CWE-798: Use of Hard-coded CredentialsWeakness ID: 798 Vulnerability Mapping:
ALLOWEDThis CWE ID may be used to map to real-world vulnerabilities Abstraction: BaseBase - a weakness that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource. |
Description The product contains hard-coded credentials, such as a password or cryptographic key. | ![Diagram for CWE-798](https://cdn.statically.io/img/cwe.mitre.org/data/images/CWE-798-Diagram.png) |
Extended Description There are two main variations: - Inbound: the product contains an authentication mechanism that checks the input credentials against a hard-coded set of credentials. In this variant, a default administration account is created, and a simple password is hard-coded into the product and associated with that account. This hard-coded password is the same for each installation of the product, and it usually cannot be changed or disabled by system administrators without manually modifying the program, or otherwise patching the product. It can also be difficult for the administrator to detect.
- Outbound: the product connects to another system or component, and it contains hard-coded credentials for connecting to that component. This variant applies to front-end systems that authenticate with a back-end service. The back-end service may require a fixed password that can be easily discovered. The programmer may simply hard-code those back-end credentials into the front-end product.
Common Consequences This table specifies different individual consequences associated with the weakness. The Scope identifies the application security area that is violated, while the Impact describes the negative technical impact that arises if an adversary succeeds in exploiting this weakness. The Likelihood provides information about how likely the specific consequence is expected to be seen relative to the other consequences in the list. For example, there may be high likelihood that a weakness will be exploited to achieve a certain impact, but a low likelihood that it will be exploited to achieve a different impact.Scope | Impact | Likelihood |
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Access Control
| Technical Impact: Bypass Protection Mechanism If hard-coded passwords are used, it is almost certain that malicious users will gain access to the account in question. Any user of the product that hard-codes passwords may be able to extract the password. Client-side systems with hard-coded passwords pose even more of a threat, since the extraction of a password from a binary is usually very simple. | | Integrity Confidentiality Availability Access Control Other
| Technical Impact: Read Application Data; Gain Privileges or Assume Identity; Execute Unauthorized Code or Commands; Other This weakness can lead to the exposure of resources or functionality to unintended actors, possibly providing attackers with sensitive information or even execute arbitrary code. If the password is ever discovered or published (a common occurrence on the Internet), then anybody with knowledge of this password can access the product. Finally, since all installations of the product will have the same password, even across different organizations, this enables massive attacks such as worms to take place. | |
Potential Mitigations
Phase: Architecture and Design For outbound authentication: store passwords, keys, and other credentials outside of the code in a strongly-protected, encrypted configuration file or database that is protected from access by all outsiders, including other local users on the same system. Properly protect the key ( CWE-320). If you cannot use encryption to protect the file, then make sure that the permissions are as restrictive as possible [ REF-7]. In Windows environments, the Encrypted File System (EFS) may provide some protection. |
Phase: Architecture and Design For inbound authentication: Rather than hard-code a default username and password, key, or other authentication credentials for first time logins, utilize a "first login" mode that requires the user to enter a unique strong password or key. |
Phase: Architecture and Design If the product must contain hard-coded credentials or they cannot be removed, perform access control checks and limit which entities can access the feature that requires the hard-coded credentials. For example, a feature might only be enabled through the system console instead of through a network connection. |
Phase: Architecture and Design For inbound authentication using passwords: apply strong one-way hashes to passwords and store those hashes in a configuration file or database with appropriate access control. That way, theft of the file/database still requires the attacker to try to crack the password. When handling an incoming password during authentication, take the hash of the password and compare it to the saved hash. Use randomly assigned salts for each separate hash that is generated. This increases the amount of computation that an attacker needs to conduct a brute-force attack, possibly limiting the effectiveness of the rainbow table method. |
Phase: Architecture and Design For front-end to back-end connections: Three solutions are possible, although none are complete. The first suggestion involves the use of generated passwords or keys that are changed automatically and must be entered at given time intervals by a system administrator. These passwords will be held in memory and only be valid for the time intervals. Next, the passwords or keys should be limited at the back end to only performing actions valid for the front end, as opposed to having full access. Finally, the messages sent should be tagged and checksummed with time sensitive values so as to prevent replay-style attacks.
