TelemetryIPCAccumulator::RecordChildScalarAction(uniqueId.id, uniqueId.dynamic,
ScalarActionType::eSet,
ScalarVariant(aValue));
return;
}
ScalarBase* scalar = nullptr;
nsresult rv = internal_GetScalarByEnum(uniqueId, ProcessID::Parent, &scalar);
if (NS_FAILED(rv)) {
return;
}
scalar->SetValue(aValue);
}
/**
* Sets the scalar to the given string value.
*
* @param aId The scalar enum id.
* @param aValue The string value to set the scalar to.
*/
void
TelemetryScalar::Set(mozilla::Telemetry::ScalarID aId, const nsAString& aValue)
{
if (NS_WARN_IF(!IsValidEnumId(aId))) {
MOZ_ASSERT_UNREACHABLE("Scalar usage requires valid ids.");
return;
}
ScalarKey uniqueId{static_cast<uint32_t>(aId), false};
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
if (internal_CanRecordScalar(uniqueId, false) != ScalarResult::Ok) {
// We can't record this scalar. Bail out.
return;
}
// Accumulate in the child process if needed.
if (!XRE_IsParentProcess()) {
TelemetryIPCAccumulator::RecordChildScalarAction(uniqueId.id, uniqueId.dynamic,
ScalarActionType::eSet,
ScalarVariant(nsString(aValue)));
return;
}
ScalarBase* scalar = nullptr;
nsresult rv = internal_GetScalarByEnum(uniqueId, ProcessID::Parent, &scalar);
if (NS_FAILED(rv)) {
return;
}
scalar->SetValue(aValue);
}
/**
* Sets the scalar to the given boolean value.
*
* @param aId The scalar enum id.
* @param aValue The boolean value to set the scalar to.
*/
void
TelemetryScalar::Set(mozilla::Telemetry::ScalarID aId, bool aValue)
{
if (NS_WARN_IF(!IsValidEnumId(aId))) {
MOZ_ASSERT_UNREACHABLE("Scalar usage requires valid ids.");
return;
}
ScalarKey uniqueId{static_cast<uint32_t>(aId), false};
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
if (internal_CanRecordScalar(uniqueId, false) != ScalarResult::Ok) {
// We can't record this scalar. Bail out.
return;
}
// Accumulate in the child process if needed.
if (!XRE_IsParentProcess()) {
TelemetryIPCAccumulator::RecordChildScalarAction(uniqueId.id, uniqueId.dynamic,
ScalarActionType::eSet,
ScalarVariant(aValue));
return;
}
ScalarBase* scalar = nullptr;
nsresult rv = internal_GetScalarByEnum(uniqueId, ProcessID::Parent, &scalar);
if (NS_FAILED(rv)) {
return;
}
scalar->SetValue(aValue);
}
/**
* Sets the keyed scalar to the given numeric value.
*
* @param aId The scalar enum id.
* @param aKey The scalar key.
* @param aValue The numeric, unsigned value to set the scalar to.
*/
void
TelemetryScalar::Set(mozilla::Telemetry::ScalarID aId, const nsAString& aKey,
uint32_t aValue)
{
if (NS_WARN_IF(!IsValidEnumId(aId))) {
MOZ_ASSERT_UNREACHABLE("Scalar usage requires valid ids.");
return;
}
ScalarKey uniqueId{static_cast<uint32_t>(aId), false};
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
if (internal_CanRecordScalar(uniqueId, true) != ScalarResult::Ok) {
// We can't record this scalar. Bail out.
return;
}
// Accumulate in the child process if needed.
if (!XRE_IsParentProcess()) {
TelemetryIPCAccumulator::RecordChildKeyedScalarAction(uniqueId.id, uniqueId.dynamic,
aKey, ScalarActionType::eSet, ScalarVariant(aValue));
return;
}
KeyedScalar* scalar = nullptr;
nsresult rv = internal_GetKeyedScalarByEnum(uniqueId, ProcessID::Parent, &scalar);
if (NS_FAILED(rv)) {
return;
}
scalar->SetValue(aKey, aValue);
}
/**
* Sets the scalar to the given boolean value.
*
* @param aId The scalar enum id.
* @param aKey The scalar key.
* @param aValue The boolean value to set the scalar to.
