logging in or signing up lec1 intro Esteban Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 128 Category: Entertainment License: All Rights Reserved Like it (0) Dislike it (0) Added: December 31, 2007 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript COS 433: Cryptography : COS 433: Cryptography Princeton University Fall 2007 Boaz BarakCryptography: Cryptography History of 2500- 4000 years. Recurring theme: (until 1970’s) Secret code invented Typically claimed “unbreakable” by inventor Used by spies, ambassadors, kings, generals for crucial tasks. Broken by enemy using cryptanalysis. Throughout most of this history: cryptography = “secret writing”: “Scramble” (encrypt) text such that it is hopefully unreadable by anyone except the intended receiver that can decrypt it. Examples: Examples 1587: Ciphers from Mary of Scots plotting assassination of queen Elizabeth broken; used as evidence to convict her of treason. 1860’s (civil war): Confederacy used good cipher (Vigenere) in a bad way. Messages routinely broken by team of young union cryptanalysts; in particular leading to a Manhattan manufacturer of plates for printing rebel currency. 1878: New York Tribune decodes telegram proving Democrats’ attempt to buy an electoral vote in presidential election for $10K. 1914: With aid of partial info from sunken German ships, British intelligence broke all German codes. Cracked telegram of German plan to form alliance with Mexico and conquer back territory from U.S. As a result, U.S. joined WWI. WWII: Cryptanalysis used by both sides. Polish & British cryptanalysts break supposedly unbreakable Enigma cipher using mix of ingenuity, German negligence, and mechanical computation. Churchill credits cryptanalysts with winning the war. This Course: This Course What you’ll learn: Foundations and principles of the science Definitions and proofs of security High-level applications Critical view of security suggestions and products What you will not learn: The most efficient and practical versions of components. Designing secure systems* “Hacking” – breaking into systems. Everything important about crypto Basic primitives and components. Viruses, worms, Windows/Unix bugs, buffer overflow etc.. Buzzwords Will help you avoid designing insecure systems. This Course: This Course Modern (post 1970’s) cryptography: Provable security – breaking the “invent-break-tweak” cycle Perfect security (Shannon) and its limitations Computational security Pseudorandom generators, one way functions Beyond encryption – public-key crypto and other wonderful creatures Public-key encryption based on factoring and RSA problem Digital signatures, hash functions Zero-knowledge proofs Active security – Chosen-Ciphertext Attack Advanced topics (won’t have time for all ) The SSL Protocol and attacks on it Secret Sharing Multi-party secure computation Quantum cryptography Password-based key-exchange, broadcast encryption, obfuscationAdministrative Info: Administrative Info Lectures: Tue,Thu 1:30-2:50pm (start on time!) Instructor: Boaz Barak: boaz@cs Web page: http://www.cs.princeton.edu/courses/archive/fall07/cos433/ Or: Google “Boaz Barak” and click “courses” TA: Rajsekar Manokaran ( rajsekar@cs ) Important: join mailing list, email me to set appointment before next class Office hrs: Thu after class (3pm) or by appointment. Precepts: --- Office hrs: ---Prerequisites: Prerequisites 1. Ability to read and write mathematical proofs and definitions. 2. Familiarity with algorithms – proving correctness and analyzing running time (O notation). Required: Helpful but not necessary: Complexity. NP-Completeness, reductions, P, BPP, P/poly Probabilistic Algorithms. Primality testing, hashing, Number theory. Modular arithmetic, prime numbers See web-site for links and resources. 