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Relationships This table shows the weaknesses and high level categories that are related to this weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to similar items that may exist at higher and lower levels of abstraction. In addition, relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user may want to explore. Relevant to the view "Research Concepts" (CWE-1000) Nature | Type | ID | Name |
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ChildOf | Base - a weakness
that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource. | 344 | Use of Invariant Value in Dynamically Changing Context | ChildOf | Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource. | 671 | Lack of Administrator Control over Security | ChildOf | Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource. | 1391 | Use of Weak Credentials | ParentOf | Variant - a weakness
that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource. | 259 | Use of Hard-coded Password | ParentOf | Variant - a weakness
that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource. | 321 | Use of Hard-coded Cryptographic Key | PeerOf | Base - a weakness
that is still mostly independent of a resource or technology, but with sufficient details to provide specific methods for detection and prevention. Base level weaknesses typically describe issues in terms of 2 or 3 of the following dimensions: behavior, property, technology, language, and resource. | 257 | Storing Passwords in a Recoverable Format |
This table shows the weaknesses and high level categories that are related to this weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to similar items that may exist at higher and lower levels of abstraction. In addition, relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user may want to explore. This table shows the weaknesses and high level categories that are related to this weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to similar items that may exist at higher and lower levels of abstraction. In addition, relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user may want to explore. Relevant to the view "Weaknesses for Simplified Mapping of Published Vulnerabilities" (CWE-1003) Nature | Type | ID | Name |
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ChildOf | Class - a weakness that is described in a very abstract fashion, typically independent of any specific language or technology. More specific than a Pillar Weakness, but more general than a Base Weakness. Class level weaknesses typically describe issues in terms of 1 or 2 of the following dimensions: behavior, property, and resource. | 287 | Improper Authentication |
This table shows the weaknesses and high level categories that are related to this weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to similar items that may exist at higher and lower levels of abstraction. In addition, relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user may want to explore. Relevant to the view "Architectural Concepts" (CWE-1008) Nature | Type | ID | Name |
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MemberOf | Category - a CWE entry that contains a set of other entries that share a common characteristic. | 1010 | Authenticate Actors |
This table shows the weaknesses and high level categories that are related to this weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to similar items that may exist at higher and lower levels of abstraction. In addition, relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user may want to explore. Relevant to the view "CISQ Quality Measures (2020)" (CWE-1305) Nature | Type | ID | Name |
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ParentOf | Variant - a weakness
that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource. | 259 | Use of Hard-coded Password | ParentOf | Variant - a weakness
that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource. | 321 | Use of Hard-coded Cryptographic Key |
This table shows the weaknesses and high level categories that are related to this weakness. These relationships are defined as ChildOf, ParentOf, MemberOf and give insight to similar items that may exist at higher and lower levels of abstraction. In addition, relationships such as PeerOf and CanAlsoBe are defined to show similar weaknesses that the user may want to explore. Relevant to the view "CISQ Data Protection Measures" (CWE-1340) Nature | Type | ID | Name |
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ParentOf | Variant - a weakness
that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource. | 259 | Use of Hard-coded Password | ParentOf | Variant - a weakness
that is linked to a certain type of product, typically involving a specific language or technology. More specific than a Base weakness. Variant level weaknesses typically describe issues in terms of 3 to 5 of the following dimensions: behavior, property, technology, language, and resource. | 321 | Use of Hard-coded Cryptographic Key |
Modes Of Introduction The different Modes of Introduction provide information about how and when this weakness may be introduced. The Phase identifies a point in the life cycle at which introduction may occur, while the Note provides a typical scenario related to introduction during the given phase.Phase | Note |
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Architecture and Design | REALIZATION: This weakness is caused during implementation of an architectural security tactic. |
Likelihood Of Exploit Demonstrative Examples Example 1 The following code uses a hard-coded password to connect to a database: (bad code) Example Language: Java
... DriverManager.getConnection(url, "scott", "tiger"); ...