*/
void
TelemetryScalar::Set(mozilla::Telemetry::ScalarID aId, const nsAString& aKey,
bool aValue)
{
if (NS_WARN_IF(!IsValidEnumId(aId))) {
MOZ_ASSERT_UNREACHABLE("Scalar usage requires valid ids.");
return;
}
ScalarKey uniqueId{static_cast<uint32_t>(aId), false};
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
if (internal_CanRecordScalar(uniqueId, true) != ScalarResult::Ok) {
// We can't record this scalar. Bail out.
return;
}
// Accumulate in the child process if needed.
if (!XRE_IsParentProcess()) {
TelemetryIPCAccumulator::RecordChildKeyedScalarAction(uniqueId.id, uniqueId.dynamic,
aKey, ScalarActionType::eSet, ScalarVariant(aValue));
return;
}
KeyedScalar* scalar = nullptr;
nsresult rv = internal_GetKeyedScalarByEnum(uniqueId, ProcessID::Parent, &scalar);
if (NS_FAILED(rv)) {
return;
}
scalar->SetValue(aKey, aValue);
}
/**
* Sets the scalar to the maximum of the current and the passed value.
*
* @param aName The scalar name.
* @param aVal The numeric value to set the scalar to.
* @param aCx The JS context.
* @return NS_OK (always) so that the JS API call doesn't throw. In case of errors,
* a warning level message is printed in the browser console.
*/
nsresult
TelemetryScalar::SetMaximum(const nsACString& aName, JS::HandleValue aVal, JSContext* aCx)
{
// Unpack the aVal to nsIVariant. This uses the JS context.
nsCOMPtr<nsIVariant> unpackedVal;
nsresult rv =
nsContentUtils::XPConnect()->JSToVariant(aCx, aVal, getter_AddRefs(unpackedVal));
if (NS_FAILED(rv)) {
internal_LogScalarError(aName, ScalarResult::CannotUnpackVariant);
return NS_OK;
}
ScalarResult sr;
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
sr = internal_UpdateScalar(aName, ScalarActionType::eSetMaximum, unpackedVal);
}
// Warn the user about the error if we need to.
if (sr != ScalarResult::Ok) {
internal_LogScalarError(aName, sr);
}
return NS_OK;
}
/**
* Sets the scalar to the maximum of the current and the passed value.
*
* @param aName The scalar name.
* @param aKey The key name.
* @param aVal The numeric value to set the scalar to.
* @param aCx The JS context.
* @return NS_OK (always) so that the JS API call doesn't throw. In case of errors,
* a warning level message is printed in the browser console.
*/
nsresult
TelemetryScalar::SetMaximum(const nsACString& aName, const nsAString& aKey, JS::HandleValue aVal,
JSContext* aCx)
{
// Unpack the aVal to nsIVariant. This uses the JS context.
nsCOMPtr<nsIVariant> unpackedVal;
nsresult rv =
nsContentUtils::XPConnect()->JSToVariant(aCx, aVal, getter_AddRefs(unpackedVal));
if (NS_FAILED(rv)) {
internal_LogScalarError(aName, ScalarResult::CannotUnpackVariant);
return NS_OK;
}
ScalarResult sr;
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
sr = internal_UpdateKeyedScalar(aName, aKey, ScalarActionType::eSetMaximum, unpackedVal);
}
// Warn the user about the error if we need to.
if (sr != ScalarResult::Ok) {
internal_LogScalarError(aName, sr);
}
return NS_OK;
}
/**
* Sets the scalar to the maximum of the current and the passed value.
*
* @param aId The scalar enum id.
* @param aValue The numeric value to set the scalar to.
*/
void
TelemetryScalar::SetMaximum(mozilla::Telemetry::ScalarID aId, uint32_t aValue)
{
if (NS_WARN_IF(!IsValidEnumId(aId))) {
MOZ_ASSERT_UNREACHABLE("Scalar usage requires valid ids.");
return;
}
ScalarKey uniqueId{static_cast<uint32_t>(aId), false};
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
if (internal_CanRecordScalar(uniqueId, false) != ScalarResult::Ok) {
// We can't record this scalar. Bail out.
return;
}
// Accumulate in the child process if needed.
if (!XRE_IsParentProcess()) {
TelemetryIPCAccumulator::RecordChildScalarAction(uniqueId.id, uniqueId.dynamic,
ScalarActionType::eSetMaximum,
ScalarVariant(aValue));
return;
}
ScalarBase* scalar = nullptr;
nsresult rv = internal_GetScalarByEnum(uniqueId, ProcessID::Parent, &scalar);
if (NS_FAILED(rv)) {
return;
}
scalar->SetMaximum(aValue);
}
/**
* Sets the keyed scalar to the maximum of the current and the passed value.
*
* @param aId The scalar enum id.
* @param aKey The key name.
