Detect Direct Network Flood in Google Chronicle
Adversaries may attempt to cause a denial of service (DoS) by directly sending a high-volume of network traffic to a target. Direct Network Floods use one or more systems to send high-volume network packets toward the targeted service or network. Any network protocol may be used — stateless protocols such as UDP and ICMP are common due to their low overhead, but TCP SYN floods are also prevalent. Botnets are frequently leveraged to amplify attack volume, with compromised endpoints acting as unwitting flood sources. Organizations may detect this technique either as a victim observing inbound traffic spikes, or by identifying compromised endpoints in their environment participating in an outbound DDoS campaign as botnet nodes.
MITRE ATT&CK
- Tactic
- Impact
- Technique
- T1498 Network Denial of Service
- Sub-technique
- T1498.001 Direct Network Flood
- Canonical reference
- https://attack.mitre.org/techniques/T1498/001/
YARA-L Detection Query
rule t1498_001_direct_network_flood {
meta:
author = "Detection Engineering"
description = "Detects execution of known DDoS and network flood tools on endpoints. Matches process name and flood-specific command-line arguments indicative of T1498.001 Direct Network Flood activity."
mitre_attack_tactic = "Impact"
mitre_attack_technique = "T1498.001"
mitre_attack_technique_name = "Direct Network Flood"
severity = "HIGH"
priority = "HIGH"
reference = "https://attack.mitre.org/techniques/T1498/001/"
version = "1.0"
events:
$e.metadata.event_type = "PROCESS_LAUNCH"
(
re.regex($e.principal.process.file.full_path, `(?i)(hping3?|nping|trafgen|t50|loic|hoic|mhddos|ufonet|goldeneye|xerxes|udpflood|synflood|icmpflood|pyflood|rudy|packetsender|ostinato|netcat)`) or
re.regex($e.target.process.file.full_path, `(?i)(hping3?|nping|trafgen|t50|loic|hoic|mhddos|ufonet|goldeneye|xerxes|udpflood|synflood|icmpflood|pyflood|rudy|packetsender|ostinato)`) or
re.regex($e.target.process.command_line, `(?i)(--flood|-i\s+u0|--rand-dest|--rand-source|--syn.*--flood|--icmp.*--flood|--udp.*--flood|--faster|--turbo|--rate\s+\d{5,}|-c\s+\d{6,}|--count\s+\d{6,})`)
)
outcome:
$hostname = $e.principal.hostname
$username = $e.principal.user.userid
$process_name = $e.target.process.file.full_path
$command_line = $e.target.process.command_line
$parent_process = $e.principal.process.file.full_path
$is_known_tool = re.regex($e.target.process.file.full_path, `(?i)(hping3?|nping|trafgen|t50|loic|hoic|mhddos|ufonet|goldeneye|xerxes|udpflood|synflood|icmpflood|pyflood|rudy|packetsender|ostinato)`)
$has_flood_args = re.regex($e.target.process.command_line, `(?i)(--flood|-i\s+u0|--rand-dest|--rand-source|--faster|--turbo|--rate\s+\d{5,})`)
condition:
$e
}Chronicle YARA-L 2.0 rule detecting T1498.001 Direct Network Flood via process launch events in the UDM. Matches known flood tool binaries (hping3, LOIC, MHDDoS, GoldenEye, UFONet, etc.) by full path regex against both principal and target process fields, as well as flood-specific command-line argument patterns. Compatible with Sysmon, EDR, and OS telemetry ingested via Chronicle forwarders or BindPlane.
Data Sources
Required Tables
False Positives & Tuning
- Authorized network capacity testing performed by infrastructure teams using hping3 or nping on internal lab segments with documented approval
- Red team engagements where flood tools are run from operator workstations against in-scope targets — correlate with engagement calendar to suppress known windows
- Developers or security researchers building or testing network simulation tooling who may call flood-adjacent binaries from build pipelines or CI runners
Other platforms for T1498.001
Testing Methodology
Validate this detection against 4 adversary techniques from Atomic Red Team. Each test below lists the behaviour to exercise and the telemetry you should expect to see. Executable commands and cleanup steps are available with Pro.
- Test 1UDP Flood with hping3 to Localhost
Expected signal: Linux auditd: syscall execve for hping3 with argv containing '--udp', '--flood', '-p 53', '127.0.0.1'. Sysmon for Linux (if deployed): Process execution event with Image=hping3 and full CommandLine. Network metrics: High-volume UDP packet rate on loopback interface visible in netstat -s and /proc/net/udp. The -c 10000 flag limits total packets to prevent resource exhaustion.
- Test 2PowerShell UDP Packet Burst to Localhost
Expected signal: Sysmon Event ID 1: Process Create for powershell.exe with CommandLine containing 'UdpClient', 'Send', 'Loopback'. Sysmon Event ID 3: High-frequency network connection events to 127.0.0.1:53 — this will generate thousands of Event ID 3 records in the Sysmon log. PowerShell ScriptBlock Log Event ID 4104 with full script content if ScriptBlock logging is enabled.
- Test 3ICMP Flood with ping -f to Localhost
Expected signal: Linux auditd: syscall execve for ping with argv '-f', '-c', '10000', '127.0.0.1'. Process execution in syslog or Sysmon for Linux. Output shows packet statistics: '10000 packets transmitted, 10000 received, 0% packet loss'. Network metrics show ICMP packet rate spike on loopback interface visible via /proc/net/snmp ICMP counters.
- Test 4LOIC Flood Tool Binary Staging and Execution Simulation
Expected signal: Sysmon Event ID 11: File Create event for %TEMP%\loic.exe — triggers the file-staging hunting query on flood tool binary name. Sysmon Event ID 1: Process Create for loic.exe with CommandLine '--method udp --target 127.0.0.1 --port 80 --threads 10'. Security Event ID 4688 (if command-line auditing enabled) with same process details. Sysmon Event ID 7: Image Load events showing DLLs loaded by the loic.exe process.
References (8)
- https://attack.mitre.org/techniques/T1498/001/
- https://www.cisco.com/c/en/us/td/docs/ios-xml/ios/netflow/configuration/15-mt/nf-15-mt-book/nf-detct-analy-thrts.pdf
- https://www.justice.gov/opa/pr/seven-iranians-working-islamic-revolutionary-guard-corps-affiliated-entities-charged
- https://github.com/redcanaryco/atomic-red-team/blob/master/atomics/T1498.001/T1498.001.md
- https://learn.microsoft.com/en-us/azure/ddos-protection/ddos-protection-overview
- https://learn.microsoft.com/en-us/defender-endpoint/advanced-hunting-devicenetworkevents-table
- https://learn.microsoft.com/en-us/defender-endpoint/advanced-hunting-deviceprocessevents-table
- https://learn.microsoft.com/en-us/defender-endpoint/advanced-hunting-devicefileevents-table
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