ee1e8abd87
* feat(tools): add seed/solution restore script * chore(curriculum): remove empty sections' markers * chore(curriculum): add seed + solution to Chinese * chore: remove old formatter * fix: update getChallenges parse translated challenges separately, without reference to the source * chore(curriculum): add dashedName to English * chore(curriculum): add dashedName to Chinese * refactor: remove unused challenge property 'name' * fix: relax dashedName requirement * fix: stray tag Remove stray `pre` tag from challenge file. Signed-off-by: nhcarrigan <nhcarrigan@gmail.com> Co-authored-by: nhcarrigan <nhcarrigan@gmail.com>
5.1 KiB
5.1 KiB
id, title, challengeType, forumTopicId, dashedName
| id | title | challengeType | forumTopicId | dashedName |
|---|---|---|---|---|
| 594fa2746886f41f7d8bf225 | Topological sort | 5 | 302340 | topological-sort |
--description--
Given a mapping between items, and items they depend on, a topological sort orders items so that no item precedes an item it depends upon. The compiling of a library in the VHDL language has the constraint that a library must be compiled after any library it depends on.
--instructions--
Write a function that will return a valid compile order of VHDL libraries from their dependencies.
- Assume library names are single words.
- Items mentioned as only dependents have no dependents of their own, but their order of compiling must be given.
- Any self dependencies should be ignored.
- Any un-orderable dependencies should be ignored.
LIBRARY LIBRARY DEPENDENCIES ======= ==================== des_system_lib std synopsys std_cell_lib des_system_lib dw02 dw01 ramlib ieee dw01 ieee dw01 dware gtech dw02 ieee dw02 dware dw03 std synopsys dware dw03 dw02 dw01 ieee gtech dw04 dw04 ieee dw01 dware gtech dw05 dw05 ieee dware dw06 dw06 ieee dware dw07 ieee dware dware ieee dware gtech ieee gtech ramlib std ieee std_cell_lib ieee std_cell_lib synopsysNote: the above data would be un-orderable if, for example,
dw04 is added to the list of dependencies of dw01.
C.f.:
There are two popular algorithms for topological sorting:
--hints--
topologicalSort should be a function.
assert(typeof topologicalSort === 'function');
topologicalSort should return correct library order.
assert.deepEqual(topologicalSort(libsSimple), ['bbb', 'aaa']);
topologicalSort should return correct library order.
assert.deepEqual(topologicalSort(libsVHDL), solutionVHDL);
topologicalSort should return correct library order.
assert.deepEqual(topologicalSort(libsCustom), solutionCustom);
topologicalSort should ignore unorderable dependencies.
assert.deepEqual(topologicalSort(libsUnorderable), solutionUnorderable);
--seed--
--after-user-code--
const libsSimple =
`aaa bbb
bbb`;
const libsVHDL =
`des_system_lib std synopsys std_cell_lib des_system_lib dw02 dw01 ramlib ieee
dw01 ieee dw01 dware gtech
dw02 ieee dw02 dware
dw03 std synopsys dware dw03 dw02 dw01 ieee gtech
dw04 dw04 ieee dw01 dware gtech
dw05 dw05 ieee dware
dw06 dw06 ieee dware
dw07 ieee dware
dware ieee dware
gtech ieee gtech
ramlib std ieee
std_cell_lib ieee std_cell_lib
synopsys`;
const solutionVHDL = [
'ieee', 'std_cell_lib', 'gtech', 'dware', 'dw07', 'dw06',
'dw05', 'dw02', 'dw01', 'dw04', 'std', 'ramlib', 'synopsys',
'dw03', 'des_system_lib'
];
const libsCustom =
`a b c d
b c d
d c
c base
base`;
const solutionCustom = ['base', 'c', 'd', 'b', 'a'];
const libsUnorderable =
`TestLib Base MainLib
MainLib TestLib
Base`;
const solutionUnorderable = ['Base'];
--seed-contents--
function topologicalSort(libs) {
return true;
}
--solutions--
function topologicalSort(libs) {
// A map of the input data, with the keys as the packages, and the values as
// and array of packages on which it depends.
const D = libs
.split('\n')
.map(e => e.split(' ').filter(ep => ep !== ''))
.reduce((p, c) =>
p.set(c[0], c.filter((e, i) => (i > 0 && e !== c[0] ? e : null))), new Map());
[].concat(...D.values()).forEach(e => {
D.set(e, D.get(e) || []);
});
// The above map rotated so that it represents a DAG of the form
// Map {
// A => [ A, B, C],
// B => [C],
// C => []
// }
// where each key represents a node, and the array contains the edges.
const G = [...D.keys()].reduce((p, c) =>
p.set(
c,
[...D.keys()].filter(e => D.get(e).includes(c))),
new Map()
);
// An array of leaf nodes; nodes with 0 in degrees.
const Q = [...D.keys()].filter(e => D.get(e).length === 0);
// The result array.
const S = [];
while (Q.length) {
const u = Q.pop();
S.push(u);
G.get(u).forEach(v => {
D.set(v, D.get(v).filter(e => e !== u));
if (D.get(v).length === 0) {
Q.push(v);
}
});
}
return S;
}