* @param aValue The numeric value to set the scalar to.
*/
void
TelemetryScalar::SetMaximum(mozilla::Telemetry::ScalarID aId, const nsAString& aKey,
uint32_t aValue)
{
if (NS_WARN_IF(!IsValidEnumId(aId))) {
MOZ_ASSERT_UNREACHABLE("Scalar usage requires valid ids.");
return;
}
ScalarKey uniqueId{static_cast<uint32_t>(aId), false};
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
if (internal_CanRecordScalar(uniqueId, true) != ScalarResult::Ok) {
// We can't record this scalar. Bail out.
return;
}
// Accumulate in the child process if needed.
if (!XRE_IsParentProcess()) {
TelemetryIPCAccumulator::RecordChildKeyedScalarAction(uniqueId.id, uniqueId.dynamic,
aKey, ScalarActionType::eSetMaximum, ScalarVariant(aValue));
return;
}
KeyedScalar* scalar = nullptr;
nsresult rv = internal_GetKeyedScalarByEnum(uniqueId, ProcessID::Parent, &scalar);
if (NS_FAILED(rv)) {
return;
}
scalar->SetMaximum(aKey, aValue);
}
/**
* Serializes the scalars from the given dataset to a json-style object and resets them.
* The returned structure looks like:
* {"process": {"category1.probe":1,"category1.other_probe":false,...}, ... }.
*
* @param aDataset DATASET_RELEASE_CHANNEL_OPTOUT or DATASET_RELEASE_CHANNEL_OPTIN.
* @param aClear Whether to clear out the scalars after snapshotting.
*/
nsresult
TelemetryScalar::CreateSnapshots(unsigned int aDataset, bool aClearScalars, JSContext* aCx,
uint8_t optional_argc, JS::MutableHandle<JS::Value> aResult)
{
MOZ_ASSERT(XRE_IsParentProcess(),
"Snapshotting scalars should only happen in the parent processes.");
// If no arguments were passed in, apply the default value.
if (!optional_argc) {
aClearScalars = false;
}
JS::Rooted<JSObject*> root_obj(aCx, JS_NewPlainObject(aCx));
if (!root_obj) {
return NS_ERROR_FAILURE;
}
aResult.setObject(*root_obj);
// Return `{}` in child processes.
if (!XRE_IsParentProcess()) {
return NS_OK;
}
// Only lock the mutex while accessing our data, without locking any JS related code.
typedef mozilla::Pair<const char*, nsCOMPtr<nsIVariant>> DataPair;
typedef nsTArray<DataPair> ScalarArray;
nsDataHashtable<ProcessIDHashKey, ScalarArray> scalarsToReflect;
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
// Iterate the scalars in gScalarStorageMap. The storage may contain empty or yet to be
// initialized scalars from all the supported processes.
for (auto iter = gScalarStorageMap.Iter(); !iter.Done(); iter.Next()) {
ScalarStorageMapType* scalarStorage = static_cast<ScalarStorageMapType*>(iter.Data());
ScalarArray& processScalars = scalarsToReflect.GetOrInsert(iter.Key());
// Are we in the "Dynamic" process?
bool isDynamicProcess = ProcessID::Dynamic == static_cast<ProcessID>(iter.Key());
// Iterate each available child storage.
for (auto childIter = scalarStorage->Iter(); !childIter.Done(); childIter.Next()) {
ScalarBase* scalar = static_cast<ScalarBase*>(childIter.Data());
// Get the informations for this scalar.
const BaseScalarInfo& info =
internal_GetScalarInfo(ScalarKey{childIter.Key(), isDynamicProcess});
// Serialize the scalar if it's in the desired dataset.
if (IsInDataset(info.dataset, aDataset)) {
// Get the scalar value.
nsCOMPtr<nsIVariant> scalarValue;
nsresult rv = scalar->GetValue(scalarValue);
if (NS_FAILED(rv)) {
return rv;
}
// Append it to our list.
processScalars.AppendElement(mozilla::MakePair(info.name(), scalarValue));
}
}
}
if (aClearScalars) {
// The map already takes care of freeing the allocated memory.
gScalarStorageMap.Clear();
}
}
// Reflect it to JS.
for (auto iter = scalarsToReflect.Iter(); !iter.Done(); iter.Next()) {
ScalarArray& processScalars = iter.Data();
const char* processName = GetNameForProcessID(ProcessID(iter.Key()));
// Create the object that will hold the scalars for this process and add it
// to the returned root object.
