More integer encoding notes.
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@ -118,7 +118,7 @@
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"_journal/2024-02-02.md": "a3b222daee8a50bce4cbac699efc7180",
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"_journal/2024-02-01.md": "3aa232387d2dc662384976fd116888eb",
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"_journal/2024-01-31.md": "7c7fbfccabc316f9e676826bf8dfe970",
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"logic/equiv-trans.md": "4d825c23bf54e8b1e645584d52b2b993",
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"logic/equiv-trans.md": "08ad9c814f0a46981b218a9c7cc8a3b8",
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"_journal/2024-02-07.md": "8d81cd56a3b33883a7706d32e77b5889",
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"algorithms/loop-invariants.md": "cbefc346842c21a6cce5c5edce451eb2",
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"algorithms/loop-invariant.md": "d883dfc997ee28a7a1e24b995377792b",
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@ -132,7 +132,7 @@
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"_journal/2024-02-09.md": "a798d35f0b2bd1da130f7ac766166109",
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"c/types.md": "cf3e66e5aee58a94db3fdf0783908555",
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"logic/quantification.md": "5d7579a511e9ff683edeec62bcc291b8",
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"c/declarations.md": "7b0277d89b83fb330970deeb37e664c4",
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"c/declarations.md": "94c85cb1a09efed2cad6b5b80e9d0be3",
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"algorithms/sorting/bubble-sort.md": "16dad1016dc6555163e42ba20f1d152d",
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"_journal/2024-02-10.md": "562b01f60ea36a3c78181e39b1c02b9f",
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"_journal/2024-01/2024-01-31.md": "7c7fbfccabc316f9e676826bf8dfe970",
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@ -159,7 +159,7 @@
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"logic/boolean-algebra.md": "f9101b2dfdedb73dc13c34c1a70a0010",
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"_journal/2024-02-13.md": "6242ed4fecabf95df6b45d892fee8eb0",
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"_journal/2024-02/2024-02-12.md": "618c0035a69b48227119379236a02f44",
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"binary/shifts.md": "c7fb2a5722a69bb23047b603edcd0b91",
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"binary/shifts.md": "ce6f2d80536b8a8b3f05383ce2190e72",
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"_journal/2024-02-14.md": "76d1b607470305fb3f00a47b8e9ece27",
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"_journal/2024-02/2024-02-13.md": "6242ed4fecabf95df6b45d892fee8eb0",
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"_journal/2024-02-15.md": "575ba46d692795d9606de9e635d1f4ac",
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@ -171,7 +171,7 @@
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"algorithms/binary-search.md": "08cb6dc2dfb204a665d8e8333def20ca",
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"_journal/2024-02-17.md": "7c37cb10515ed3d2f5388eaf02a67048",
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"_journal/2024-02/2024-02-16.md": "e701902e369ec53098fc2deed4ec14fd",
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"binary/integer-encoding.md": "193566bf1b9e88257002d32bb2bc0bf2",
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"binary/integer-encoding.md": "afe5e82b534fc5ab409b188addab36f4",
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"combinatorics/index.md": "f9de9671fdb6068ef2bb5e63051734be",
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"_journal/2024-02-18.md": "67e36dbbb2cac699d4533b5a2eaeb629",
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"_journal/2024-02/2024-02-17.md": "7c37cb10515ed3d2f5388eaf02a67048",
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@ -186,7 +186,9 @@
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"combinatorics/inclusion-exclusion.md": "4d5ba716bc90cd378c7c4c816b224c75",
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"_journal/2024-02-21.md": "b9d944ecebe625da5dd72aeea6a916a2",
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"_journal/2024-02/2024-02-20.md": "af2ef10727726200c4defe2eafc7d841",
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"algebra/radices.md": "1171835a864103fbc4cbe21d56fcfa1f"
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"algebra/radices.md": "0fcd901c798eaed8075ff1375e2429dd",
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"_journal/2024-02-22.md": "e01f1d4bd2f7ac2a667cdfd500885a2a",
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"_journal/2024-02/2024-02-21.md": "a627f267700f36abd5ceb9b4c294479e"
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},
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"fields_dict": {
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"Basic": [
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@ -1,15 +0,0 @@
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---
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title: "2024-02-21"
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---
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- [x] Anki Flashcards
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- [x] KoL
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- [ ] Sheet Music (10 min.)
