Google Git
Sign in
pigweed / third_party / github / project-chip / connectedhomeip / 93a8cedb0654791bbb7583564a2015d16df77865 / . / src / lib / dnssd / tests / TestTxtFields.cpp
blob: d487c261346c05c37272629357d3698c2d9aed1b [file] [log] [blame]
/*
*
* 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 <lib/dnssd/TxtFields.h>
#include <limits>
#include <stdio.h>
#include <string.h>
#include <lib/dnssd/Resolver.h>
#include <gtest/gtest.h>
using namespace chip;
using namespace chip::Dnssd;
using namespace chip::Dnssd::Internal;
namespace {
ByteSpan GetSpan(char * key)
{
size_t len = strlen(key);
// Stop the string from being null terminated to ensure the code makes no assumptions.
key[len] = '1';
return ByteSpan(reinterpret_cast<uint8_t *>(key), len);
}
TEST(TestTxtFields, TestGetTxtFieldKey)
{
char key[4];
strcpy(key, "D");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kLongDiscriminator);
strcpy(key, "VP");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kVendorProduct);
strcpy(key, "CM");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kCommissioningMode);
strcpy(key, "DT");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kDeviceType);
strcpy(key, "DN");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kDeviceName);
strcpy(key, "RI");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kRotatingDeviceId);
strcpy(key, "PI");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kPairingInstruction);
strcpy(key, "PH");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kPairingHint);
strcpy(key, "SII");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kSessionIdleInterval);
strcpy(key, "SAI");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kSessionActiveInterval);
strcpy(key, "SAT");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kSessionActiveThreshold);
strcpy(key, "T");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kTcpSupported);
strcpy(key, "ICD");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kLongIdleTimeICD);
strcpy(key, "XX");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kUnknown);
strcpy(key, "CP");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kCommissionerPasscode);
}
TEST(TestTxtFields, TestGetTxtFieldKeyCaseInsensitive)
{
char key[3];
strcpy(key, "d");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kLongDiscriminator);
strcpy(key, "vp");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kVendorProduct);
strcpy(key, "Vp");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kVendorProduct);
strcpy(key, "vP");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kVendorProduct);
strcpy(key, "Xx");
EXPECT_EQ(GetTxtFieldKey(GetSpan(key)), TxtFieldKey::kUnknown);
}
TEST(TestTxtFields, TestGetProduct)
{
// Product and vendor are given as part of the same key, on either side of a + sign. Product is after the +
char vp[64];
strcpy(vp, "123+456");
EXPECT_EQ(GetProduct(GetSpan(vp)), 456);
strcpy(vp, "123+");
EXPECT_EQ(GetProduct(GetSpan(vp)), 0);
strcpy(vp, "+456");
EXPECT_EQ(GetProduct(GetSpan(vp)), 456);
strcpy(vp, "123");
EXPECT_EQ(GetProduct(GetSpan(vp)), 0);
// overflow a uint16
sprintf(vp, "123+%" PRIu32, static_cast<uint32_t>(std::numeric_limits<uint16_t>::max()) + 1);
EXPECT_EQ(GetProduct(GetSpan(vp)), 0);
}
TEST(TestTxtFields, TestGetVendor)
{
// Product and vendor are given as part of the same key, on either side of a + sign. Vendor is first
char vp[64];
strcpy(vp, "123+456");
EXPECT_EQ(GetVendor(GetSpan(vp)), 123);