3. Familiarity with basic probability theory (random variables, expectations – see handout).Reading: Reading Foundations of Cryptography / Goldreich. Graduate-level text, will be sometimes used. Lecture notes on web: (links on web site) Computational Intro to Algebra and Number Theory / Shoup. (Available also on the web) Introduction to the Theory of Computation / Sipser. For complexity background Introduction to Modern Cryptography / Katz & Lindell Main text used, though not 100% followedRequirements: Requirements Exercises: Weekly from Thursday till Thursday before class. Submit by email / mailbox / in class to Rajsekar. Flexibility: 4 late days, bonus questions Take home final. Final grade: 50% homework, 50% final Honor code. Collaboration on homework with other students encouraged. However, write alone and give credit. Work on final alone and as directed.This course is hard: This course is hard Challenging weekly exercises Emphasis on mathematical proofs Counterintuitive concepts. Extensive use of quantifiers/probability But it’s not my fault :) Good coverage of crypto (meat, vegetables and desert) takes a year. Simulation / experimentation can’t be used to show security. Need to acquire “crypto-intuition” Quantifiers, proofs by contradiction, reductions, probability are inherent. Mitigating hardness Avoid excessive exercises – only questions that teach you something. Try best to explain intuition behind proofs Me and Rajsekar available for any questions and clarifications.Encryption Schemes: Encryption Schemes Alice wants to send Bob a secret message. They agree in advance on 3 components: Encryption algorithm: E Decryption algorithm: D Secret key: k To encrypt plaintext m, Alice sends c = E(m,k) to Bob. To decrypt a cyphertext c, Bob computes m’ = D(c,k). c = E(m,k) m’ = D(c,k) A scheme is valid if m’=m Intuitively, a scheme is secure if eavesdropper can not learn m from c. Example 1: Caesar’s Cipher : Example 1: Caesar’s Cipher Key: k = no. between 0 and 25. Encryption: encode the ith letter as the (i+k) th letter. (working mod 26: z+1=a ) Decryption: decode the jth letter to the (j-k) th letter. S E N D R E I N F O R C E M E N T Plain-text: Key: 2 Cipher-text: U G P F T F K P H Q T E G O G P V Problem: only 26 possibilities for key – can be broken in short time. In other words: “security through obscurity” does not work.Example 2: Substitution Cipher: Example 2: Substitution Cipher Key: k = table mapping each letter to another letter A B C Z U R B E Encryption and decryption: letter by letter according to table. # of possible keys: 26! ( = 403,291,461,126,605,635,584,000,000 ) However – substitution cipher is still insecure! Key observation: can recover plaintext using statistics on letter frequencies. LIVITCSWPIYVEWHEVSRIQMXLEYVEOIEWHRXEXIPFEMVEWHKVSTYLX ZIXLIKIIXPIJVSZEYPERRGERIMWQLMGLMXQERIWGPSRIHMXQEREKI He e e e h e t t ht ethe eet e e h h t e e t e I – most common letter LI – most common pair XLI – most common triple Here e r e h e t t r r ht ethe eet e r e h h t e e t e I=e L=h X=t Here e ra a e ha a ea tat a ra r ht ethe eet e r a a e h h t a e e t a a e V=r E=a Y=g HereUpOnLeGrandAroseWithAGraveAndStatelyAirAndBrought MeTheBeetleFromAGlassCaseInWhichItWasEnclosedItWasABeExample 3- Vigenere: Example 3- Vigenere “Multi-Caesar Cipher” – A statefull cipher Key: k = (k1,k2,…,km) list of m numbers between 0 and 25 Encryption: 1st letter encoded as Caesar w/ key=k1 : i I + k1 (mod 26) 2nd letter encoded as Caesar w/ key=k2 : i I + k2 (mod 26) mth letter encoded as Caesar w/ key=km : i I + km (mod 26) m+1th letter encoded as Caesar w/ key=k1 : i I + k1 (mod 26) Decryption: In the natural way … Important Property: Can no longer break using letter frequencies alone. ‘e’ will be mapped to ‘e’+k1,‘e’+k2,…,‘e’+km according to location. nth letter encoded w/ key=k(n mod m) : i I + k(n mod m) (mod 26) Considered “unbreakable” for 300 years (broken by Babbage, Kasiski 1850’s) (Belaso, 1553)Example 3- Vigenere: Example 3- Vigenere “Multi-Caesar Cipher” – A statefull cipher Key: k = (k1,k2,…,km) list of m numbers between 0 and 25 Encryption: Breaking Vigenere: nth letter encoded w/ key=k(n mod m) : i I + k(n mod m) (mod 26) (Belaso, 1553) LIVITC SWPIYV EWHEVS RIQMXL EYVEOI EWHRXE XIPFEM VEWHKV Step 1: Guess the length of the key m Step 2: Group together positions {1, m+1, 2m+1, 3m+1,…} {m-1, 2m+m-1, 3m+m-1,…} Decryption: In the natural way … {2, m+2, 2m+2, 3m+2,…}Example 3- Vigenere: Example 3- Vigenere “Multi-Caesar Cipher” – A statefull cipher Key: k = (k1,k2,…,km) list