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- [ ] OGS (1 Life & Death Problem)
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- [ ] Korean (Read 1 Story)
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- [ ] Interview Prep (1 Practice Problem)
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- [ ] Log Work Hours (Max 3 hours)
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* Read through "Stars and Bars" section in "Discrete Mathematics: An Open Introduction".
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* Added notes on radices.
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* Spent time thinking about how two's-complement works.
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@ -0,0 +1,19 @@
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---
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title: "2024-02-22"
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---
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- [x] Anki Flashcards
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- [x] KoL
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- [ ] Sheet Music (10 min.)
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- [ ] OGS (1 Life & Death Problem)
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- [ ] Korean (Read 1 Story)
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- [x] Interview Prep (1 Practice Problem)
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- [x] Log Work Hours (Max 3 hours)
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* Briefly discussed first chapter of "Designing Data-Intensive Applications" with Mike.
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* Continued reading more on integer encodings.
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* Focused on conversions between unsigned encoding and two's-complement, though still need to create flashcards for these.
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* Did Leetcode problems
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* [3Sum Closest](https://leetcode.com/problems/3sum-closest/description/)
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* [Letter Combinations of a Phone Number](https://leetcode.com/problems/letter-combinations-of-a-phone-number/description/)
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* [Remove Nth Node From End of List](https://leetcode.com/problems/remove-nth-node-from-end-of-list/description/)
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@ -0,0 +1,20 @@
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---
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title: "2024-02-21"
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---
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- [x] Anki Flashcards
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- [x] KoL
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- [ ] Sheet Music (10 min.)
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- [ ] OGS (1 Life & Death Problem)
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- [ ] Korean (Read 1 Story)
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- [x] Interview Prep (1 Practice Problem)
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- [ ] Log Work Hours (Max 3 hours)
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* Read through "Stars and Bars" section in "Discrete Mathematics: An Open Introduction".
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* Added notes on radices.
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* Spent time thinking about how two's-complement works.
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* Read the first chapter on "Designing Data-Intensive Applications".
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* Leetcode Problems
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* [Integer to Roman](https://leetcode.com/problems/integer-to-roman/description/)
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* [Roman to Integer](https://leetcode.com/problems/roman-to-integer/description/)
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* [Container With Most Water](https://leetcode.com/problems/container-with-most-water/description/)
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@ -267,6 +267,24 @@ Tags: binary::hex
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<!--ID: 1707432641596-->
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END%%
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%%ANKI
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Basic
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Which hexadecimal digits have a leading `1` bit?
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Back: `8` through `F`
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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Tags: binary::hex
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<!--ID: 1708631918825-->
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END%%
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%%ANKI
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Basic
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Which hexadecimal digits have a leading `0` bit?
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Back: `0` through `7`
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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Tags: binary::hex
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<!--ID: 1708631918829-->
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END%%
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## References
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* Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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@ -54,7 +54,7 @@ END%%
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%%ANKI
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Basic
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An integral value of 0 has what encoding?
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An integral value of $0_{10}$ likely has what encoding?
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Back: Either unsigned or two's-complement.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708177246105-->
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@ -62,7 +62,7 @@ END%%
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%%ANKI
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Basic
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An integral value of 100 has what encoding?
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An integral value of $100_{10}$ likely has what encoding?
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Back: Either unsigned or two's-complement.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708177246109-->
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@ -70,7 +70,7 @@ END%%
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%%ANKI
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Basic
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An integral value of -100 has what encoding?
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An integral value of $-100_{10}$ likely has what encoding?
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Back: Two's-complement.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708177246114-->
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@ -87,7 +87,7 @@ END%%
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%%ANKI
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Basic
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What integral values share the same binary representation in unsigned encoding and two's-complement?
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Back: Nonnegative values $\leq |TMax|$.