strcpy(vp, "123+");
EXPECT_EQ(GetVendor(GetSpan(vp)), 123);
strcpy(vp, "+456");
EXPECT_EQ(GetVendor(GetSpan(vp)), 0);
strcpy(vp, "123");
EXPECT_EQ(GetVendor(GetSpan(vp)), 123);
// overflow a uint16
sprintf(vp, "%" PRIu32 "+456", static_cast<uint32_t>(std::numeric_limits<uint16_t>::max()) + 1);
EXPECT_EQ(GetVendor(GetSpan(vp)), 0);
}
TEST(TestTxtFields, TestGetLongDiscriminator)
{
char ld[64];
strcpy(ld, "1234");
EXPECT_EQ(GetLongDiscriminator(GetSpan(ld)), 1234);
// overflow a uint16
sprintf(ld, "%" PRIu32, static_cast<uint32_t>(std::numeric_limits<uint16_t>::max()) + 1);
printf("ld = %s\n", ld);
EXPECT_EQ(GetLongDiscriminator(GetSpan(ld)), 0);
}
TEST(TestTxtFields, TestGetCommissioningMode)
{
char cm[64];
strcpy(cm, "0");
EXPECT_EQ(GetCommissioningMode(GetSpan(cm)), 0);
strcpy(cm, "1");
EXPECT_EQ(GetCommissioningMode(GetSpan(cm)), 1);
strcpy(cm, "2");
EXPECT_EQ(GetCommissioningMode(GetSpan(cm)), 2);
// overflow a uint8
sprintf(cm, "%u", static_cast<uint16_t>(std::numeric_limits<uint8_t>::max()) + 1);
EXPECT_EQ(GetCommissioningMode(GetSpan(cm)), 0);
}
TEST(TestTxtFields, TestGetDeviceType)
{
char dt[64];
strcpy(dt, "1234");
EXPECT_EQ(GetDeviceType(GetSpan(dt)), 1234u);
// overflow a uint32
sprintf(dt, "%" PRIu64, static_cast<uint64_t>(std::numeric_limits<uint32_t>::max()) + 1);
EXPECT_EQ(GetDeviceType(GetSpan(dt)), 0u);
}
TEST(TestTxtFields, TestGetDeviceName)
{
char name[kMaxDeviceNameLen + 1] = "";
char val[kMaxDeviceNameLen + 2];
strcpy(val, "testname");
GetDeviceName(GetSpan(val), name);
EXPECT_STREQ(name, "testname");
// If the data passed in is too long, it should truncate the end.
memset(val, 'a', kMaxDeviceNameLen);
val[kMaxDeviceNameLen] = 'b';
val[kMaxDeviceNameLen + 1] = '\0';
GetDeviceName(GetSpan(val), name);
val[kMaxDeviceNameLen] = '\0';
EXPECT_STREQ(name, val);
}
TEST(TestTxtFields, TestGetRotatingDeviceId)
{
// Rotating device ID is given as up to 50 hex bytes
char ri[kMaxRotatingIdLen * 2 + 1];
uint8_t id[kMaxRotatingIdLen];
size_t len;
strcpy(ri, "0A1B");
GetRotatingDeviceId(GetSpan(ri), id, &len);
printf("id[0] = %x\n", id[0]);
EXPECT_EQ(id[0], 0x0A);
EXPECT_EQ(id[1], 0x1B);
EXPECT_EQ(len, 2u);
// odd number of characters can't be parsed.
strcpy(ri, "0A1BC");
GetRotatingDeviceId(GetSpan(ri), id, &len);
EXPECT_EQ(len, 0u);
// non-hex characters can't be parsed
strcpy(ri, "0ATT");
GetRotatingDeviceId(GetSpan(ri), id, &len);
EXPECT_EQ(len, 0u);
// Lower case should work on SDK even though devices shouldn't be sending that.
strcpy(ri, "0a1b");
GetRotatingDeviceId(GetSpan(ri), id, &len);
EXPECT_EQ(id[0], 0x0A);
EXPECT_EQ(id[1], 0x1B);
EXPECT_EQ(len, 2u);
strcpy(ri, "000102030405060708090A0B0C0D0E0F101112131415161718191A1B1C1D1E1F202122232425262728292A2B2C2D2E2F3031");
GetRotatingDeviceId(GetSpan(ri), id, &len);
EXPECT_EQ(len, sizeof(id));
for (size_t i = 0; i < sizeof(id); ++i)
{
EXPECT_EQ(id[i], i);
}
}
TEST(TestTxtFields, TestGetPairingHint)
{
char ph[64];
strcpy(ph, "0");
EXPECT_EQ(GetPairingHint(GetSpan(ph)), 0);
strcpy(ph, "9");
EXPECT_EQ(GetPairingHint(GetSpan(ph)), 9);
// overflow a uint16
sprintf(ph, "%" PRIu32, static_cast<uint32_t>(std::numeric_limits<uint16_t>::max()) + 1);
EXPECT_EQ(GetPairingHint(GetSpan(ph)), 0);
}
TEST(TestTxtFields, TestGetPairingInstruction)
{
char data[kMaxPairingInstructionLen + 2];
char ret[kMaxPairingInstructionLen + 1] = "";
strcpy(data, "something");
GetPairingInstruction(GetSpan(data), ret);
EXPECT_STREQ(ret, "something");
// Exactly the max len.