This is an example of an external hard-coded password on the client-side of a connection. This code will run successfully, but anyone who has access to it will have access to the password. Once the program has shipped, there is no going back from the database user "scott" with a password of "tiger" unless the program is patched. A devious employee with access to this information can use it to break into the system. Even worse, if attackers have access to the bytecode for application, they can use the javap -c command to access the disassembled code, which will contain the values of the passwords used. The result of this operation might look something like the following for the example above:
javap -c ConnMngr.class 22: ldc #36; //String jdbc:mysql://ixne.com/rxsql 24: ldc #38; //String scott 26: ldc #17; //String tiger
Example 2 The following code is an example of an internal hard-coded password in the back-end: (bad code) Example Language: C
int VerifyAdmin(char *password) {
if (strcmp(password, "Mew!")) {
printf("Incorrect Password!\n"); return(0)
} printf("Entering Diagnostic Mode...\n"); return(1);
}
(bad code) Example Language: Java
int VerifyAdmin(String password) { if (!password.equals("Mew!")) { return(0) } //Diagnostic Mode return(1); }
Every instance of this program can be placed into diagnostic mode with the same password. Even worse is the fact that if this program is distributed as a binary-only distribution, it is very difficult to change that password or disable this "functionality." Example 3 The following code examples attempt to verify a password using a hard-coded cryptographic key. (bad code) Example Language: C
int VerifyAdmin(char *password) {
if (strcmp(password,"68af404b513073584c4b6f22b6c63e6b")) {
printf("Incorrect Password!\n"); return(0);
} printf("Entering Diagnostic Mode...\n"); return(1);
}
(bad code) Example Language: Java
public boolean VerifyAdmin(String password) { if (password.equals("68af404b513073584c4b6f22b6c63e6b")) { System.out.println("Entering Diagnostic Mode..."); return true; } System.out.println("Incorrect Password!"); return false;
(bad code) Example Language: C#
int VerifyAdmin(String password) { if (password.Equals("68af404b513073584c4b6f22b6c63e6b")) { Console.WriteLine("Entering Diagnostic Mode..."); return(1); } Console.WriteLine("Incorrect Password!"); return(0); }
The cryptographic key is within a hard-coded string value that is compared to the password. It is likely that an attacker will be able to read the key and compromise the system. Example 4 The following examples show a portion of properties and configuration files for Java and ASP.NET applications. The files include username and password information but they are stored in cleartext. This Java example shows a properties file with a cleartext username / password pair. (bad code) Example Language: Java
# Java Web App ResourceBundle properties file
... webapp.ldap.username=secretUsername webapp.ldap.password=secretPassword ...
The following example shows a portion of a configuration file for an ASP.Net application. This configuration file includes username and password information for a connection to a database but the pair is stored in cleartext. (bad code) Example Language: ASP.NET
... <connectionStrings> <add name="ud_DEV" connectionString="connectDB=uDB; uid=db2admin; pwd=password; dbalias=uDB;" providerName="System.Data.Odbc" /> </connectionStrings> ...
Username and password information should not be included in a configuration file or a properties file in cleartext as this will allow anyone who can read the file access to the resource. If possible, encrypt this information. Example 5 In 2022, the OT:ICEFALL study examined products by 10 different Operational Technology (OT) vendors. The researchers reported 56 vulnerabilities and said that the products were "insecure by design" [REF-1283]. If exploited, these vulnerabilities often allowed adversaries to change how the products operated, ranging from denial of service to changing the code that the products executed. Since these products were often used in industries such as power, electrical, water, and others, there could even be safety implications. Multiple vendors used hard-coded credentials in their OT products. Observed Examples Reference | Description |
| Condition Monitor firmware has a maintenance interface with hard-coded credentials |
| Engineering Workstation uses hard-coded cryptographic keys that could allow for unathorized filesystem access and privilege escalation |
| Distributed Control System (DCS) has hard-coded passwords for local shell access |
| Programmable Logic Controller (PLC) has a maintenance service that uses undocumented, hard-coded credentials |
| Firmware for a Safety Instrumented System (SIS) has hard-coded credentials for access to boot configuration |
| Remote Terminal Unit (RTU) uses a hard-coded SSH private key that is likely to be used in typical deployments |