JS::RootedObject processObj(aCx, JS_NewPlainObject(aCx));
if (!processObj ||
!JS_DefineProperty(aCx, root_obj, processName, processObj, JSPROP_ENUMERATE)) {
return NS_ERROR_FAILURE;
}
for (nsTArray<DataPair>::size_type i = 0; i < processScalars.Length(); i++) {
const DataPair& scalar = processScalars[i];
// Convert it to a JS Val.
JS::Rooted<JS::Value> scalarJsValue(aCx);
nsresult rv =
nsContentUtils::XPConnect()->VariantToJS(aCx, processObj, scalar.second(), &scalarJsValue);
if (NS_FAILED(rv)) {
return rv;
}
// Add it to the scalar object.
if (!JS_DefineProperty(aCx, processObj, scalar.first(), scalarJsValue, JSPROP_ENUMERATE)) {
return NS_ERROR_FAILURE;
}
}
}
return NS_OK;
}
/**
* Serializes the scalars from the given dataset to a json-style object and resets them.
* The returned structure looks like:
* { "process": { "category1.probe": { "key_1": 2, "key_2": 1, ... }, ... }, ... }
*
* @param aDataset DATASET_RELEASE_CHANNEL_OPTOUT or DATASET_RELEASE_CHANNEL_OPTIN.
* @param aClear Whether to clear out the keyed scalars after snapshotting.
*/
nsresult
TelemetryScalar::CreateKeyedSnapshots(unsigned int aDataset, bool aClearScalars, JSContext* aCx,
uint8_t optional_argc, JS::MutableHandle<JS::Value> aResult)
{
MOZ_ASSERT(XRE_IsParentProcess(),
"Snapshotting scalars should only happen in the parent processes.");
// If no arguments were passed in, apply the default value.
if (!optional_argc) {
aClearScalars = false;
}
JS::Rooted<JSObject*> root_obj(aCx, JS_NewPlainObject(aCx));
if (!root_obj) {
return NS_ERROR_FAILURE;
}
aResult.setObject(*root_obj);
// Return `{}` in child processes.
if (!XRE_IsParentProcess()) {
return NS_OK;
}
// Only lock the mutex while accessing our data, without locking any JS related code.
typedef mozilla::Pair<const char*, nsTArray<KeyedScalar::KeyValuePair>> DataPair;
typedef nsTArray<DataPair> ScalarArray;
nsDataHashtable<ProcessIDHashKey, ScalarArray> scalarsToReflect;
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
// Iterate the scalars in gKeyedScalarStorageMap. The storage may contain empty or yet
// to be initialized scalars from all the supported processes.
for (auto iter = gKeyedScalarStorageMap.Iter(); !iter.Done(); iter.Next()) {
KeyedScalarStorageMapType* scalarStorage =
static_cast<KeyedScalarStorageMapType*>(iter.Data());
ScalarArray& processScalars = scalarsToReflect.GetOrInsert(iter.Key());
// Are we in the "Dynamic" process?
bool isDynamicProcess = ProcessID::Dynamic == static_cast<ProcessID>(iter.Key());
for (auto childIter = scalarStorage->Iter(); !childIter.Done(); childIter.Next()) {
KeyedScalar* scalar = static_cast<KeyedScalar*>(childIter.Data());
// Get the informations for this scalar.
const BaseScalarInfo& info =
internal_GetScalarInfo(ScalarKey{childIter.Key(), isDynamicProcess});
// Serialize the scalar if it's in the desired dataset.
if (IsInDataset(info.dataset, aDataset)) {
// Get the keys for this scalar.
nsTArray<KeyedScalar::KeyValuePair> scalarKeyedData;
nsresult rv = scalar->GetValue(scalarKeyedData);
if (NS_FAILED(rv)) {
return rv;
}
// Append it to our list.
processScalars.AppendElement(mozilla::MakePair(info.name(), scalarKeyedData));
}
}
}
if (aClearScalars) {
// The map already takes care of freeing the allocated memory.
gKeyedScalarStorageMap.Clear();
}
}
// Reflect it to JS.
for (auto iter = scalarsToReflect.Iter(); !iter.Done(); iter.Next()) {
ScalarArray& processScalars = iter.Data();
const char* processName = GetNameForProcessID(ProcessID(iter.Key()));
// Create the object that will hold the scalars for this process and add it
// to the returned root object.
JS::RootedObject processObj(aCx, JS_NewPlainObject(aCx));
if (!processObj ||
!JS_DefineProperty(aCx, root_obj, processName, processObj, JSPROP_ENUMERATE)) {
return NS_ERROR_FAILURE;
}
for (nsTArray<DataPair>::size_type i = 0; i < processScalars.Length(); i++) {
const DataPair& keyedScalarData = processScalars[i];
// Go through each keyed scalar and create a keyed scalar object.