memset(data, 'a', kMaxPairingInstructionLen);
data[kMaxPairingInstructionLen] = '\0';
GetPairingInstruction(GetSpan(data), ret);
// Add back the null terminator removed by GetSpan.
data[kMaxPairingInstructionLen] = '\0';
EXPECT_STREQ(data, ret);
// Too long - should truncate end.
memset(data, 'a', kMaxPairingInstructionLen);
data[kMaxPairingInstructionLen] = 'b';
data[kMaxPairingInstructionLen + 1] = '\0';
GetPairingInstruction(GetSpan(data), ret);
data[kMaxPairingInstructionLen] = '\0';
EXPECT_STREQ(ret, data);
}
TEST(TestTxtFields, TestGetCommissionerPasscode)
{
char cm[64];
strcpy(cm, "0");
EXPECT_EQ(GetCommissionerPasscode(GetSpan(cm)), 0);
strcpy(cm, "1");
EXPECT_EQ(GetCommissionerPasscode(GetSpan(cm)), 1);
// overflow a uint8
sprintf(cm, "%u", static_cast<uint16_t>(std::numeric_limits<uint8_t>::max()) + 1);
EXPECT_EQ(GetCommissionerPasscode(GetSpan(cm)), 0);
}
bool NodeDataIsEmpty(const DiscoveredNodeData & node)
{
if (node.nodeData.longDiscriminator != 0 || node.nodeData.vendorId != 0 || node.nodeData.productId != 0 ||
node.nodeData.commissioningMode != 0 || node.nodeData.deviceType != 0 || node.nodeData.rotatingIdLen != 0 ||
node.nodeData.pairingHint != 0 || node.resolutionData.mrpRetryIntervalIdle.HasValue() ||
node.resolutionData.mrpRetryIntervalActive.HasValue() || node.resolutionData.mrpRetryActiveThreshold.HasValue() ||
node.resolutionData.isICDOperatingAsLIT.HasValue() || node.resolutionData.supportsTcp ||
node.nodeData.supportsCommissionerGeneratedPasscode != 0)
{
return false;
}
if (strcmp(node.nodeData.deviceName, "") != 0 || strcmp(node.nodeData.pairingInstruction, "") != 0)
{
return false;
}
for (uint8_t id : node.nodeData.rotatingId)
{
if (id != 0)
{
return false;
}
}
return true;
}
// The individual fill tests test the error cases for each key type, this test is used to ensure the proper record is filled.