| Telnet service for IoT feeder for dogs and cats has hard-coded password [ REF-1288] |
| Firmware for a WiFi router uses a hard-coded password for a BusyBox shell, allowing bypass of authentication through the UART port |
| Installation script has a hard-coded secret token value, allowing attackers to bypass authentication |
| SCADA system uses a hard-coded password to protect back-end database containing authorization information, exploited by Stuxnet worm |
| FTP server library uses hard-coded usernames and passwords for three default accounts |
| Chain: Router firmware uses hard-coded username and password for access to debug functionality, which can be used to execute arbitrary code |
| Server uses hard-coded authentication key |
| Backup product uses hard-coded username and password, allowing attackers to bypass authentication via the RPC interface |
| Security appliance uses hard-coded password allowing attackers to gain root access |
| Drive encryption product stores hard-coded cryptographic keys for encrypted configuration files in executable programs |
| VoIP product uses hard-coded public credentials that cannot be changed, which allows attackers to obtain sensitive information |
| VoIP product uses hard coded public and private SNMP community strings that cannot be changed, which allows remote attackers to obtain sensitive information |
| Backup product contains hard-coded credentials that effectively serve as a back door, which allows remote attackers to access the file system |
Weakness Ordinalities Ordinality | Description |
Primary | (where the weakness exists independent of other weaknesses) |
Detection Methods
Black Box Credential storage in configuration files is findable using black box methods, but the use of hard-coded credentials for an incoming authentication routine typically involves an account that is not visible outside of the code. |
Automated Static Analysis Automated white box techniques have been published for detecting hard-coded credentials for incoming authentication, but there is some expert disagreement regarding their effectiveness and applicability to a broad range of methods. |
Manual Static Analysis This weakness may be detectable using manual code analysis. Unless authentication is decentralized and applied throughout the product, there can be sufficient time for the analyst to find incoming authentication routines and examine the program logic looking for usage of hard-coded credentials. Configuration files could also be analyzed. Note: These may be more effective than strictly automated techniques. This is especially the case with weaknesses that are related to design and business rules. |
Manual Dynamic Analysis For hard-coded credentials in incoming authentication: use monitoring tools that examine the product's process as it interacts with the operating system and the network. This technique is useful in cases when source code is unavailable, if the product was not developed by you, or if you want to verify that the build phase did not introduce any new weaknesses. Examples include debuggers that directly attach to the running process; system-call tracing utilities such as truss (Solaris) and strace (Linux); system activity monitors such as FileMon, RegMon, Process Monitor, and other Sysinternals utilities (Windows); and sniffers and protocol analyzers that monitor network traffic. Attach the monitor to the process and perform a login. Using call trees or similar artifacts from the output, examine the associated behaviors and see if any of them appear to be comparing the input to a fixed string or value. |
Automated Static Analysis - Binary or Bytecode According to SOAR, the following detection techniques may be useful: Cost effective for partial coverage: Effectiveness: SOAR Partial |
Manual Static Analysis - Binary or Bytecode According to SOAR, the following detection techniques may be useful: |
Dynamic Analysis with Manual Results Interpretation According to SOAR, the following detection techniques may be useful: Cost effective for partial coverage: Network Sniffer Forced Path Execution
Effectiveness: SOAR Partial |
Manual Static Analysis - Source Code According to SOAR, the following detection techniques may be useful: |
Automated Static Analysis - Source Code According to SOAR, the following detection techniques may be useful: |
Automated Static Analysis According to SOAR, the following detection techniques may be useful: Cost effective for partial coverage: Effectiveness: SOAR Partial |
Architecture or Design Review According to SOAR, the following detection techniques may be useful: Inspection (IEEE 1028 standard) (can apply to requirements, design, source code, etc.) Formal Methods / Correct-By-Construction
