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286 lines
9.8 KiB
Markdown
286 lines
9.8 KiB
Markdown
# Leo RFC 005: Countdown Loops
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## Authors
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The Aleo Team.
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## Status
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IMPLEMENTED
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# Summary
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This proposal suggests adding countdown loops and inclusive loop ranges into the Leo language.
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# Motivation
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In the current design of the language only incremental ranges are allowed. Though
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in some cases there's a need for loops going in the reverse direction. These examples
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demonstrate the shaker sort and bubble sort algorithms where countdown loops are mocked:
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```ts
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function shaker_sort(a: [u32; 10], const rounds: u32) -> [u32; 10] {
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for k in 0..rounds {
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for i in 0..9 {
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if a[i] > a[i + 1] {
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let tmp = a[i];
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a[i] = a[i + 1];
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a[i + 1] = tmp;
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}
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}
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for j in 0..9 { // j goes from 0 to 8
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let i = 8 - j; // j is flipped
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if a[i] > a[i + 1] {
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let tmp = a[i];
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a[i] = a[i + 1];
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a[i + 1] = tmp;
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}
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}
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}
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return a;
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}
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```
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```ts
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function bubble_sort(a: [u32; 10]) -> [u32; 10] {
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for i in 0..9 { // i counts up
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for j in 0..9-i { // i is flipped
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if (a[j] > a[j+1]) {
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let tmp = a[j];
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a[j] = a[j+1];
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a[j+1] = tmp;
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}
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}
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}
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return a
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}
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```
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Having a countdown loop in the examples above could improve readability and
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usability of the language by making it more natural to the developer.
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However, if we imagined this example using a countdown loop, we would see that
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it wouldn't be possible to count to 0; because the first bound of the range is
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inclusive and the second is exclusive, and loops ranges must use only unsigned integers.
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```ts
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// loop goes 0,1,2,3,4,5,6,7,8
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for i in 0..9 { /* ... */ }
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// loop goes 9,8,7,6,5,4,3,2,1
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for i in 9..0 { /* ... */ }
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```
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Hence direct implementation of the coundown loop ranges would create asymmetry (1)
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and would not allow loops to count down to 0 (2). To implement coundown loops and
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solve these two problems we suggest adding an inclusive range bounds.
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# Design
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## Coundown loops
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Countdown ranges do not need any changes to the existing syntax. However their
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functionality needs to be implemented in the compiler.
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```ts
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for i in 5..0 {}
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```
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## Inclusive ranges
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To solve loop asymmetry and to improve loop ranges in general we suggest adding
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inclusive range operator to Leo. Inclusive range would extend the second bound
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of the loop making it inclusive (instead of default - exclusive)
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therefore allowing countdown loops to reach 0 value.
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```ts
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// default loop: 0,1,2,3,4
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for i in 0..5 {}
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// inclusive range: 0,1,2,3,4,5
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for i in 0..=5 {}
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```
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## Step and Direction
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We remark that the step of both counting-up and counting-down loops is implicitly 1;
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that is, the loop variable is incremented or decremented by 1.
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Whether the loop counts up or down is determined by how the starting and ending bounds compare.
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Note that the bounds are not necessarily literals;
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they may be more complex `const` expressions, and thus in general their values are resolved at code flattening time.
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Because of the type restrictions on bounds, their values are always non-negative integers.
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If `S` is the integer value of the starting bound and `E` is the integer value of the ending bound,
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there are several cases to consider:
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1. If `S == E` and the ending bound is exclusive, there is no actual loop; the range is empty.
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2. If `S == E` and the ending bound is inclusive, the loop consists of just one iteration; the loop counts neither up nor down.
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3. If `S < E` and the ending bound is exclusive, the loop counts up, from `S` to `E-1`.
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4. If `S < E` and the ending bound is inclusive, the loop counts up, from `S` to `E`.
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5. If `S > E` and the ending bound is exclusive, the loop counts down, from `S` to `E+1`.
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6. If `S > E` and the ending bound is inclusive, the loop counts down, from `S` to `E`.
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Cases 3 and 5 consist of one or more iterations; cases 4 and 6 consist of two or more iterations.