TEST(TestTxtFields, TestFillDiscoveredNodeDataFromTxt)
{
char key[3];
char val[16];
DiscoveredNodeData filled;
// Long discriminator
strcpy(key, "D");
strcpy(val, "840");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), filled.nodeData);
EXPECT_EQ(filled.nodeData.longDiscriminator, 840);
filled.nodeData.longDiscriminator = 0;
EXPECT_TRUE(NodeDataIsEmpty(filled));
// vendor and product
strcpy(key, "VP");
strcpy(val, "123+456");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), filled.nodeData);
EXPECT_EQ(filled.nodeData.vendorId, 123);
EXPECT_EQ(filled.nodeData.productId, 456);
filled.nodeData.vendorId = 0;
filled.nodeData.productId = 0;
EXPECT_TRUE(NodeDataIsEmpty(filled));
// Commissioning mode
strcpy(key, "CM");
strcpy(val, "1");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), filled.nodeData);
EXPECT_EQ(filled.nodeData.commissioningMode, 1);
filled.nodeData.commissioningMode = 0;
EXPECT_TRUE(NodeDataIsEmpty(filled));
// Supports Commissioner Generated Passcode
strcpy(key, "CP");
strcpy(val, "1");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), filled.nodeData);
EXPECT_TRUE(filled.nodeData.supportsCommissionerGeneratedPasscode);
filled.nodeData.supportsCommissionerGeneratedPasscode = false;
EXPECT_TRUE(NodeDataIsEmpty(filled));
// Device type
strcpy(key, "DT");
strcpy(val, "1");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), filled.nodeData);
EXPECT_EQ(filled.nodeData.deviceType, 1u);
filled.nodeData.deviceType = 0;
EXPECT_TRUE(NodeDataIsEmpty(filled));
// Device name
strcpy(key, "DN");
strcpy(val, "abc");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), filled.nodeData);
EXPECT_STREQ(filled.nodeData.deviceName, "abc");
memset(filled.nodeData.deviceName, 0, sizeof(filled.nodeData.deviceName));
EXPECT_TRUE(NodeDataIsEmpty(filled));
// Rotating device id
strcpy(key, "RI");
strcpy(val, "1A2B");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), filled.nodeData);
EXPECT_EQ(filled.nodeData.rotatingId[0], 0x1A);
EXPECT_EQ(filled.nodeData.rotatingId[1], 0x2B);
EXPECT_EQ(filled.nodeData.rotatingIdLen, 2u);
filled.nodeData.rotatingIdLen = 0;
memset(filled.nodeData.rotatingId, 0, sizeof(filled.nodeData.rotatingId));
EXPECT_TRUE(NodeDataIsEmpty(filled));
// Pairing instruction
strcpy(key, "PI");
strcpy(val, "hint");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), filled.nodeData);
EXPECT_STREQ(filled.nodeData.pairingInstruction, "hint");
memset(filled.nodeData.pairingInstruction, 0, sizeof(filled.nodeData.pairingInstruction));
EXPECT_TRUE(NodeDataIsEmpty(filled));
// Pairing hint
strcpy(key, "PH");
strcpy(val, "1");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), filled.nodeData);
EXPECT_EQ(filled.nodeData.pairingHint, 1);
filled.nodeData.pairingHint = 0;
EXPECT_TRUE(NodeDataIsEmpty(filled));
}
bool NodeDataIsEmpty(const ResolvedNodeData & nodeData)
{
return nodeData.operationalData.peerId == PeerId{} && nodeData.resolutionData.numIPs == 0 &&
nodeData.resolutionData.port == 0 && !nodeData.resolutionData.mrpRetryIntervalIdle.HasValue() &&
!nodeData.resolutionData.mrpRetryIntervalActive.HasValue() && !nodeData.resolutionData.supportsTcp &&
!nodeData.resolutionData.isICDOperatingAsLIT.HasValue();
}
void ResetRetryIntervalIdle(DiscoveredNodeData & nodeData)
{
nodeData.resolutionData.mrpRetryIntervalIdle.ClearValue();
}
void ResetRetryIntervalIdle(ResolvedNodeData & nodeData)
{
nodeData.resolutionData.mrpRetryIntervalIdle.ClearValue();
}
void ResetRetryIntervalActive(DiscoveredNodeData & nodeData)
{
nodeData.resolutionData.mrpRetryIntervalActive.ClearValue();
}
void ResetRetryIntervalActive(ResolvedNodeData & nodeData)
{
nodeData.resolutionData.mrpRetryIntervalActive.ClearValue();