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Memberships This MemberOf Relationships table shows additional CWE Categories and Views that reference this weakness as a member. This information is often useful in understanding where a weakness fits within the context of external information sources. Vulnerability Mapping Notes Usage: ALLOWED (this CWE ID could be used to map to real-world vulnerabilities) | Reason: Acceptable-Use | Rationale: This CWE entry is at the Base level of abstraction, which is a preferred level of abstraction for mapping to the root causes of vulnerabilities. | Comments: Carefully read both the name and description to ensure that this mapping is an appropriate fit. Do not try to 'force' a mapping to a lower-level Base/Variant simply to comply with this preferred level of abstraction. |
Notes Maintenance The Taxonomy_Mappings to ISA/IEC 62443 were added in CWE 4.10, but they are still under review and might change in future CWE versions. These draft mappings were performed by members of the "Mapping CWE to 62443" subgroup of the CWE-CAPEC ICS/OT Special Interest Group (SIG), and their work is incomplete as of CWE 4.10. The mappings are included to facilitate discussion and review by the broader ICS/OT community, and they are likely to change in future CWE versions. Taxonomy Mappings Mapped Taxonomy Name | Node ID | Fit | Mapped Node Name |
The CERT Oracle Secure Coding Standard for Java (2011) | MSC03-J | | Never hard code sensitive information |
OMG ASCSM | ASCSM-CWE-798 | | |
ISA/IEC 62443 | Part 3-3 | | Req SR 1.5 |
ISA/IEC 62443 | Part 4-2 | | Req CR 1.5 |
References Content History Submissions |
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Submission Date | Submitter | Organization |
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2010-01-15 (CWE 1.8, 2010-02-16) | CWE Content Team | MITRE | More abstract entry for hard-coded password and hard-coded cryptographic key. | Contributions |
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Contribution Date | Contributor | Organization |
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2023-01-24 (CWE 4.10, 2023-01-31) | "Mapping CWE to 62443" Sub-Working Group | CWE-CAPEC ICS/OT SIG | Suggested mappings to ISA/IEC 62443. | 2024-02-29 (CWE 4.15, 2024-07-16) | Abhi Balakrishnan | | Provided diagram to improve CWE usability | Modifications |
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Modification Date | Modifier | Organization |
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2010-04-05 | CWE Content Team | MITRE | updated Related_Attack_Patterns | 2010-06-21 | CWE Content Team | MITRE | updated Common_Consequences, References | 2010-09-27 | CWE Content Team | MITRE | updated Potential_Mitigations | 2010-12-13 | CWE Content Team | MITRE | updated Description | 2011-06-01 | CWE Content Team | MITRE | updated Common_Consequences, Relationships, Taxonomy_Mappings | 2011-06-27 | CWE Content Team | MITRE | updated Observed_Examples, Relationships | 2011-09-13 | CWE Content Team | MITRE | updated Potential_Mitigations, Relationships | 2012-05-11 | CWE Content Team | MITRE | updated Demonstrative_Examples, Related_Attack_Patterns, Relationships, Taxonomy_Mappings | 2012-10-30 | CWE Content Team | MITRE | updated Demonstrative_Examples, Potential_Mitigations | 2013-02-21 | CWE Content Team | MITRE | updated Applicable_Platforms, References | 2014-07-30 | CWE Content Team | MITRE | updated Demonstrative_Examples, Detection_Factors | 2015-12-07 | CWE Content Team | MITRE | updated Relationships | 2017-01-19 | CWE Content Team | MITRE | updated Related_Attack_Patterns | 2017-11-08 | CWE Content Team | MITRE | updated Causal_Nature, Demonstrative_Examples, Likelihood_of_Exploit, Modes_of_Introduction, References, Relationships | 2018-03-27 | CWE Content Team | MITRE | updated References | 2019-01-03 | CWE Content Team | MITRE | updated References, Relationships, Taxonomy_Mappings | 2019-06-20 | CWE Content Team | MITRE | updated Related_Attack_Patterns, Relationships | 2019-09-19 | CWE Content Team | MITRE | updated Relationships | 2020-02-24 | CWE Content Team | MITRE | updated Applicable_Platforms, Relationships | 2020-08-20 | CWE Content Team | MITRE | updated Relationships | 2020-12-10 | CWE Content Team | MITRE | updated Relationships | 2021-03-15 | CWE Content Team | MITRE | updated Demonstrative_Examples | 2021-07-20 | CWE Content Team | MITRE | updated Relationships | 2021-10-28 | CWE Content Team | MITRE | updated Relationships | 2022-06-28 | CWE Content Team | MITRE | updated Relationships | 2022-10-13 | CWE Content Team | MITRE | updated Applicable_Platforms, Demonstrative_Examples, Observed_Examples, References, Relationships | 2023-01-31 | CWE Content Team | MITRE | updated Description, Detection_Factors, Maintenance_Notes, Potential_Mitigations, Taxonomy_Mappings | 2023-04-27 | CWE Content Team | MITRE | updated References, Relationships | 2023-06-29 | CWE Content Team | MITRE | updated Mapping_Notes, Relationships | 2024-02-29 (CWE 4.14, 2024-02-29) | CWE Content Team | MITRE | updated Observed_Examples | 2024-07-16 (CWE 4.15, 2024-07-16) | CWE Content Team | MITRE | updated Common_Consequences, Description, Diagram |
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