## Hot answers tagged linear-search

10

Since the algorithm is finding the highest value in a collection, it is called a linear selection algorithm, not a linear search algorithm. This is different from a search algorithm, which looks for a specific value.

9

For small arrays, the problem is not cache. You are right: A small array is likely to be cached quickly.
The problem is that branch prediction is likely to fail for binary search because branches are taken or skipped at random in a data-dependent way. Branch prediction misses stall the CPU pipeline.
This effect can be severe. You can easily search 3 to 8 ...

7

In this case it says/indicates that linear[i] is smaller than your key.
In some occasions it might also indicate that a key is not found.
This is a widely used convention (I mean returning -1 in such cases).

7

It depends.
If you are searching for only one string the linear search is better because it is in O(n)
If you are searching for multiple strings first sorting and then binary searching maybe better. it will be O(logn + n*logn) which is O(n*logn). So if you are checking for ca. n strings, this one is better.
If you only want to know if your Collection ...

6

I believe this function is meant to take a sorted array and returns the index of a given key if it is found in the array and return -1 if there is no matching element in the array.
EDIT: to avoid confusion - in the example you show linear is not sorted. This means that it will not do what I describe above. If linear is not sorted, then the function will do ...

6

Your comparison code is buggy, and this is distorting your results.
This does search for the target
if (ints.contains(target)) {
// nothing
}
But this does not!
for (Integer i : ints) {
// nothing
}
You are actually just iterating over the list elements without testing them.
Having said that, the second version is ...

5

You should look at the generated instructions to see (gcc -S source.c), but generally it comes down to these three:
1) N is too small.
If you only have a 8 different branches, you execute an average of 4 checks (assuming equally probable cases, otherwise it could be even faster).
If you make it a binary search, that is log(8) == 3 checks, but these checks ...

5

The precise type must be known at compile time (and is subsequently erased). You cannot decide arbitrarily which types to return at runtime.
However, you can do you've tried to do, by wrapping the types into a generic enum (which replaces the || in your code):
enum TypeOr<S, T> {
Left(S),
Right(T),
}
fn linear_search(vector: ...) -> ...

4

you can avoid for loop and check condition by just giving number like this: txtLinearOutput.setText(listOfBooks[number-1]);
remove your code
// Linear search to match index number and user input number
for(int i = 0; i < listOfBooks.length - 1; i++) {
if (listOfBooks.get(i) == number) {
txtLinearOutput.setText(listOfBooks[i]);
break;
}
...

4

You should always use .equals() and not == operator for String comparison. == operator will evaluate to true only when both the references are pointing to same String instance. To check whether String contents are equal you can use .equals() or equalsIgnoreCase().
So change your search condition from
if (myArray[j] == search)
to
if ...

3

To find out if a list is sorted, you would have to compare each element with ist neighbors. If only one element of thousands is not in order, a binary search can fail. So you would have to check the complete list. But going through all the list to check if the list is sorted takes longer than to look for one element in the list with linear search, so that ...

3

I suggest NOT using the built in intrinsics and implicit vectors. This only makes sense if you don't use the non GCC intrinsics (e.g. _mm_cmpeq_epi32) and only want to stick to GCC. You can do what you want like this
__m128i key2 = _mm_set1_epi64x(key);
__m128i v1 = _mm_loadu_si128((const __m128i *)&data[start + i + 0]);
__m128i v2 = ...

3

regarding 1&2, an absolute number as an answer would've been possible if an absolute number was provided as the size of the input. since the question asks about an arbitrarily sized array (of length n) then answer is also given in these terms.
you can read more about big O notation for details, but basically O(n) & O(log n) mean order of n & ...

3

You have a problem in your code. Change
scanf("%d",arr[i]);
To
scanf("%d",&arr[i]);
This is done because scanf expects an argument of type int* but you provide argument arr[i] which is of type int. Also add a check that ends the program if user inputs a number which is greater than 10 for the first scanf.

3

A linear search starts at the beginning and compares every element until it finds what you're looking for.
A binary search splits the list in the middle and looks if your value is greater or smaller than the pivot value. Then it continues doing so recursively.
For example in a list of people. You're looking for John. The binary search looks in the middle ...

3

@Trophe covered the time complexity, so I'll try to explain the space complexity
The space requirement has the same complexity
a linear search is simpler and needs just one variable
a binary search needs to store a lower and upper bound, so it's more space, but it's not dependent on the size of the list
So we say they are both O(1) space complexity

3

It's just a shorthand for when the value is not found in the sorted array. With the assumption that it's sorted, if a bigger value than the one you're searching for is met, it's useless to continue the search, so it quits and returns -1 (0 or a positive number would be ambiguous)

3

Here is the difference:
When you use contains, it use the internal array of the object and does a search like this:
for (int i = 0; i < size; i++)
if (searchObject.equals(listObject[i]))
return true;
return false;
Here when it tries to get the ith element, it directly gets the ith element object form the internal array.
...

3

Your function is defined with bool as the return type, but it returns an int (in the form of the return position statement at the end). This is a type error. Change one type or the other until they agree, and it should compile.

3

This really depends what you know about the numbers in the array. If they're all drawn from a distribution where all the probability mass is on a single value, then on expectation it will take you exactly 1 step to find the value you're looking for, since every value is the same, for example.
Let's now make a pretty strong assumption, that the array is ...

3

A couple of problems I see:
In StringList::search, the line
if (str[i] >= s)
should be changed to
if (str[i] == s)
You want to find an exact match, not the first lexicographically "greater" string, correct?
Next, the first line in StringList::remove should use
numberOfStrings - 1
instead of just
numberOfStrings
If numberOfStrings = 3, ...

2

There can be two reasons.
Case 1 [Much likely for _always_]
Simple. Because your if(arr[i]==n) condition is not met, and i<m became false. It came out of for() loop and hence, return 20.
case 2 [Less likely for _always_]
By chance, the value of n is present at the 21st location [index 20] in the input array.
Apart from the coding aspect, did you ...

2

Yes, that's correct. Can you find examples of cases that trigger these run times?

2

You are comparing if (listOfBooks.get(i) == number) it is wrong, you should compare: if (i == number), becouse you need compare element position.

2

No, it is not a linear search, as you are not looking for an element in this array, but for the maximum value in this array. It always checks all the elements of the array, while a linear-search algorithm terminates when a specific value (the one you are searching) is found. However, the complexity of this algorithm is indeed linear (more details on ...

2

Your sequentialSearch is all wrong, you are not even accessing the array in it.
Both your search method call loadItemsAndTargets. It should only be called once
binarySearch only works on sorted array. Your arrays are not sorted.
Even if you correct all of these mistakes. Beware that your array will contain duplicates. So if try to compare the index ...

2

No, you cannot.
Moreover, even if m=2 you cannot find in O(1), because that will imply you can find a value x in an unrestricted array (all values are possible) also in O(1), by creating a function:
f(i) = 1 arr[i] = x
0 otherwise
and searching if there is a value i such that f(i) = 1.
Since you cannot find in an array an element in ...

2

In your last test, the function accesses list[5], which is out of range. This causes an IndexError. The largest index you can access without raising an exception is one less than the length of the list. You can address this by modifying the condition of your while loop:
while position < len(list):
Or even better, just iterate through the list directly, ...

2

You're using == instead of .equals which doesn't check if strings are equal. .equals will check that the values are equal, not just the reference numbers like this:
if( myArray[j].equals(search)){

2

Yes, your conclusion is correct. However usually the point of using a sorted array (or any other organized structure) is when you perform the preprocessing step only once or rarely - in contrast to frequent queries. After many queries the preprocessing cost pays off.

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