of m numbers between 0 and 25 Encryption: Breaking Vigenere: nth letter encoded w/ key=k(n mod m) : i i + k(n mod m) (mod 26) (Belaso, 1553) LIVITC SWPIYV EWHEVS RIQMXL EYVEOI EWHRXE XIPFEM VEWHKV Step 1: Guess the length of the key m Step 2: Group together positions 1, m+1, 2m+1, 3m+1,… Step 3: Frequency-analyze each group independently. Decryption: In the natural way {m-1, 2m+m-1, 3m+m-1,…} … {2, m+2, 2m+2, 3m+2,…}Example 4 - The Enigma: Example 4 - The Enigma A mechanical statefull cipher. Roughly: composition of 3-5 substitution ciphers implemented by wiring. Wiring on rotors moving in different schedules, making cipher statefull Key: 1) Wiring of machine (changed infrequently) 2) Daily key from code books 3) New operator-chosen key for each message Tools used by Poles & British to break Enigma: 1) Mathematical analysis combined w/ mechanical computers 2) Captured machines and code-books 3) German operators negligence 4) Known plaintext attacks (greetings, weather reports) 5) Chosen plaintext attacks Used by Germany in WWII for top-secret communication.Post 1970’s Crypto: Post 1970’s Crypto Two major developments: 1) Provably secure cryptography Encryptions w/ mathematical proof that are unbreakable* * Currently use conjectures/axioms, however defeated all cryptanalysis effort so far. 2) Cryptography beyond “secret writing” Public-key encryptions Digital signatures Zero-knowledge proofs Anonymous electronic elections Privacy-preserving data mining e-cash …Review of Encryption Schemes: Review of Encryption Schemes Alice wants to send Bob a secret message. Encryption algorithm: E Decryption algorithm: D Secret key: k To encrypt m, Alice sends c = E(m,k) to Bob. To decrypt c, Bob computes m’ = D(c,k). c = E(m,k) m’ = D(c,k) Q: Can Bob send Alice the secret key over the net? A: Of course not!! Eve could decrypt c! Q: What if Bob could send Alice a “crippled key” useful only for encryption but no help for decryptionPublic Key Cryptography [DH76,RSA77]: Public Key Cryptography [DH76,RSA77] Alice wants to send Bob a secret message. Encryption algorithm: E Decryption algorithm: D To encrypt m, Alice sends c = E(m,e) to Bob. To decrypt c, Bob computes m’ = D(c,d). c = E(m,e) m’ = D(c,d) Key: Bob chooses two keys: Secret key d for decrypting messages. Public key e for encrypting messages. choose d,eOther Crypto Wonders: Other Crypto Wonders Digital Signatures. Electronically sign documents in unforgeable way. Zero-knowledge proofs. Alice proves to Bob that she earns <$50K without Bob learning her income. Privacy-preserving data mining. Bob holds DB. Alice gets answer to one query, without Bob knowing what she asked. Playing poker over the net. Alice, Bob, Carol and David can play poker over the net without trusting each other or any central server. Distributed systems. Distribute sensitive data to 7 servers s.t. as long as <3 are broken, no harm to security occurs. Electronic auctions. Can run auctions s.t. no one (even not seller) learns anything other than winning party and bid.Cryptography & Security: Cryptography & Security Prev slides: Have provably secure algorithm for every crypto task imaginable. Q: How come nothing is secure? A1: Not all of these are used or used correctly: Strange tendency to use “home-brewed” cryptosystems. Combining secure primitives in insecure way Strict efficiency requirements for crypto/security: Many provably secure algs not efficient enough The cost is visible but benefit invisible. Easy to get implementation wrong – many subtleties Compatibility issues, legacy systems, Misunderstanding properties of crypto components.Cryptography & Security: Cryptography & Security Prev slides: Have provably secure algorithm for every crypto task imaginable. Q: How come nothing is secure? A2: Cryptography is only part of designing secure systems Chain is only as strong as weakest link. A “dormant bug” is often a security hole. Security is hard to “modularize” Human element (hard to add to existing system, changes in system features can have unexpected consequences) Many subtle issues (e.g., caching & virtual memory, side channel attacks) Key storage and protection issues. You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
