```
/*
```

At the time I am writing this, all of the solutions on this page will double (or
more) the amount of space required to store the array. The following solution
reduces the amount of wasted space from Ω(n) to θ(n/w), where w is the number of
bits in a computer "word". On my machine, that's 64.

This prose in this answer is in C comments, so you can copy-and-paste this
answer verbatim and compile it with your C compiler.

```
*/
#include <stdbool.h>
#include <stddef.h>
#include <stdint.h>
#include <stdlib.h>
/*
```

The problem is to support reading and writing values in an array in O(1) time
along with bulk writes in which all values in the array are written at once in
O(1) time. This is possible using a technique invented by Aho, Hopcroft and
Ullman, as far as I know. I will present a version due to Gonzalo Navarro,
"Constant-Time Array Initialization in Little
Space".

The idea is to keep three metadata arrays along with the data array. We also
keep two integers: `unset`

, which is the last value used in a bulk write
operation, and `size`

, an approximation for the number of values that have been
set since the last bulk write. At all times, the number of distinct values
written since the last bulk write is between `size`

and w * `size`

.

The three metadata arrays describe information about blocks of w values in the
data array. They are:

`nth`

: nth[i] is the ith unique block to be written to since the last bulk
write

`inverse_nth`

: inverse_nth[i] is the order in in which the ith block of the
array was written, counting from 0 at the last bulk write.

`bitset`

: The jth bit of `bitset[i]`

is 1 when the array cell numbered
64*i + j has been written to since the last bulk write.

`bitset[i]`

and `inverse_nth[i]`

are allowed to be invalid if `i`

is not a
member of the set {`nth[0]`

, `nth[1]`

, ... , `nth[size-1]`

}. In other words,
`inverse_nth[i]`

and `bitset[i]`

are valid if and only if `inverse_nth[i] < size`

and `nth[inverse_nth[i]] == i`

.

Rather than store three separate arrays of the same length, I chose to store one
array, `is_set`

, with three fields.

```
*/
typedef struct {
int nth_;
int inverse_nth_;
uint64_t bitset_;
} IsSetCell;
typedef struct {
int unset_;
int size_;
IsSetCell is_set_[];
} IsSetArray;
typedef struct {
IsSetArray * metadata_;
int payload_[];
} ResettableArray;
/*
```

To construct an array, we need a default value to return when the reading a
value that has never been written to.

```
*/
ResettableArray * ConstructResettableArray(int n, int unset) {
ResettableArray* result =
malloc(offsetof(ResettableArray, payload_) + n * sizeof(int));
if (!result) return NULL;
n = (n + 63) / 64;
result->metadata_ =
malloc(offsetof(IsSetArray, is_set_) + n * sizeof(IsSetCell));
if (!result->metadata_) {
free(result);
return NULL;
}
result->metadata_->size_ = 0;
result->metadata_->unset_ = unset;
return result;
}
void DestructResettableArray(ResettableArray * a) {
if (a) free(a->metadata_);
free(a);
}
/*
```

The bulk of the algorithm is in writing and reading the metadata. After
`IsSet()`

and `Set()`

are defined (below), reading and writing the arrays is
straightforward.

```
*/
bool IsSet(const IsSetArray * a, int i);
void Set(IsSetArray * a, int i);
int GetValue(const ResettableArray * a, int i) {
if (!IsSet(a->metadata_, i)) return a->metadata_->unset_;
return a->payload_[i];
}
void SetValue(ResettableArray * a, int i, int v) {
a->payload_[i] = v;
Set(a->metadata_, i);
}
void SetAllValues(ResettableArray * a, int v) {
a->metadata_->unset_ = v;
}
/*
```

The complex part of reading and writing is the bidirectional relationship
between `inverse_nth`

and `nth`

. If they point to each other at location i
(`is_set[is_set[i].inverse_nth].nth == i`

) then location i contains valid data
that was written after the last bulk write, as long as ```
is_set[i].inverse_nth <
size
```

.

```
*/
uint64_t OneBit(int i) {
return UINT64_C(1) << i;
}
bool IsSet(const IsSetArray * a, int i) {
const int cell = i/64, offset = i & 63;
const int inverse_nth = a->is_set_[cell].inverse_nth_;
return inverse_nth < a->size_ && a->is_set_[inverse_nth].nth_ == cell &&
a->is_set_[cell].bitset_ & OneBit(offset);
}
void Set(IsSetArray * a, int i) {
const int cell = i/64, offset = i & 63;
const int inverse_nth = a->is_set_[cell].inverse_nth_;
if (inverse_nth >= a->size_ || a->is_set_[inverse_nth].nth_ != cell) {
a->is_set_[cell].inverse_nth_ = a->size_;
a->is_set_[cell].bitset_ = 0;
a->is_set_[a->size_].nth_ = cell;
++a->size_;
}
a->is_set_[cell].bitset_ |= OneBit(offset);
}
```