// This object will hold the values for all the keyed scalar keys.
JS::RootedObject keyedScalarObj(aCx, JS_NewPlainObject(aCx));
// Define a property for each scalar key, then add it to the keyed scalar
// object.
const nsTArray<KeyedScalar::KeyValuePair>& keyProps = keyedScalarData.second();
for (uint32_t i = 0; i < keyProps.Length(); i++) {
const KeyedScalar::KeyValuePair& keyData = keyProps[i];
// Convert the value for the key to a JSValue.
JS::Rooted<JS::Value> keyJsValue(aCx);
nsresult rv =
nsContentUtils::XPConnect()->VariantToJS(aCx, keyedScalarObj, keyData.second(), &keyJsValue);
if (NS_FAILED(rv)) {
return rv;
}
// Add the key to the scalar representation.
const NS_ConvertUTF8toUTF16 key(keyData.first());
if (!JS_DefineUCProperty(aCx, keyedScalarObj, key.Data(), key.Length(), keyJsValue, JSPROP_ENUMERATE)) {
return NS_ERROR_FAILURE;
}
}
// Add the scalar to the root object.
if (!JS_DefineProperty(aCx, processObj, keyedScalarData.first(), keyedScalarObj, JSPROP_ENUMERATE)) {
return NS_ERROR_FAILURE;
}
}
}
return NS_OK;
}
nsresult
TelemetryScalar::RegisterScalars(const nsACString& aCategoryName,
JS::Handle<JS::Value> aScalarData,
JSContext* cx)
{
MOZ_ASSERT(XRE_IsParentProcess(),
"Dynamic scalars should only be created in the parent process.");
if (!IsValidIdentifierString(aCategoryName, kMaximumCategoryNameLength, true, false)) {
JS_ReportErrorASCII(cx, "Invalid category name %s.",
PromiseFlatCString(aCategoryName).get());
return NS_ERROR_INVALID_ARG;
}
if (!aScalarData.isObject()) {
JS_ReportErrorASCII(cx, "Scalar data parameter should be an object");
return NS_ERROR_INVALID_ARG;
}
JS::RootedObject obj(cx, &aScalarData.toObject());
JS::Rooted<JS::IdVector> scalarPropertyIds(cx, JS::IdVector(cx));
if (!JS_Enumerate(cx, obj, &scalarPropertyIds)) {
return NS_ERROR_FAILURE;
}
// Collect the scalar data into local storage first.
// Only after successfully validating all contained scalars will we register
// them into global storage.
nsTArray<DynamicScalarInfo> newScalarInfos;
for (size_t i = 0, n = scalarPropertyIds.length(); i < n; i++) {
nsAutoJSString scalarName;
if (!scalarName.init(cx, scalarPropertyIds[i])) {
return NS_ERROR_FAILURE;
}
if (!IsValidIdentifierString(NS_ConvertUTF16toUTF8(scalarName), kMaximumScalarNameLength,
false, true)) {
JS_ReportErrorASCII(cx, "Invalid scalar name %s.",
PromiseFlatCString(NS_ConvertUTF16toUTF8(scalarName)).get());
return NS_ERROR_INVALID_ARG;
}
// Join the category and the probe names.
nsPrintfCString fullName("%s.%s",
PromiseFlatCString(aCategoryName).get(),
NS_ConvertUTF16toUTF8(scalarName).get());
JS::RootedValue value(cx);
if (!JS_GetPropertyById(cx, obj, scalarPropertyIds[i], &value) || !value.isObject()) {
return NS_ERROR_FAILURE;
}
JS::RootedObject scalarDef(cx, &value.toObject());
// Get the scalar's kind.
if (!JS_GetProperty(cx, scalarDef, "kind", &value)
|| !value.isInt32()) {
JS_ReportErrorASCII(cx, "Invalid or missing 'kind' for scalar %s.",
PromiseFlatCString(fullName).get());
return NS_ERROR_FAILURE;
}
uint32_t kind = static_cast<uint32_t>(value.toInt32());
// Get the optional scalar's recording policy (default to false).