lec1 intro Esteban Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 128 Category: Entertainment License: All Rights Reserved Like it (0) Dislike it (0) Added: December 31, 2007 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript COS 433: Cryptography : COS 433: Cryptography Princeton University Fall 2007 Boaz BarakCryptography: Cryptography History of 2500- 4000 years. Recurring theme: (until 1970’s) Secret code invented Typically claimed “unbreakable” by inventor Used by spies, ambassadors, kings, generals for crucial tasks. Broken by enemy using cryptanalysis. Throughout most of this history: cryptography = “secret writing”: “Scramble” (encrypt) text such that it is hopefully unreadable by anyone except the intended receiver that can decrypt it. Examples: Examples 1587: Ciphers from Mary of Scots plotting assassination of queen Elizabeth broken; used as evidence to convict her of treason. 1860’s (civil war): Confederacy used good cipher (Vigenere) in a bad way. Messages routinely broken by team of young union cryptanalysts; in particular leading to a Manhattan manufacturer of plates for printing rebel currency. 1878: New York Tribune decodes telegram proving Democrats’ attempt to buy an electoral vote in presidential election for $10K. 1914: With aid of partial info from sunken German ships, British intelligence broke all German codes. Cracked telegram of German plan to form alliance with Mexico and conquer back territory from U.S. As a result, U.S. joined WWI. WWII: Cryptanalysis used by both sides. Polish & British cryptanalysts break supposedly unbreakable Enigma cipher using mix of ingenuity, German negligence, and mechanical computation. Churchill credits cryptanalysts with winning the war. This Course: This Course What you’ll learn: Foundations and principles of the science Definitions and proofs of security High-level applications Critical view of security suggestions and products What you will not learn: The most efficient and practical versions of components. Designing secure systems* “Hacking” – breaking into systems. Everything important about crypto Basic primitives and components. Viruses, worms, Windows/Unix bugs, buffer overflow etc.. Buzzwords Will help you avoid designing insecure systems. This Course: This Course Modern (post 1970’s) cryptography: Provable security – breaking the “invent-break-tweak” cycle Perfect security (Shannon) and its limitations Computational security Pseudorandom generators, one way functions Beyond encryption – public-key crypto and other wonderful creatures Public-key encryption based on factoring and RSA problem Digital signatures, hash functions Zero-knowledge proofs Active security – Chosen-Ciphertext Attack Advanced topics (won’t have time for all ) The SSL Protocol and attacks on it Secret Sharing Multi-party secure computation Quantum cryptography Password-based key-exchange, broadcast encryption, obfuscationAdministrative Info: Administrative Info Lectures: Tue,Thu 1:30-2:50pm (start on time!) Instructor: Boaz Barak: boaz@cs Web page: http://www.cs.princeton.edu/courses/archive/fall07/cos433/ Or: Google “Boaz Barak” and click “courses” TA: Rajsekar Manokaran ( rajsekar@cs ) Important: join mailing list, email me to set appointment before next class Office hrs: Thu after class (3pm) or by appointment. Precepts: --- Office hrs: ---Prerequisites: Prerequisites 1. Ability to read and write mathematical proofs and definitions. 2. Familiarity with algorithms – proving correctness and analyzing running time (O notation). Required: Helpful but not necessary: Complexity. NP-Completeness, reductions, P, BPP, P/poly Probabilistic Algorithms. Primality testing, hashing, Number theory. Modular arithmetic, prime numbers See web-site for links and resources. 