}
void ResetRetryActiveThreshold(DiscoveredNodeData & nodeData)
{
nodeData.resolutionData.mrpRetryActiveThreshold.ClearValue();
}
void ResetRetryActiveThreshold(ResolvedNodeData & nodeData)
{
nodeData.resolutionData.mrpRetryActiveThreshold.ClearValue();
}
// Test SAI (formally CRI)
template <class NodeData>
void TxtFieldSessionIdleInterval()
{
char key[4];
char val[16];
NodeData nodeData;
// Minimum
strcpy(key, "SII");
strcpy(val, "1");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_TRUE(nodeData.resolutionData.GetMrpRetryIntervalIdle().HasValue());
EXPECT_EQ(nodeData.resolutionData.GetMrpRetryIntervalIdle().Value(), 1_ms32);
// Maximum
strcpy(key, "SII");
strcpy(val, "3600000");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_TRUE(nodeData.resolutionData.GetMrpRetryIntervalIdle().HasValue());
EXPECT_EQ(nodeData.resolutionData.GetMrpRetryIntervalIdle().Value(), 3600000_ms32);
// Test no other fields were populated
ResetRetryIntervalIdle(nodeData);
EXPECT_TRUE(NodeDataIsEmpty(nodeData));
// Invalid SII - negative value
strcpy(key, "SII");
strcpy(val, "-1");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryIntervalIdle().HasValue());
// Invalid SII - greater than maximum
strcpy(key, "SII");
strcpy(val, "3600001");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryIntervalIdle().HasValue());
// Invalid SII - much greater than maximum
strcpy(key, "SII");
strcpy(val, "1095216660481"); // 0xFF00000001 == 1 (mod 2^32)
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryIntervalIdle().HasValue());
// Invalid SII - hexadecimal value
strcpy(key, "SII");
strcpy(val, "0x20");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryIntervalIdle().HasValue());
// Invalid SII - leading zeros
strcpy(key, "SII");
strcpy(val, "0700");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryIntervalIdle().HasValue());
// Invalid SII - text at the end
strcpy(key, "SII");
strcpy(val, "123abc");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryIntervalIdle().HasValue());
}
TEST(TestTxtFields, TxtDiscoveredFieldMrpRetryIntervalIdle)
{
TxtFieldSessionIdleInterval<DiscoveredNodeData>();
}
TEST(TestTxtFields, TxtResolvedFieldMrpRetryIntervalIdle)
{
TxtFieldSessionIdleInterval<ResolvedNodeData>();
}
// Test SAI (formerly CRA)
template <class NodeData>
void TxtFieldSessionActiveInterval()
{
char key[4];
char val[16];
NodeData nodeData;
// Minimum
strcpy(key, "SAI");
strcpy(val, "1");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_TRUE(nodeData.resolutionData.GetMrpRetryIntervalActive().HasValue());
EXPECT_EQ(nodeData.resolutionData.GetMrpRetryIntervalActive().Value(), 1_ms32);
// Maximum
strcpy(key, "SAI");
strcpy(val, "3600000");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_TRUE(nodeData.resolutionData.GetMrpRetryIntervalActive().HasValue());
EXPECT_EQ(nodeData.resolutionData.GetMrpRetryIntervalActive().Value(), 3600000_ms32);
// Test no other fields were populated
ResetRetryIntervalActive(nodeData);
EXPECT_TRUE(NodeDataIsEmpty(nodeData));
// Invalid SAI - negative value
strcpy(key, "SAI");
strcpy(val, "-1");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryIntervalActive().HasValue());
// Invalid SAI - greater than maximum
strcpy(key, "SAI");
strcpy(val, "3600001");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryIntervalActive().HasValue());
// Invalid SAI - much greater than maximum
strcpy(key, "SAI");
strcpy(val, "1095216660481"); // 0xFF00000001 == 1 (mod 2^32)
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryIntervalActive().HasValue());
// Invalid SAI - hexadecimal value
strcpy(key, "SAI");
strcpy(val, "0x20");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryIntervalActive().HasValue());