bool hasProperty = false;
bool recordOnRelease = false;
if (JS_HasProperty(cx, scalarDef, "record_on_release", &hasProperty) && hasProperty) {
if (!JS_GetProperty(cx, scalarDef, "record_on_release", &value) || !value.isBoolean()) {
JS_ReportErrorASCII(cx, "Invalid 'record_on_release' for scalar %s.",
PromiseFlatCString(fullName).get());
return NS_ERROR_FAILURE;
}
recordOnRelease = static_cast<bool>(value.toBoolean());
}
// Get the optional scalar's keyed (default to false).
bool keyed = false;
if (JS_HasProperty(cx, scalarDef, "keyed", &hasProperty) && hasProperty) {
if (!JS_GetProperty(cx, scalarDef, "keyed", &value) || !value.isBoolean()) {
JS_ReportErrorASCII(cx, "Invalid 'keyed' for scalar %s.",
PromiseFlatCString(fullName).get());
return NS_ERROR_FAILURE;
}
keyed = static_cast<bool>(value.toBoolean());
}
// Get the optional scalar's expired state (default to false).
bool expired = false;
if (JS_HasProperty(cx, scalarDef, "expired", &hasProperty) && hasProperty) {
if (!JS_GetProperty(cx, scalarDef, "expired", &value) || !value.isBoolean()) {
JS_ReportErrorASCII(cx, "Invalid 'expired' for scalar %s.",
PromiseFlatCString(fullName).get());
return NS_ERROR_FAILURE;
}
expired = static_cast<bool>(value.toBoolean());
}
// We defer the actual registration here in case any other event description is invalid.
// In that case we don't need to roll back any partial registration.
newScalarInfos.AppendElement(DynamicScalarInfo{
kind, recordOnRelease, expired, fullName, keyed
});
}
// Register the dynamic definition on the parent process.
ScalarResult res = ScalarResult::Ok;
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
res = ::internal_RegisterScalars(locker, newScalarInfos);
}
if (res == ScalarResult::AlreadyRegistered) {
JS_ReportErrorASCII(cx, "Attempt to register a scalar that is already registered.");
return NS_ERROR_INVALID_ARG;
}
// Propagate the registration to all the content-processes. Please note that
// this does not require to hold the mutex.
::internal_BroadcastDefinitions(newScalarInfos);
return NS_OK;
}
/**
* Resets all the stored scalars. This is intended to be only used in tests.
*/
void
TelemetryScalar::ClearScalars()
{
MOZ_ASSERT(XRE_IsParentProcess(), "Scalars should only be cleared in the parent process.");
if (!XRE_IsParentProcess()) {
return;
}
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
gScalarStorageMap.Clear();
gKeyedScalarStorageMap.Clear();
}
size_t
TelemetryScalar::GetMapShallowSizesOfExcludingThis(mozilla::MallocSizeOf aMallocSizeOf)
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
return gScalarNameIDMap.ShallowSizeOfExcludingThis(aMallocSizeOf);
}
size_t
TelemetryScalar::GetScalarSizesOfIncludingThis(mozilla::MallocSizeOf aMallocSizeOf)
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
size_t n = 0;
// Account for scalar data coming from parent and child processes.
for (auto iter = gScalarStorageMap.Iter(); !iter.Done(); iter.Next()) {
ScalarStorageMapType* scalarStorage = static_cast<ScalarStorageMapType*>(iter.Data());
for (auto childIter = scalarStorage->Iter(); !childIter.Done(); childIter.Next()) {
ScalarBase* scalar = static_cast<ScalarBase*>(childIter.Data());
n += scalar->SizeOfIncludingThis(aMallocSizeOf);
}
}
// Also account for keyed scalar data coming from parent and child processes.
for (auto iter = gKeyedScalarStorageMap.Iter(); !iter.Done(); iter.Next()) {
KeyedScalarStorageMapType* scalarStorage =
static_cast<KeyedScalarStorageMapType*>(iter.Data());
for (auto childIter = scalarStorage->Iter(); !childIter.Done(); childIter.Next()) {
KeyedScalar* scalar = static_cast<KeyedScalar*>(childIter.Data());
n += scalar->SizeOfIncludingThis(aMallocSizeOf);
}
}
return n;
}
void
TelemetryScalar::UpdateChildData(ProcessID aProcessType,
const nsTArray<mozilla::Telemetry::ScalarAction>& aScalarActions)
{
MOZ_ASSERT(XRE_IsParentProcess(),
"The stored child processes scalar data must be updated from the parent process.");
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
if (!internal_CanRecordBase()) {
return;
}
for (auto& upd : aScalarActions) {
ScalarKey uniqueId{upd.mId, upd.mDynamic};
if (NS_WARN_IF(!internal_IsValidId(uniqueId))) {
MOZ_ASSERT_UNREACHABLE("Scalar usage requires valid ids.");
continue;
}
if (internal_IsKeyedScalar(uniqueId)) {
continue;
}
// Are we allowed to record this scalar? We don't need to check for
// allowed processes here, that's taken care of when recording
// in child processes.
if (!internal_CanRecordForScalarID(uniqueId)) {
continue;
}
// Refresh the data in the parent process with the data coming from the child
// processes.