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Back: Nonnegative values $\leq TMax$.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708454709515-->
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END%%
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@ -108,9 +108,83 @@ Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Program
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<!--ID: 1708455064696-->
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END%%
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%%ANKI
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Basic
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According to the C standard, Is `unsigned` underflow/overflow safe?
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Back: Yes
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708551236389-->
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END%%
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%%ANKI
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Basic
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According to the C standard, Is `signed` underflow/overflow safe?
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Back: No
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708551236392-->
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END%%
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%%ANKI
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Basic
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Why is `signed` underflow/overflow considered UB?
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Back: Because there is no requirement on how `signed` integers are encoded.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708551236395-->
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END%%
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%%ANKI
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Basic
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How does $UMax$ relate to $TMax$?
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Back: $UMax = 2 \cdot TMax + 1$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708453398445-->
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END%%
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%%ANKI
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Basic
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*Why* is it $UMax = 2 \cdot TMax + 1$?
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Back: All bit patterns denoting negative numbers in two's-complement are positive in unsigned encoding.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708613447880-->
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END%%
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%%ANKI
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Basic
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What are the binary encodings of $UMax_4$ and $TMax_4$?
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Back: $1111_2$ and $0111_2$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708453398449-->
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END%%
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%%ANKI
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Basic
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Reinterpret $TMax$ in unsigned encoding. What arithmetic operations yield $UMax$?
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Back: Multiply by two and add one.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708453398454-->
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END%%
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%%ANKI
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Basic
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Reinterpret $TMax$ in unsigned encoding. What bitwise operations yield $UMax$?
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Back: One-bit left shift and add one.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708453398459-->
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END%%
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%%ANKI
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Basic
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Reinterpret $UMax$ in two's-complement. What decimal value do you have?
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Back: $-1$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708453398469-->
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END%%
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### Unsigned Encoding
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Always represents nonnegative numbers. Given an integral type $\vec{x}$ of $w$ bits, we convert binary to its unsigned encoding with: $$B2U_w(\vec{x}) = \sum_{i=0}^{w-1} 2^ix_i$$
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Always represents nonnegative numbers. Given an integral type $\vec{x}$ of $w$ bits, we convert binary to its unsigned encoding with: $$B2U_w(\vec{x}) = 2^{w-1}x_{w-1} + \sum_{i=0}^{w-2} 2^ix_i$$
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Note we unfold the summation on the RHS by one term to make it's relationship to $T2U_w$ clearer.
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%%ANKI
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Basic
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@ -171,7 +245,7 @@ END%%
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%%ANKI
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Basic
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How does Bryant et al. define $B2U_w$?
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Back: $B2U_w(\vec{x}) = \sum_{i=0}^{w-1} 2^ix_i$
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Back: $B2U_w(\vec{x}) = 2^{w-1}x_{w-1} + \sum_{i=0}^{w-2} 2^ix_i$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708179147785-->
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END%%
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@ -179,11 +253,19 @@ END%%
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%%ANKI
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Basic
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What is $B2U_w$ an acronym for?
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Back: **B**inary "to" **u**nsigned.
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Back: **B**inary to **u**nsigned, width $w$.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708179147791-->
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END%%
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%%ANKI
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Basic
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What is $U2B_w$ an acronym for?
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Back: **U**nsigned to **b**inary, width $w$.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708613447885-->
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END%%
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%%ANKI
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Basic
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What does $w$ in $B2U_w$ represent?
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@ -195,11 +277,19 @@ END%%
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%%ANKI
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Basic
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What is the domain of $B2U_w$?
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Back: Bit vectors of size $w$.
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Back: Bit strings of size $w$.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708179147798-->
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END%%
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%%ANKI
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Basic
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What is the domain of $U2B_w$?
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Back: $[0, 2^w)$
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708613447888-->
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END%%
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%%ANKI
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Basic
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What is the range of $B2U_w$?
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@ -210,10 +300,10 @@ END%%
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%%ANKI
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Basic
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What is the hexadecimal representation of $UMin_4$?