// Invalid SAI - leading zeros
strcpy(key, "SAI");
strcpy(val, "0700");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryIntervalActive().HasValue());
// Invalid SAI - text at the end
strcpy(key, "SAI");
strcpy(val, "123abc");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryIntervalActive().HasValue());
}
TEST(TestTxtFields, TxtDiscoveredFieldMrpRetryIntervalActive)
{
TxtFieldSessionActiveInterval<DiscoveredNodeData>();
}
TEST(TestTxtFields, TxtResolvedFieldMrpRetryIntervalActive)
{
TxtFieldSessionActiveInterval<ResolvedNodeData>();
}
// Test SAT (Session Active Threshold)
template <class NodeData>
void TxtFieldSessionActiveThreshold()
{
char key[4];
char val[16];
NodeData nodeData;
// Minimum
strcpy(key, "SAT");
strcpy(val, "1");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_TRUE(nodeData.resolutionData.GetMrpRetryActiveThreshold().HasValue());
EXPECT_EQ(nodeData.resolutionData.GetMrpRetryActiveThreshold().Value(), 1_ms16);
// Maximum
strcpy(key, "SAT");
strcpy(val, "65535");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_TRUE(nodeData.resolutionData.GetMrpRetryActiveThreshold().HasValue());
EXPECT_EQ(nodeData.resolutionData.GetMrpRetryActiveThreshold().Value(), 65535_ms16);
// Test no other fields were populated
ResetRetryActiveThreshold(nodeData);
EXPECT_TRUE(NodeDataIsEmpty(nodeData));
// Invalid SAI - negative value
strcpy(key, "SAT");
strcpy(val, "-1");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryActiveThreshold().HasValue());
// Invalid SAI - greater than maximum
strcpy(key, "SAT");
strcpy(val, "65536");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryActiveThreshold().HasValue());
// Invalid SAT - much greater than maximum
strcpy(key, "SAT");
strcpy(val, "1095216660481"); // 0xFF00000001 == 1 (mod 2^32)
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryActiveThreshold().HasValue());
// Invalid SAT - hexadecimal value
strcpy(key, "SAT");
strcpy(val, "0x20");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryActiveThreshold().HasValue());
// Invalid SAT - leading zeros
strcpy(key, "SAT");
strcpy(val, "0700");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryActiveThreshold().HasValue());
// Invalid SAT - text at the end
strcpy(key, "SAT");
strcpy(val, "123abc");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.GetMrpRetryActiveThreshold().HasValue());
}
TEST(TestTxtFields, TxtDiscoveredFieldMrpRetryActiveThreshold)
{
TxtFieldSessionActiveThreshold<DiscoveredNodeData>();
}
TEST(TestTxtFields, TxtResolvedFieldMrpRetryActiveThreshold)
{
TxtFieldSessionActiveThreshold<ResolvedNodeData>();
}
// Test T (TCP support)
template <class NodeData>
void TxtFieldTcpSupport()
{
char key[4];
char val[8];
NodeData nodeData;
// True
strcpy(key, "T");
strcpy(val, "1");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_TRUE(nodeData.resolutionData.supportsTcp);
// Test no other fields were populated
nodeData.resolutionData.supportsTcp = false;
EXPECT_TRUE(NodeDataIsEmpty(nodeData));
// False
strcpy(key, "T");
strcpy(val, "0");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_EQ(nodeData.resolutionData.supportsTcp, false);
// Invalid value, stil false
strcpy(key, "T");
strcpy(val, "asdf");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_EQ(nodeData.resolutionData.supportsTcp, false);
}
TEST(TestTxtFields, TxtDiscoveredFieldTcpSupport)
{
TxtFieldTcpSupport<DiscoveredNodeData>();
}
TEST(TestTxtFields, TxtResolvedFieldTcpSupport)
{
TxtFieldTcpSupport<ResolvedNodeData>();
}
// Test ICD (ICD operation Mode)
template <class NodeData>
void TxtFieldICDoperatesAsLIT()
{
char key[4];
char val[16];
NodeData nodeData;