ScalarBase* scalar = nullptr;
nsresult rv = internal_GetScalarByEnum(uniqueId, aProcessType, &scalar);
if (NS_FAILED(rv)) {
NS_WARNING("NS_FAILED internal_GetScalarByEnum for CHILD");
continue;
}
if (upd.mData.isNothing()) {
MOZ_ASSERT(false, "There is no data in the ScalarActionType.");
continue;
}
// Get the type of this scalar from the scalar ID. We already checked
// for its validity a few lines above.
const uint32_t scalarType = internal_GetScalarInfo(uniqueId).kind;
// Extract the data from the mozilla::Variant.
switch (upd.mActionType)
{
case ScalarActionType::eSet:
{
switch (scalarType)
{
case nsITelemetry::SCALAR_TYPE_COUNT:
scalar->SetValue(upd.mData->as<uint32_t>());
break;
case nsITelemetry::SCALAR_TYPE_BOOLEAN:
scalar->SetValue(upd.mData->as<bool>());
break;
case nsITelemetry::SCALAR_TYPE_STRING:
scalar->SetValue(upd.mData->as<nsString>());
break;
}
break;
}
case ScalarActionType::eAdd:
{
if (scalarType != nsITelemetry::SCALAR_TYPE_COUNT) {
NS_WARNING("Attempting to add on a non count scalar.");
continue;
}
// We only support adding uint32_t.
scalar->AddValue(upd.mData->as<uint32_t>());
break;
}
case ScalarActionType::eSetMaximum:
{
if (scalarType != nsITelemetry::SCALAR_TYPE_COUNT) {
NS_WARNING("Attempting to add on a non count scalar.");
continue;
}
// We only support SetMaximum on uint32_t.
scalar->SetMaximum(upd.mData->as<uint32_t>());
break;
}
default:
NS_WARNING("Unsupported action coming from scalar child updates.");
}
}
}
void
TelemetryScalar::UpdateChildKeyedData(ProcessID aProcessType,
const nsTArray<mozilla::Telemetry::KeyedScalarAction>& aScalarActions)
{
MOZ_ASSERT(XRE_IsParentProcess(),
"The stored child processes keyed scalar data must be updated from the parent process.");
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
if (!internal_CanRecordBase()) {
return;
}
for (auto& upd : aScalarActions) {
ScalarKey uniqueId{upd.mId, upd.mDynamic};
if (NS_WARN_IF(!internal_IsValidId(uniqueId))) {
MOZ_ASSERT_UNREACHABLE("Scalar usage requires valid ids.");
continue;
}
if (!internal_IsKeyedScalar(uniqueId)) {
continue;
}
// Are we allowed to record this scalar? We don't need to check for
// allowed processes here, that's taken care of when recording
// in child processes.
if (!internal_CanRecordForScalarID(uniqueId)) {
continue;
}
// Refresh the data in the parent process with the data coming from the child
// processes.
KeyedScalar* scalar = nullptr;
nsresult rv = internal_GetKeyedScalarByEnum(uniqueId, aProcessType, &scalar);
if (NS_FAILED(rv)) {
NS_WARNING("NS_FAILED internal_GetScalarByEnum for CHILD");
continue;
}
if (upd.mData.isNothing()) {
MOZ_ASSERT(false, "There is no data in the KeyedScalarAction.");
continue;
}
// Get the type of this scalar from the scalar ID. We already checked
// for its validity a few lines above.
const uint32_t scalarType = internal_GetScalarInfo(uniqueId).kind;
// Extract the data from the mozilla::Variant.
switch (upd.mActionType)
{
case ScalarActionType::eSet:
{
switch (scalarType)
{
case nsITelemetry::SCALAR_TYPE_COUNT:
scalar->SetValue(NS_ConvertUTF8toUTF16(upd.mKey), upd.mData->as<uint32_t>());
break;
case nsITelemetry::SCALAR_TYPE_BOOLEAN:
scalar->SetValue(NS_ConvertUTF8toUTF16(upd.mKey), upd.mData->as<bool>());
break;
default:
NS_WARNING("Unsupported type coming from scalar child updates.");
}
break;
}
case ScalarActionType::eAdd:
{
if (scalarType != nsITelemetry::SCALAR_TYPE_COUNT) {
NS_WARNING("Attempting to add on a non count scalar.");
continue;
}
// We only support adding on uint32_t.