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Back: `0x0000`
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What is the range of $U2B_w$?
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Back: Bit strings of length $w$.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708453398386-->
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<!--ID: 1708613447891-->
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END%%
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%%ANKI
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@ -224,14 +314,6 @@ Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Program
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<!--ID: 1708453398392-->
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END%%
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%%ANKI
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Basic
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What is the hexadecimal representation of $UMax_4$?
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Back: `0xFFFF`
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708453398397-->
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END%%
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%%ANKI
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Basic
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How is the largest unsigned integer formatted in hexadecimal?
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%%ANKI
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Basic
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With unsigned encoding, *why* does `n + ~n = UMax`?
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Using unsigned encoding, *why* does `n + ~n = UMax`?
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Back: Because this always yields a bit string of all `1`s.
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Reference: “Two’s-Complement.” In *Wikipedia*, January 9, 2024. [https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561](https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561).
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<!--ID: 1708545574154-->
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<!--ID: 1708545383255-->
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END%%
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%%ANKI
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Basic
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How do $TMin$ and $TMax$ relate to one another?
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Back: $TMin = -TMax - 1$
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<!--ID: 1708609869518-->
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END%%
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%%ANKI
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Basic
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What half-open interval represents the possible $w$-bit two's-complement decimal values?
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Basic
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What is the weight of the sign bit in $w$-bit two's-complement?
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Back: $-2^{w-1}$
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The {sign bit} refers to the {most significant bit} in two's-complement.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
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<!--ID: 1708179649887-->
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END%%
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@ -350,11 +438,19 @@ END%%
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%%ANKI
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Basic
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What is $B2T_w$ an acronym for?
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Back: **B**inary "to" **t**wo's-complement.
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Back: **B**inary to **t**wo's-complement, width $w$.
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Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708179649907-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What is $T2B_w$ an acronym for?
|
||||
Back: **T**wo's-complement to **b**inary, width $w$.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708613447895-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What does $w$ in $B2T_w$ represent?
|
||||
|
@ -366,11 +462,19 @@ END%%
|
|||
%%ANKI
|
||||
Basic
|
||||
What is the domain of $B2T_w$?
|
||||
Back: Bit vectors of size $w$.
|
||||
Back: Bit strings of size $w$.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708179649921-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What is the domain of $T2B_w$?
|
||||
Back: $[-2^{w-1}, 2^{w-1})$
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708613447899-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What is the range of $B2T_w$?
|
||||
|
@ -381,10 +485,10 @@ END%%
|
|||
|
||||
%%ANKI
|
||||
Basic
|
||||
What is the hexadecimal representation of $TMin_4$?
|
||||
Back: `0x8000`
|
||||
What is the range of $T2B_w$?
|
||||
Back: Bit strings of length $w$.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708453398408-->
|
||||
<!--ID: 1708613447903-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
|
@ -395,14 +499,6 @@ Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Program
|
|||
<!--ID: 1708453398413-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What is the hexadecimal representation of $TMax_4$?
|
||||
Back: `0x7FFF`
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708453398418-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
How is the largest two's-complement integer formatted in hexadecimal?
|
||||
|
@ -429,54 +525,12 @@ END%%
|
|||
|
||||
%%ANKI
|
||||
Basic
|
||||
Why is two's-complement encoding's range asymmetric?
|
||||
Back: Leading `1`s correspond to negatives but leading `0`s corerspond to nonnegative numbers (which include $0$.)
|
||||
Why is two's-complement's encoding range asymmetric?
|
||||
Back: Leading `1`s correspond to negatives but leading `0`s corerspond to nonnegative numbers (which include $0$).
