| CVE |
Vendors |
Products |
Updated |
CVSS v3.1 |
| Encryption is missing on the configuration interface for Growatt ShineLan-X and MIC 3300TL-X. This allows an attacker with access to the network to intercept and potentially manipulate communication requests between the inverter and its cloud endpoint. |
| The SWD debug interface on the Growatt ShineLan-X communication dongle is available by default, allowing an attacker to attain debug access to the device and to extracting secrets or domains from within the device |
| ShineLan-X contains a stored cross site scripting (XSS) vulnerability in the Plant Name field. A HTML payload will be displayed on the plant management page via a direct post. This may allow attackers to force a legitimate user’s browser’s JavaScript engine to run malicious code. |
| ShineLan-X contains a stored cross site scripting (XSS) vulnerability in the local configuration web server. The JavaScript code snippet can be inserted in the communication module’s settings center. This may allow attackers to force a legitimate user’s browser’s JavaScript engine to run malicious code. |
| The authentication mechanism on web interface is not properly implemented. It is possible to bypass authentication checks by crafting a post request with new settings since there is no session token or authentication in place. This would allow an attacker for instance to point the device to an arbitrary address for domain name resolution to e.g. facililitate a man-in-the-middle (MitM) attack. |
| Growatt ShineLan-X communication dongle has an undocumented backup account with undocumented credentials which allows significant level access to the device, such as allowing any attacker to access the Setting Center. This means that this is effectively backdoor for all devices utilizing a Growatt ShineLan-X communication dongle. |
| ShineLan-X contains a set of credentials for an FTP server was found within the firmware, allowing testers to establish an insecure FTP connection with the server. This may allow an attacker to replace legitimate files being deployed to devices with their own malicious versions, since the firmware signature verification is not enforced. |
| An unauthenticated attacker can obtain a user's plant list by knowing the username. |
| An unauthenticated attacker can check the existence of usernames in the system by querying an API. |
| An unauthenticated attacker can obtain a list of smart devices by knowing a valid username. |
| An authenticated attacker can obtain any plant name by knowing the plant ID. |
| Due to lack of server-side input validation, attackers can inject malicious JavaScript code into users personal spaces of the web portal. |
| Unauthenticated attackers can add devices of other users to their scenes (or arbitrary scenes of other arbitrary users). |
| An attacker can export other users' plant information. |
| An unauthenticated attacker can hijack other users' devices and potentially control them. |
| Unauthenticated attackers can rename arbitrary devices of arbitrary users (i.e., EV chargers). |
| Unauthenticated attackers can rename "rooms" of arbitrary users. |
| An unauthenticated attacker can delete any user's "rooms" by knowing the user's and room IDs. |
| An unauthenticated attacker can obtain EV charger version and firmware upgrading history by knowing the charger ID. |
| Unauthenticated attackers can query an API endpoint and get device details. |
