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Project: Simulated Encrypted File System (SEFS) Omar Chowdhury Fall 2015CS526: Information Security1.

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Presentation on theme: "Project: Simulated Encrypted File System (SEFS) Omar Chowdhury Fall 2015CS526: Information Security1."— Presentation transcript:

1 Project: Simulated Encrypted File System (SEFS) Omar Chowdhury Fall 2015CS526: Information Security1

2 Motivation Traditionally files are stored in the disk in plaintext. If the disk gets stolen by a perpetrator, he can access all the data in the disk. Disk containing sensitive personal information getting stolen by hackers are very common. Fall 2015CS526: Information Security2

3 A Possible Defense (Encrypted File Systems) Defense: encrypt the files using some semantically secure encryption scheme. No one should be access/change the file’s contents without proper credentials. An individual with proper credentials should be able to perform all the necessary operations on the encrypted file. An encrypted file system (in short, EFS) can support such operations. Example: Solaris, Windows NT, and Linux support EFS. Fall 2015CS526: Information Security3

4 Goal of this Project Goal: Implement a simulated version of EFS Take-a-way message from cryptography lectures: Do not try to implement your own cryptography library rather use well-known cryptography libraries. We will specifically learn to usage of openSSL library. Additionally, we are trying something new this semester. To increase the communication between your classmates we want the projects to be inter-operable. Fall 2015CS526: Information Security4 Communication does not imply copying each other’s code

5 Logistics Team: You can work in a team of consisting of (maximum) two members. Fall 2015CS526: Information Security5 Project (1) User Authentication (2) Simplified SEFS (3) Full SEFS Inter-operability: 5% of the total project points. 20% 30% 45%

6 Part 1 – User Authentication using Passwords Username: Allowed characters: “a-zA-Z0-9” Length: >5 and <32 Password: Allowed characters: “a-zA-Z0-9@#$%&*()-+=” Length: >8 and <32 Salt: Randomly generated for each password Length 32 bytes Hashing algorithm: PKCS5_PBKDF2_HMAC_SHA1 Fall 2015CS526: Information Security6 Password file username:salt:hashedPassword ……………………………………….. passwd Field Separator Plaintext Hexadecimal 32 bytes

7 register_user(u,p,pFile) delete_user(u,p,pFile) is_user_valid(u,pFile) match_user(u,p,pFile) change_user_password(u,p,p n,pFile) Part 1 – Functionalities Fall 2015CS526: Information Security7 Password file u2:salt2:hashedPassword2 u1:salt1:hashedPassword1 u3:salt3:hashedPassword3 passwd Returns: OKAY -> 1 ERROR -> -1 Functions developed in this part of the project for checking user authentication will be used in the next two parts of the project.

8 Part 2 – Simplified SEFS Simplified SEFS Master key: Randomly generated, 128 bit Master IV: Randomly generated, 128 bit A sample master key file will be given to you which contains the binary representation of a key and IV. A sample key and IV loading program is given to you. A sample random key and IV generator program is given to you. Fall 2015CS526: Information Security8 Chunk file – Name can contain only alphanumeric characters File name length maximum 20 characters. Plaintext File F Meta File F.meta Chunk File Rname After encryption

9 Part 2 – File Format Fall 2015CS526: Information Security9 Meta file format Chunk file format File owner username Number of Chunks File size Start Chunk Name End Chunk Name Chunk name – Encryption key – Chunk HMAC IV (in plaintext) Next Chunk Name Size of File Content in this Chunk Plaintext file content 1 Same NULL

10 Master File List (Simplified SEFS Integrity Protection) Fall 2015CS526: Information Security10 File NameSHA256 Digest of the Meta file ………

11 Part 2 – Functionality create_file(u,p,filename) delete_file(u,p,filename) encrypt_file(u,p,filename) decrypt_file(u,p,filename,pfilename) read_from_file(u,p,filename,position,len) write_to_file(u,p,filename,position,newcontent) file_size(u,p,filename) file_integrity_check(u,p,filename) system_health_check() Fall 2015CS526: Information Security11 Returns: OKAY -> 1 ERROR -> -1 Returns: OKAY -> char * ERROR -> NULL

12 Part 2 – Read Operation Fall 2015CS526: Information Security12 Meta file format Chunk file format File owner username Number of Chunks File size Start Chunk Name End Chunk Name Chunk name – Encryption key – Chunk HMAC IV (in plaintext) Next Chunk Name Size of File Content in this Chunk Plaintext file content Master Key and IV

13 Full SEFS Generalization of the simplified SEFS. Each chunk can hold at most 1024 bytes of plaintext data. Each plaintext file can be divided into multiple encrypted chunk files. If a file has less than 1024 bytes of data, you are required to pad it with ASCII character 0 to make it 1024 bytes. Space restriction: You are required to use the minimum number of chunk files for storing each plaintext file Example: If you have a chunk containing 512 bytes of data and the user wants to write 200 bytes to the end of the chunk, you cannot create a new chunk and instead have to write into that chunk. Fall 2015CS526: Information Security13

14 Part 2 – Full SEFS Read Operation Fall 2015CS526: Information Security14 Meta file format Chunk file format File owner username Number of Chunks File size Start Chunk Name End Chunk Name Chunk name – Encryption key – Chunk HMAC IV (in plaintext) Next Chunk Name Size of File Content in this Chunk Plaintext file content ….

15 Potential Pitfalls Memory leaks – a lot of the operations of the project require pointer manipulation, make sure to free the pointer after usage File operations – file operations in C is complicated, you cannot write in the middle of a file without overwriting the content. You have to manually move the following content and then write something Error checking – a lot of errors can potentially happen during the operation and it is paramount that you do handle these errors. Do not assume inputs are well-formed. Perform input validation when applicable. Fall 2015CS526: Information Security15

16 Different parameters username a-zA-Z0-9 Length >= 6 and < 32 Password a-zA-Z0-9@#$%&*()-+= Length >= 9 and < 32 Password salt Randomly generated 32 bytes Master key 128 bits Master IV 128 bits Chunk keys 128 bits, randomly generated For encryption use, AES in the CTR mode Chunk IVs 128 bits, randomly generated Chunk names are randomly generated and cannot have space character in it For padding use the ASCII character 0 For hash mac, use HMAC with EVP_sha256() For digest, use SHA256 For password hash, use PKCS5_PBKDF2_HMAC_SHA1 with iteration value 20000 Fall 2015CS526: Information Security16

17 Questions If you do not understand any specifics, please do not make your own assumptions rather confirm with me. Making arbitrary, easy to implement assumptions will surely ensure you losing 5% of the inter-operability. Direct any questions related to the project to me through piazza, email (ochowdhu@purdue.edu), or drop by my office during office hours (LWSN 2142 R, Thursday 11:30am - 12:30pm)ochowdhu@purdue.edu Fall 2015CS526: Information Security17

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