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708453398440-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
How does $UMax$ relate to $TMax$?
|
||||
Back: $|UMax| = 2|TMax| + 1$
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708453398445-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What are the binary encodings of $UMax_4$ and $TMax_4$?
|
||||
Back: $1111_2$ and $0111_2$
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708453398449-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
Reinterpret $TMax$ in unsigned encoding. What arithmetic operations yield $UMax$?
|
||||
Back: Multiply by two and add one.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708453398454-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
Reinterpret $TMax$ in unsigned encoding. What bitwise operations yield $UMax$?
|
||||
Back: One-bit left shift and add one.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708453398459-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
Reinterpret $UMax$ in two's-complement. What decimal value do you have?
|
||||
Back: $-1$
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708453398469-->
|
||||
END%%
|
||||
|
||||
The "two's-complement" of an integer often refers to the binary representation of the integer's additive inverse. For example, $0110_2 = 6$ has two's-complement $1010_2 = -6$. In contrast, the "complement" of a nonnegative integer is the other nonnegative integer such that together add up to $2^{w-1}$. For example, $0110_2 = 6$ has complement $0010_2 = 2$ (with respect to $2^3 = 8$).
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What are the median values of two's-complement's encoding range?
|
||||
|
@ -492,90 +546,122 @@ Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Program
|
|||
<!--ID: 1708545383265-->
|
||||
END%%
|
||||
|
||||
## Casting
|
||||
|
||||
Most implementations of C cast an object of one type to another by simply re-interpreting their binary representation. This casting may happen implicitly if comparing or operating on e.g. `signed` and `unsigned` objects in the same expression. $T2U$ and $U2T$ reflect this method of casting:
|
||||
|
||||
$$T2U_w(x) = \begin{cases}
|
||||
x + 2^w & x < 0 \\
|
||||
x & x \geq 0
|
||||
\end{cases}$$
|
||||
|
||||
$$U2T_w(x) = \begin{cases}
|
||||
x & x \leq TMax_w \\
|
||||
x - 2^w & x > TMax_w
|
||||
\end{cases}$$
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
How does `n` relate to `~n` in two's-complement?
|
||||
Back: `~n = -n - 1`
|
||||
Reference: “Two’s-Complement.” In *Wikipedia*, January 9, 2024. [https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561](https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561).
|
||||
<!--ID: 1708545383267-->
|
||||
How do most implementations of C perform casting?
|
||||
Back: As a reinterpretation of the same byte pattern of the object being casted.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
Tags: c
|
||||
<!--ID: 1708615249879-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What value does not have a two's-complement?
|
||||
Back: $TMin$
|
||||
Reference: “Two’s-Complement.” In *Wikipedia*, January 9, 2024. [https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561](https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561).
|
||||
<!--ID: 1708545383268-->
|
||||
What is $T2U_w$ an acronym for?
|
||||
Back: **T**wo's-complement to **u**nsigned, width $w$.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708615249883-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
*Why* doesn't $TMin$ have a two's-complement?
|
||||
Back: Because there is one less representable positive number than negative number.
|
||||
Reference: “Two’s-Complement.” In *Wikipedia*, January 9, 2024. [https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561](https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561).
|
||||
<!--ID: 1708545383270-->
|
||||
For what decimal values $x$ does $T2U_w$ and $U2T_w$ serve as the identity function?
|
||||
Back: $0 \leq x \leq TMax_w$
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708615249887-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What values $x$ are unaffected when casting from `signed` to `unsigned`?
|
||||
Back: $0 \leq x \leq TMax_w$
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
Tags: c
|
||||
<!--ID: 1708615249891-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What values $x$ are unaffected when casting from `unsigned` to `signed`?
|
||||
Back: $0 \leq x \leq TMax_w$
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
Tags: c
|
||||
<!--ID: 1708615249897-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
How are casts implicitly performed in operations containing `signed` and `unsigned` objects?
|
||||
Back: `signed` objects are cast to `unsigned` objects.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
Tags: c
|
||||
<!--ID: 1708615249903-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Cloze
|
||||
$TMin$ is called the "{weird number}" because {it is it's own two's-complement}.
|
||||
Reference: “Two’s-Complement.” In *Wikipedia*, January 9, 2024. [https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561](https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561).