3. Familiarity with basic probability theory (random variables, expectations – see handout).Reading: Reading Foundations of Cryptography / Goldreich. Graduate-level text, will be sometimes used. Lecture notes on web: (links on web site) Computational Intro to Algebra and Number Theory / Shoup. (Available also on the web) Introduction to the Theory of Computation / Sipser. For complexity background Introduction to Modern Cryptography / Katz & Lindell Main text used, though not 100% followedRequirements: Requirements Exercises: Weekly from Thursday till Thursday before class. Submit by email / mailbox / in class to Rajsekar. Flexibility: 4 late days, bonus questions Take home final. Final grade: 50% homework, 50% final Honor code. Collaboration on homework with other students encouraged. However, write alone and give credit. Work on final alone and as directed.This course is hard: This course is hard Challenging weekly exercises Emphasis on mathematical proofs Counterintuitive concepts. Extensive use of quantifiers/probability But it’s not my fault :) Good coverage of crypto (meat, vegetables and desert) takes a year. Simulation / experimentation can’t be used to show security. Need to acquire “crypto-intuition” Quantifiers, proofs by contradiction, reductions, probability are inherent. Mitigating hardness Avoid excessive exercises – only questions that teach you something. Try best to explain intuition behind proofs Me and Rajsekar available for any questions and clarifications.Encryption Schemes: Encryption Schemes Alice wants to send Bob a secret message. They agree in advance on 3 components: Encryption algorithm: E Decryption algorithm: D Secret key: k To encrypt plaintext m, Alice sends c = E(m,k) to Bob. To decrypt a cyphertext c, Bob computes m’ = D(c,k). c = E(m,k) m’ = D(c,k) A scheme is valid if m’=m Intuitively, a scheme is secure if eavesdropper can not learn m from c. Example 1: Caesar’s Cipher : Example 1: Caesar’s Cipher Key: k = no. between 0 and 25. Encryption: encode the ith letter as the (i+k) th letter. (working mod 26: z+1=a ) Decryption: decode the jth letter to the (j-k) th letter. S E N D R E I N F O R C E M E N T Plain-text: Key: 2 Cipher-text: U G P F T F K P H Q T E G O G P V Problem: only 26 possibilities for key – can be broken in short time. In other words: “security through obscurity” does not work.Example 2: Substitution Cipher: Example 2: Substitution Cipher Key: k = table mapping each letter to another letter A B C Z U R B E Encryption and decryption: letter by letter according to table. # of possible keys: 26! ( = 403,291,461,126,605,635,584,000,000 ) However – substitution cipher is still insecure! Key observation: can recover plaintext using statistics on letter frequencies. LIVITCSWPIYVEWHEVSRIQMXLEYVEOIEWHRXEXIPFEMVEWHKVSTYLX ZIXLIKIIXPIJVSZEYPERRGERIMWQLMGLMXQERIWGPSRIHMXQEREKI He e e e h e t t ht ethe eet e e h h t e e t e I – most common letter LI – most common pair XLI – most common triple Here e r e h e t t r r ht ethe eet e r e h h t e e t e I=e L=h X=t Here e ra a e ha a ea tat a ra r ht ethe eet e r a a e h h t a e e t a a e V=r E=a Y=g HereUpOnLeGrandAroseWithAGraveAndStatelyAirAndBrought MeTheBeetleFromAGlassCaseInWhichItWasEnclosedItWasABeExample 3- Vigenere: Example 3- Vigenere “Multi-Caesar Cipher” – A statefull cipher Key: k = (k1,k2,…,km) list of m numbers between 0 and 25 Encryption: 1st letter encoded as Caesar w/ key=k1 : i I + k1 (mod 26) 2nd letter encoded as Caesar w/ key=k2 : i I + k2 (mod 26) mth letter encoded as Caesar w/ key=km : i I + km (mod 26) m+1th letter encoded as Caesar w/ key=k1 : i I + k1 (mod 26) Decryption: In the natural way … Important Property: Can no longer break using letter frequencies alone. ‘e’ will be mapped to ‘e’+k1,‘e’+k2,…,‘e’+km according to location. nth letter encoded w/ key=k(n mod m) : i I + k(n mod m) (mod 26) Considered “unbreakable” for 300 years (broken by Babbage, Kasiski 1850’s) (Belaso, 1553)Example 3- Vigenere: Example 3- Vigenere “Multi-Caesar Cipher” – A statefull cipher Key: k = (k1,k2,…,km) list of m numbers between 0 and 25 Encryption: Breaking Vigenere: nth letter encoded w/ key=k(n mod m) : i I + k(n mod m) (mod 26) (Belaso, 1553) LIVITC SWPIYV EWHEVS RIQMXL EYVEOI EWHRXE XIPFEM VEWHKV Step 1: Guess the length of the key m Step 2: Group together positions {1, m+1, 2m+1, 3m+1,…} {m-1, 2m+m-1, 3m+m-1,…} Decryption: In the natural way … {2, m+2, 2m+2, 3m+2,…}Example 3- Vigenere: Example 3- Vigenere “Multi-Caesar Cipher” – A statefull cipher Key: k = (k1,k2,…,km) list of m numbers between 0 and 25 Encryption: Breaking Vigenere: nth letter encoded w/ key=k(n mod m) : i i + k(n mod m) (mod 26) (Belaso, 1553) LIVITC SWPIYV EWHEVS RIQMXL EYVEOI EWHRXE XIPFEM VEWHKV Step 1: Guess the length of the key m Step 2: Group together positions 1, m+1, 2m+1, 3m+1,… Step 3: Frequency-analyze each group independently. Decryption: In the natural way {m-1, 2m+m-1, 3m+m-1,…} … {2, m+2, 2m+2, 3m+2,…}Example 4 - The Enigma: Example 4 - The Enigma A mechanical statefull cipher. Roughly: composition of 3-5 substitution ciphers implemented by wiring. Wiring on rotors moving in different schedules, making cipher statefull Key: 1) Wiring of machine (changed infrequently) 2) Daily key from code books 3) New operator-chosen key for each message Tools used by Poles & British to break Enigma: 1) Mathematical analysis combined w/ mechanical computers 2) Captured machines and code-books 3) German operators negligence 4) Known plaintext attacks (greetings, weather reports) 5) Chosen plaintext attacks Used by Germany in WWII for top-secret communication.Post 1970’s Crypto: Post 1970’s Crypto Two major developments: 1) Provably secure cryptography Encryptions w/ mathematical proof that are unbreakable* * Currently use conjectures/axioms, however defeated all cryptanalysis effort so far. 2) Cryptography beyond “secret writing” Public-key encryptions Digital signatures Zero-knowledge proofs Anonymous electronic elections Privacy-preserving data mining e-cash …Review of Encryption Schemes: Review of Encryption Schemes Alice wants to send Bob a secret message. Encryption algorithm: E Decryption algorithm: D Secret key: k To encrypt m, Alice sends c = E(m,k) to Bob. To decrypt c, Bob computes m’ = D(c,k). c = E(m,k) m’ = D(c,k) Q: Can Bob send Alice the secret key over the net? A: Of course not!! Eve could decrypt c! Q: What if Bob could send Alice a “crippled key” useful only for encryption but no help for decryptionPublic Key Cryptography [DH76,RSA77]: Public Key Cryptography [DH76,RSA77] Alice wants to send Bob a secret message. Encryption algorithm: E Decryption algorithm: D To encrypt m, Alice sends c = E(m,e) to Bob. To decrypt c, Bob computes m’ = D(c,d). c = E(m,e) m’ = D(c,d) Key: Bob chooses two keys: Secret key d for decrypting messages. Public key e for encrypting messages. choose d,eOther Crypto Wonders: Other Crypto Wonders Digital Signatures. Electronically sign documents in unforgeable way. Zero-knowledge proofs. Alice proves to Bob that she earns <$50K without Bob learning her income. Privacy-preserving data mining. Bob holds DB. Alice gets answer to one query, without Bob knowing what she asked. Playing poker over the net. Alice, Bob, Carol and David can play poker over the net without trusting each other or any central server. Distributed systems. Distribute sensitive data to 7 servers s.t. as long as <3 are broken, no harm to security occurs. Electronic auctions. Can run auctions s.t. no one (even not seller) learns anything other than winning party and bid.Cryptography & Security: Cryptography & Security Prev slides: Have provably secure algorithm for every crypto task imaginable. Q: How come nothing is secure? A1: Not all of these are used or used correctly: Strange tendency to use “home-brewed” cryptosystems. Combining secure primitives in insecure way Strict efficiency requirements for crypto/security: Many provably secure algs not efficient enough The cost is visible but benefit invisible. Easy to get implementation wrong – many subtleties Compatibility issues, legacy systems, Misunderstanding properties of crypto components.Cryptography & Security: Cryptography & Security Prev slides: Have provably secure algorithm for every crypto task imaginable. Q: How come nothing is secure? A2: Cryptography is only part of designing secure systems Chain is only as strong as weakest link. A “dormant bug” is often a security hole. Security is hard to “modularize” Human element (hard to add to existing system, changes in system features can have unexpected consequences) Many subtle issues (e.g., caching & virtual memory, side channel attacks) Key storage and protection issues.