// ICD is operating as a LIT device
strcpy(key, "ICD");
strcpy(val, "1");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_TRUE(nodeData.resolutionData.isICDOperatingAsLIT.HasValue());
EXPECT_TRUE(nodeData.resolutionData.isICDOperatingAsLIT.Value());
// Test no other fields were populated
nodeData.resolutionData.isICDOperatingAsLIT.ClearValue();
EXPECT_TRUE(NodeDataIsEmpty(nodeData));
// ICD is operating as a SIT device
strcpy(key, "ICD");
strcpy(val, "0");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_TRUE(nodeData.resolutionData.isICDOperatingAsLIT.HasValue());
EXPECT_EQ(nodeData.resolutionData.isICDOperatingAsLIT.Value(), false);
nodeData.resolutionData.isICDOperatingAsLIT.ClearValue();
EXPECT_TRUE(NodeDataIsEmpty(nodeData));
// Invalid value, No key set
strcpy(key, "ICD");
strcpy(val, "asdf");
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_EQ(nodeData.resolutionData.isICDOperatingAsLIT.HasValue(), false);
}
TEST(TestTxtFields, TxtDiscoveredIsICDoperatingAsLIT)
{
TxtFieldICDoperatesAsLIT<DiscoveredNodeData>();
}
TEST(TestTxtFields, TxtResolvedFieldICDoperatingAsLIT)
{
TxtFieldICDoperatesAsLIT<ResolvedNodeData>();
}
// Test IsDeviceTreatedAsSleepy() with CRI
template <class NodeData>
void TestIsDeviceSessionIdle()
{
char key[4];
char val[32];
NodeData nodeData;
const ReliableMessageProtocolConfig defaultMRPConfig(CHIP_CONFIG_MRP_LOCAL_IDLE_RETRY_INTERVAL,
CHIP_CONFIG_MRP_LOCAL_ACTIVE_RETRY_INTERVAL);
// No key/val set, so the device can't be sleepy
EXPECT_FALSE(nodeData.resolutionData.IsDeviceTreatedAsSleepy(&defaultMRPConfig));
// If the interval is the default value, the device is not sleepy
strcpy(key, "SII");
sprintf(val, "%d", static_cast<int>(CHIP_CONFIG_MRP_LOCAL_IDLE_RETRY_INTERVAL.count()));
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.IsDeviceTreatedAsSleepy(&defaultMRPConfig));
// If the interval is greater than the default value, the device is sleepy
sprintf(key, "SII");
sprintf(val, "%d", static_cast<int>(CHIP_CONFIG_MRP_LOCAL_IDLE_RETRY_INTERVAL.count() + 1));
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_TRUE(nodeData.resolutionData.IsDeviceTreatedAsSleepy(&defaultMRPConfig));
}
TEST(TestTxtFields, TxtDiscoveredIsDeviceSessionIdle)
{
TestIsDeviceSessionIdle<DiscoveredNodeData>();
}
TEST(TestTxtFields, TxtResolvedIsDeviceSessionIdle)
{
TestIsDeviceSessionIdle<ResolvedNodeData>();
}
// Test IsDeviceTreatedAsSleepy() with CRA
template <class NodeData>
void TestIsDeviceSessionActive()
{
char key[4];
char val[32];
NodeData nodeData;
const ReliableMessageProtocolConfig defaultMRPConfig(CHIP_CONFIG_MRP_LOCAL_IDLE_RETRY_INTERVAL,
CHIP_CONFIG_MRP_LOCAL_ACTIVE_RETRY_INTERVAL);
// No key/val set, so the device can't be sleepy
EXPECT_FALSE(nodeData.resolutionData.IsDeviceTreatedAsSleepy(&defaultMRPConfig));
// If the interval is the default value, the device is not sleepy
sprintf(key, "SAI");
sprintf(val, "%d", static_cast<int>(CHIP_CONFIG_MRP_LOCAL_ACTIVE_RETRY_INTERVAL.count()));
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_FALSE(nodeData.resolutionData.IsDeviceTreatedAsSleepy(&defaultMRPConfig));
// If the interval is greater than the default value, the device is sleepy
strcpy(key, "SAI");
sprintf(val, "%d", static_cast<int>(CHIP_CONFIG_MRP_LOCAL_ACTIVE_RETRY_INTERVAL.count() + 1));
FillNodeDataFromTxt(GetSpan(key), GetSpan(val), nodeData.resolutionData);
EXPECT_TRUE(nodeData.resolutionData.IsDeviceTreatedAsSleepy(&defaultMRPConfig));
}
TEST(TestTxtFields, TxtDiscoveredIsDeviceSessionActive)
{
TestIsDeviceSessionActive<DiscoveredNodeData>();
}
TEST(TestTxtFields, TxtResolvedIsDeviceSessionActive)
{
TestIsDeviceSessionActive<ResolvedNodeData>();
}
} // namespace