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What is the result of applying the two's-complement operation on $TMin$?
|
||||
Back: $TMin$
|
||||
Reference: “Two’s-Complement.” In *Wikipedia*, January 9, 2024. [https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561](https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561).
|
||||
<!--ID: 1708545383271-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What does the two's-complement of $n$ refer to?
|
||||
Back: The binary representation of $-n$.
|
||||
Reference: “Two’s-Complement.” In *Wikipedia*, January 9, 2024. [https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561](https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561).
|
||||
<!--ID: 1708545383273-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
Using two's-complement, what is the *complement* of $0101_2$?
|
||||
Back: $0011_2$
|
||||
Reference: “Two’s-Complement.” In *Wikipedia*, January 9, 2024. [https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561](https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561).
|
||||
<!--ID: 1708545383274-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
Using two's-complement, the *complement* of $0101_2$ is found with respect to what value?
|
||||
Back: $2^3 = 8$
|
||||
Reference: “Two’s-Complement.” In *Wikipedia*, January 9, 2024. [https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561](https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561).
|
||||
<!--ID: 1708545383276-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What bitwise operations yield the two's-complement of $n$?
|
||||
Back: `~n + 1`
|
||||
Reference: “Two’s-Complement.” In *Wikipedia*, January 9, 2024. [https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561](https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561).
|
||||
<!--ID: 1708545383277-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
Why is two's-complement named the way it is?
|
||||
Back: For $x \geq 0$, $-x$'s $w$-bit representation is found using $2^w - x$.
|
||||
For {$x < 0$}, $T2U_w(x) =$ {$x + 2^w$}.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708545383279-->
|
||||
<!--ID: 1708615249908-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Cloze
|
||||
For {$x \geq 0$}, $T2U_w(x) =$ {$x$}.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708615249914-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What identity show $3$ and $5$ are complements with respect to $2^3$?
|
||||
Back: $3 + 5 = 8$
|
||||
Reference: “Two’s-Complement.” In *Wikipedia*, January 9, 2024. [https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561](https://en.wikipedia.org/w/index.php?title=Two%27s_complement&oldid=1194543561).
|
||||
<!--ID: 1708545383280-->
|
||||
How is $T2U_w$ written as a function composition?
|
||||
Back: $T2U_w = B2U_w \circ T2B_w$
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708615249920-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What is $U2T_w$ an acronym for?
|
||||
Back: **U**nsigned to **t**wo's-complement, width $w$.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708615249925-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
How is $U2T_w$ written as a function composition?
|
||||
Back: $U2T_w = B2T_w \circ U2B_w$
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708615249930-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Cloze
|
||||
For {$x > TMax_w$}, $U2T_w(x) =$ {$x - 2^w$}.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708615249935-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Cloze
|
||||
For {$x \leq TMax_w$}, $U2T_w(x) =$ {$x$}.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708615249939-->
|
||||
END%%
|
||||
|
||||
## References
|
||||
|
|
|
@ -45,7 +45,7 @@ END%%
|
|||
%%ANKI
|
||||
Basic
|
||||
What is a logical right shift operation?
|
||||
Back: One that fills the left end of the result with `k` zeros.
|
||||
Back: One that fills the left end of the result with zeros.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1707854589786-->
|
||||
END%%
|
||||
|
@ -53,7 +53,7 @@ END%%
|
|||
%%ANKI
|
||||
Basic
|
||||
What is an arithmetic right shift operation?
|
||||
Back: One that fills the left end of the result with `k` copies of the most significant bit.
|
||||
Back: One that fills the left end of the result with copies of the most significant bit.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1707854589789-->
|
||||
END%%
|
||||
|
|
|
@ -28,6 +28,14 @@ Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Program
|
|||
<!--ID: 1707835869728-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
Which header file contains `INT32_MAX`?
|
||||
Back: `<stdint.h>`
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708615249870-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What does the "width" of an integer type refer to?