scalar->AddValue(NS_ConvertUTF8toUTF16(upd.mKey), upd.mData->as<uint32_t>());
break;
}
case ScalarActionType::eSetMaximum:
{
if (scalarType != nsITelemetry::SCALAR_TYPE_COUNT) {
NS_WARNING("Attempting to add on a non count scalar.");
continue;
}
// We only support SetMaximum on uint32_t.
scalar->SetMaximum(NS_ConvertUTF8toUTF16(upd.mKey), upd.mData->as<uint32_t>());
break;
}
default:
NS_WARNING("Unsupported action coming from keyed scalar child updates.");
}
}
}
void
TelemetryScalar::RecordDiscardedData(ProcessID aProcessType,
const mozilla::Telemetry::DiscardedData& aDiscardedData)
{
MOZ_ASSERT(XRE_IsParentProcess(),
"Discarded Data must be updated from the parent process.");
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
if (!internal_CanRecordBase()) {
return;
}
ScalarBase* scalar = nullptr;
mozilla::DebugOnly<nsresult> rv;
rv = internal_GetScalarByEnum(
ScalarKey{static_cast<uint32_t>(ScalarID::TELEMETRY_DISCARDED_ACCUMULATIONS), false},
aProcessType, &scalar);
MOZ_ASSERT(NS_SUCCEEDED(rv));
scalar->AddValue(aDiscardedData.mDiscardedHistogramAccumulations);
rv = internal_GetScalarByEnum(
ScalarKey{static_cast<uint32_t>(ScalarID::TELEMETRY_DISCARDED_KEYED_ACCUMULATIONS), false},
aProcessType, &scalar);
MOZ_ASSERT(NS_SUCCEEDED(rv));
scalar->AddValue(aDiscardedData.mDiscardedKeyedHistogramAccumulations);
rv = internal_GetScalarByEnum(
ScalarKey{static_cast<uint32_t>(ScalarID::TELEMETRY_DISCARDED_SCALAR_ACTIONS), false},
aProcessType, &scalar);
MOZ_ASSERT(NS_SUCCEEDED(rv));
scalar->AddValue(aDiscardedData.mDiscardedScalarActions);
rv = internal_GetScalarByEnum(
ScalarKey{static_cast<uint32_t>(ScalarID::TELEMETRY_DISCARDED_KEYED_SCALAR_ACTIONS), false},
aProcessType, &scalar);
MOZ_ASSERT(NS_SUCCEEDED(rv));
scalar->AddValue(aDiscardedData.mDiscardedKeyedScalarActions);
rv = internal_GetScalarByEnum(
ScalarKey{static_cast<uint32_t>(ScalarID::TELEMETRY_DISCARDED_CHILD_EVENTS), false},
aProcessType, &scalar);
MOZ_ASSERT(NS_SUCCEEDED(rv));
scalar->AddValue(aDiscardedData.mDiscardedChildEvents);
}
/**
* Get the dynamic scalar definitions in an IPC-friendly
* structure.
*/
void
TelemetryScalar::GetDynamicScalarDefinitions(
nsTArray<DynamicScalarDefinition> &aDefArray)
{
MOZ_ASSERT(XRE_IsParentProcess());
if (!gDynamicScalarInfo) {
// Don't have dynamic scalar definitions. Bail out!
return;
}
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
internal_DynamicScalarToIPC(*gDynamicScalarInfo, aDefArray);
}
/**
* This adds the dynamic scalar definitions coming from
* the parent process to this child process.
*/
void
TelemetryScalar::AddDynamicScalarDefinitions(
const nsTArray<DynamicScalarDefinition>& aDefs)
{
MOZ_ASSERT(!XRE_IsParentProcess());
nsTArray<DynamicScalarInfo> dynamicStubs;
// Populate the definitions array before acquiring the lock.
for (auto def : aDefs) {
bool recordOnRelease = def.dataset == nsITelemetry::DATASET_RELEASE_CHANNEL_OPTOUT;
dynamicStubs.AppendElement(DynamicScalarInfo{
def.type,
recordOnRelease,
def.expired,
def.name,
def.keyed});
}
{
StaticMutexAutoLock locker(gTelemetryScalarsMutex);
internal_RegisterScalars(locker, dynamicStubs);
}
}
Reference in New Issue View Git Blame Copy Permalink