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/*
*
* Copyright (c) 2021 Project CHIP Authors
* All rights reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <app/AttributePathExpandIterator.h>
#include <app/AttributePathParams.h>
#include <app/ConcreteAttributePath.h>
#include <app/EventManagement.h>
#include <app/GlobalAttributes.h>
#include <app/util/att-storage.h>
#include <app/util/endpoint-config-api.h>
#include <lib/core/CHIPCore.h>
#include <lib/core/TLVDebug.h>
#include <lib/support/CodeUtils.h>
#include <lib/support/DLLUtil.h>
#include <lib/support/logging/CHIPLogging.h>
using namespace chip;
// TODO: Need to make it so that declarations of things that don't depend on generated files are not intermixed in af.h with
// dependencies on generated files, so we don't have to re-declare things here.
// Note: Some of the generated files that depended by af.h are gen_config.h and gen_tokens.h
typedef uint8_t EmberAfClusterMask;
extern uint16_t emberAfEndpointCount();
extern uint16_t emberAfIndexFromEndpoint(EndpointId endpoint);
extern uint8_t emberAfClusterCount(EndpointId endpoint, bool server);
extern uint16_t emberAfGetServerAttributeCount(chip::EndpointId endpoint, chip::ClusterId cluster);
extern uint16_t emberAfGetServerAttributeIndexByAttributeId(chip::EndpointId endpoint, chip::ClusterId cluster,
chip::AttributeId attributeId);
extern chip::EndpointId emberAfEndpointFromIndex(uint16_t index);
extern Optional<ClusterId> emberAfGetNthClusterId(chip::EndpointId endpoint, uint8_t n, bool server);
extern Optional<AttributeId> emberAfGetServerAttributeIdByIndex(chip::EndpointId endpoint, chip::ClusterId cluster,
uint16_t attributeIndex);
extern uint8_t emberAfClusterIndex(EndpointId endpoint, ClusterId clusterId, EmberAfClusterMask mask);
extern bool emberAfEndpointIndexIsEnabled(uint16_t index);
namespace chip {
namespace app {
AttributePathExpandIterator::AttributePathExpandIterator(SingleLinkedListNode<AttributePathParams> * aAttributePath)
{
mpAttributePath = aAttributePath;
// Reset iterator state
mEndpointIndex = UINT16_MAX;
mClusterIndex = UINT8_MAX;
mAttributeIndex = UINT16_MAX;
static_assert(std::numeric_limits<decltype(mGlobalAttributeIndex)>::max() >= ArraySize(GlobalAttributesNotInMetadata),
"Our index won't be able to hold the value we need to hold.");
static_assert(std::is_same<decltype(mGlobalAttributeIndex), uint8_t>::value,
"If this changes audit all uses where we set to UINT8_MAX");
mGlobalAttributeIndex = UINT8_MAX;
// Make the iterator ready to emit the first valid path in the list.
Next();
}
void AttributePathExpandIterator::PrepareEndpointIndexRange(const AttributePathParams & aAttributePath)
{
if (aAttributePath.HasWildcardEndpointId())
{
mEndpointIndex = 0;
mEndEndpointIndex = emberAfEndpointCount();
}
else
{
mEndpointIndex = emberAfIndexFromEndpoint(aAttributePath.mEndpointId);
// If the given cluster id does not exist on the given endpoint, it will return uint16(0xFFFF), then endEndpointIndex
// will be 0, means we should iterate a null endpoint set (skip it).
mEndEndpointIndex = static_cast<uint16_t>(mEndpointIndex + 1);
}
}
void AttributePathExpandIterator::PrepareClusterIndexRange(const AttributePathParams & aAttributePath, EndpointId aEndpointId)
{
if (aAttributePath.HasWildcardClusterId())
{
mClusterIndex = 0;
mEndClusterIndex = emberAfClusterCount(aEndpointId, true /* server */);
}
else
{
mClusterIndex = emberAfClusterIndex(aEndpointId, aAttributePath.mClusterId, CLUSTER_MASK_SERVER);
// If the given cluster id does not exist on the given endpoint, it will return uint8(0xFF), then endClusterIndex
// will be 0, means we should iterate a null cluster set (skip it).
mEndClusterIndex = static_cast<uint8_t>(mClusterIndex + 1);
}
}
void AttributePathExpandIterator::PrepareAttributeIndexRange(const AttributePathParams & aAttributePath, EndpointId aEndpointId,
ClusterId aClusterId)
{
if (aAttributePath.HasWildcardAttributeId())
{
mAttributeIndex = 0;
mEndAttributeIndex = emberAfGetServerAttributeCount(aEndpointId, aClusterId);
mGlobalAttributeIndex = 0;
mGlobalAttributeEndIndex = ArraySize(GlobalAttributesNotInMetadata);
}
else
{
mAttributeIndex = emberAfGetServerAttributeIndexByAttributeId(aEndpointId, aClusterId, aAttributePath.mAttributeId);
// If the given attribute id does not exist on the given endpoint, it will return uint16(0xFFFF), then endAttributeIndex
// will be 0, means we should iterate a null attribute set (skip it).
mEndAttributeIndex = static_cast<uint16_t>(mAttributeIndex + 1);
if (mAttributeIndex == UINT16_MAX)
{
// Check whether this is a non-metadata global attribute.