|
||||
|
@ -195,6 +203,147 @@ Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Program
|
|||
<!--ID: 1707493017244-->
|
||||
END%%
|
||||
|
||||
## Integer Literals
|
||||
|
||||
Negative integer literals are typed in a counterintuitive way. When the compiler sees a number of form `-X`, the type of `X` is first determined *before* then being negated. Promotion rules are as follows:
|
||||
|
||||
C90 (Decimal) | C90 (Other) | C99 (Decimal) | C99 (Other)
|
||||
--------------- | --------------- | ------------- | ---------
|
||||
`int` | `int` | `int` | `int`
|
||||
`long` | `unsigned` | `long` | `unsigned`
|
||||
`unsigned` | `long` | `long long` | `long`
|
||||
`unsigned long` | `unsigned long` | `-` | `unsigned long`
|
||||
`-` | `-` | `-` | `long long`
|
||||
`-` | `-` | `-` | `unsigned long long`
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
How does the compiler process integer literal `-X`?
|
||||
Back: By first determining the type of `X` and then negating the value.
|
||||
Reference: Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820805-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What simplification did C99 introduce to decimal integer literals?
|
||||
Back: The integer constant is guaranteed a `signed` type.
|
||||
Reference: Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820816-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
Since what standard was it guaranteed decimal integer literals were `signed`?
|
||||
Back: C99
|
||||
Reference: Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820820-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
In ISO C90, what integer literals are guaranteed `signed`?
|
||||
Back: None.
|
||||
Reference: Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820823-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
In ISO C99, what integer literals are guaranteed `signed`?
|
||||
Back: Decimal integer constants.
|
||||
Reference: Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820826-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
Why avoid negative octal integer literals?
|
||||
Back: Depending on value, the resulting type may be `unsigned`.
|
||||
Reference: Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820829-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
Why avoid negative hexadecimal integer literals?
|
||||
Back: Depending on value, the resulting type may be `unsigned`.
|
||||
Reference: Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820833-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
Which header file contains `INT_MAX`?
|
||||
Back: `<limits.h>`
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708615249864-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Cloze
|
||||
{`INT_MAX`} is to `signed` whereas {`UINT_MAX`} is to `unsigned`.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820837-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
How does `<limits.h>` define `INT_MIN`?
|
||||
Back: As `(-INT_MAX - 1)`.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820840-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
*Why* is `INT_MIN` defined as `(-INT_MAX - 1)` instead of directly as e.g. `-2147483648`?
|
||||
Back: Because `2147483648` (without `-`) would be sized as a non-`int` before being negated.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820843-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Cloze
|
||||
`INT_MAX` is to {`<limits.h>`} whereas `INT32_MAX` is to {`<stdint.h>`}.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708615249873-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What suffix can be used to denote an `unsigned` integer literal?
|
||||
Back: Case-insensitive `U`.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708615249876-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What suffix can be used to denote a `long` integer literal?
|
||||
Back: Case-insensitive `L`.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820847-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What suffix can be used to denote a `long long` integer literal?
|
||||
Back: Case-insensitive `LL`.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820850-->
|
||||
END%%
|
||||
|
||||
%%ANKI
|
||||
Basic
|
||||
What suffix can be used to denote an `unsigned long long` integer literal?
|
||||
Back: Case-insensitive `ULL`.
|
||||
Reference: Bryant, Randal E., and David O'Hallaron. *Computer Systems: A Programmer's Perspective*. Third edition, Global edition. Always Learning. Pearson, 2016.
|
||||
<!--ID: 1708631820856-->
|
||||
END%%
|
||||
|
||||
## Pointers
|
||||
|
||||
Pointers have the same size as the machine's word size since it should be able to refer to any virtual address.
|
||||
|
||||
%%ANKI
|
||||
|
|
|
@ -788,7 +788,7 @@ END%%
|
|||
%%ANKI
|
||||
Basic
|
||||
How is $(s; x{:}v)$ written instead using set-theoretical notation?
|
||||
Back: $(s - \{(x, s(x))\}) \cup \{(x, v)\}$
|
||||
Back: $(s - \{\langle x, s(x) \rangle\}) \cup \{\langle x, v \rangle\}$
|
||||
Reference: Gries, David. *The Science of Programming*. Texts and Monographs in Computer Science. New York: Springer-Verlag, 1981.
|
||||
<!--ID: 1707937867053-->
|
||||
END%%
|
||||
|
|
Loading…
Reference in New Issue