//
// Default to the max value, which will correspond (after we add 1
// and overflow to 0 for the max index) to us not going through
// non-metadata global attributes for this attribute.
mGlobalAttributeIndex = UINT8_MAX;
static_assert(ArraySize(GlobalAttributesNotInMetadata) <= UINT8_MAX, "Iterating over at most 256 array entries");
const uint8_t arraySize = static_cast<uint8_t>(ArraySize(GlobalAttributesNotInMetadata));
for (uint8_t idx = 0; idx < arraySize; ++idx)
{
if (GlobalAttributesNotInMetadata[idx] == aAttributePath.mAttributeId)
{
mGlobalAttributeIndex = idx;
break;
}
}
mGlobalAttributeEndIndex = static_cast<uint8_t>(mGlobalAttributeIndex + 1);
}
else
{
mGlobalAttributeIndex = UINT8_MAX;
mGlobalAttributeEndIndex = 0;
}
}
}
void AttributePathExpandIterator::ResetCurrentCluster()
{
// If this is a null iterator, or the attribute id of current cluster info is not a wildcard attribute id, then this function
// will do nothing, since we won't be expanding the wildcard attribute ids under a cluster.
VerifyOrReturn(mpAttributePath != nullptr && mpAttributePath->mValue.HasWildcardAttributeId());
// Otherwise, we will reset the index for iterating the attributes, so we report the attributes for this cluster again. This
// will ensure that the client sees a coherent view of the cluster from the reports generated by a single (wildcard) attribute
// path in the request.
//
// Note that when Next() returns, we must be in one of the following states:
// - This is not a wildcard path
// - We just expanded some attribute id field
// - We have exhausted all paths
// Only the second case will happen here since the above check will fail for 1 and 3, so the following Next() call must result
// in a valid path, which is the first attribute id we will emit for the current cluster.
mAttributeIndex = UINT16_MAX;
mGlobalAttributeIndex = UINT8_MAX;
Next();
}
bool AttributePathExpandIterator::Next()
{
for (; mpAttributePath != nullptr; (mpAttributePath = mpAttributePath->mpNext, mEndpointIndex = UINT16_MAX))
{
mOutputPath.mExpanded = mpAttributePath->mValue.IsWildcardPath();
if (mEndpointIndex == UINT16_MAX)
{
// Special case: If this is a concrete path, we just return its value as-is.
if (!mpAttributePath->mValue.IsWildcardPath())
{
mOutputPath.mEndpointId = mpAttributePath->mValue.mEndpointId;
mOutputPath.mClusterId = mpAttributePath->mValue.mClusterId;
mOutputPath.mAttributeId = mpAttributePath->mValue.mAttributeId;
// Prepare for next iteration
mEndpointIndex = mEndEndpointIndex = 0;
return true;
}
PrepareEndpointIndexRange(mpAttributePath->mValue);
mClusterIndex = UINT8_MAX;
}
for (; mEndpointIndex < mEndEndpointIndex;
(mEndpointIndex++, mClusterIndex = UINT8_MAX, mAttributeIndex = UINT16_MAX, mGlobalAttributeIndex = UINT8_MAX))
{
if (!emberAfEndpointIndexIsEnabled(mEndpointIndex))
{
// Not an enabled endpoint; skip it.
continue;
}
EndpointId endpointId = emberAfEndpointFromIndex(mEndpointIndex);
if (mClusterIndex == UINT8_MAX)
{
PrepareClusterIndexRange(mpAttributePath->mValue, endpointId);
mAttributeIndex = UINT16_MAX;
mGlobalAttributeIndex = UINT8_MAX;
}
for (; mClusterIndex < mEndClusterIndex;
(mClusterIndex++, mAttributeIndex = UINT16_MAX, mGlobalAttributeIndex = UINT8_MAX))
{
// emberAfGetNthClusterId must return a valid cluster id here since we have verified the mClusterIndex does
// not exceed the mEndClusterIndex.
ClusterId clusterId = emberAfGetNthClusterId(endpointId, mClusterIndex, true /* server */).Value();
if (mAttributeIndex == UINT16_MAX && mGlobalAttributeIndex == UINT8_MAX)
{
PrepareAttributeIndexRange(mpAttributePath->mValue, endpointId, clusterId);
}
if (mAttributeIndex < mEndAttributeIndex)
{
// GetServerAttributeIdByIdex must return a valid attribute here since we have verified the mAttributeIndex does
// not exceed the mEndAttributeIndex.
mOutputPath.mAttributeId = emberAfGetServerAttributeIdByIndex(endpointId, clusterId, mAttributeIndex).Value();
mOutputPath.mClusterId = clusterId;
mOutputPath.mEndpointId = endpointId;
mAttributeIndex++;
// We found a valid attribute path, now return and increase the attribute index for next iteration.
// Return true will skip the increment of mClusterIndex, mEndpointIndex and mpAttributePath.
return true;
}
if (mGlobalAttributeIndex < mGlobalAttributeEndIndex)
{
// Return a path pointing to the next global attribute.
mOutputPath.mAttributeId = GlobalAttributesNotInMetadata[mGlobalAttributeIndex];
mOutputPath.mClusterId = clusterId;
mOutputPath.mEndpointId = endpointId;
mGlobalAttributeIndex++;
return true;
}
// We have exhausted all attributes of this cluster, continue iterating over attributes of next cluster.
}
// We have exhausted all clusters of this endpoint, continue iterating over clusters of next endpoint.
}
// We have exhausted all endpoints in this cluster info, continue iterating over next cluster info item.
}
// Reset to default, invalid value.
mOutputPath = ConcreteReadAttributePath();
return false;
}
} // namespace app
} // namespace chip