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## Examples
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The code examples demostrated in the Motivation part of this document
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could be extended (or simplified) with the suggested syntax:
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```ts
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function shaker_sort(a: [u32; 10], const rounds: u32) -> [u32; 10] {
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for k in 0..rounds {
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for i in 0..9 { // i goes from 0 to 8
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if a[i] > a[i + 1] {
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let tmp = a[i];
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a[i] = a[i + 1];
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a[i + 1] = tmp;
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}
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}
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for i in 8..=0 { // i goes from 8 to 0
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if a[i] > a[i + 1] {
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let tmp = a[i];
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a[i] = a[i + 1];
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a[i + 1] = tmp;
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}
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}
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}
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return a;
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}
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```
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```ts
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function bubble_sort(a: [u32; 10]) -> [u32; 10] {
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for i in 9..0 { // counts down
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for j in 0..i { // no flipping
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if (a[j] > a[j+1]) {
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let tmp = a[j];
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a[j] = a[j+1];
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a[j+1] = tmp;
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}
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}
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}
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return a
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}
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```
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# Drawbacks
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No obvious drawback.
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# Effect on Ecosystem
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Suggested change should have no effect on ecosystem because of its backward compatibility.
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# Alternatives
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## Mocking
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Coundown loops can be mocked manually.
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## Exclusive Starting Bounds
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While the ability to designate the ending bound of a loop as either exclusive or inclusive is critical as discussed below,
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we could also consider adding the ability to designate the starting bound of a loop as either exclusive or inclusive.
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If we do that, we run into a sort of asymmetry in the defaults for starting and ending bounds:
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the default for the starting bound is inclusive, while the default for ending bounds is exclusive.
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The most symmetric but verbose approach is exemplified as follows:
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* `0=..=5` for `0 1 2 3 4 5`
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* `0<..=5` for `1 2 3 4 5`
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* `0=..<5` for `0 1 2 3 4`
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* `0<..<5` for `1 2 3 4`
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* `5=..=0` for `5 4 3 2 1 0`
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* `5>..=0` for `4 3 2 1 0`
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* `5=..>0` for `5 4 3 2 1`
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* `5>..>0` for `4 3 2 1`
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That is, this approach makes exclusivensss and inclusiveness implicit.
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The use of `<` vs. `>` also indicates a loop direction, which can be inferred anyhow when the `const` bounds are resolved,
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so that would entail an additional consistency check,
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namely that the inequality sign/signs is/are consistent with the inferred loop direction.
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Within the symmetric approach above, there are different options for defaults.
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The most symmetric default would be perhaps `=` for both bounds,
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but that would be a different behavior from current Leo.
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We could instead go for different defaults for starting and ending bounds,
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i.e. `=` for the starting bound and `<` or `>` (depending on direction) for the ending bound.
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A drawback of this approach is that it is somewhat verbose.
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Furthermore, some of the authors of this RFC do not find it very readable.
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## Flipping Bound Defaults for Countdown
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In the proposed design, there is an asymmetry between the treatment of loops that count up vs. down.
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This can be seen clearly by thinking how to iterate through an array of size `N`:
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```ts
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for i in 0..n { ... a[i] ... } // count up -- 0 1 2 ... n-1
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for i in n-1..=0 { ... a[i] ... } // count down -- n-1 ... 2 1 0
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```
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While the loop that counts up has nice and simple bounds `0` and `n`,
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the loop that counts down needs `n-1` and `=0`.
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So a possible idea is to use different defaults depending on the loop direction:
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* For a loop that counts up:
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* The starting (i.e. lower) bound is always inclusive.
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* The ending (i.e. upper) bound is exclusive by default, inclusive with `=`.
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* For loop that counts down:
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* The ending (i.e. lower) bound is always inclusive.
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* The starting (i.e. upper) bound is exclusive by default, inclusive with `=`.
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That is, different defaults apply to lower vs. upper bound, rather than to starting and ending bounds.
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Things become more symmetric in a way:
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```ts
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for i in 0..n { ... a[i] ... } // count up -- 0 1 2 ... n-1
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for i in n..0 { ... a[i] ... } // count down -- n-1 ... 2 1 0
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```
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This is also consistent with Rust in a way,
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where countdown loops are obtained by reversing the increasing range into a decreasing range, which flips the bounds.
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However, if we consider a possible extension in which the step may be larger than 1, we run into some awkwardness.
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Imagine an extension in which `step` is specified:
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```ts
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for i in 10..0 step 2 ... // i = 8 6 4 2 0 -- starts at 10-2 = 8
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for i in 10..0 step 3 ... // i = 9 6 3 0 -- starts at 10-1 = 9
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```
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Note how the actual starting index does not depend on starting/upper bound and step,
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but rather on ending/lower bound and step, and must be calculated explicitly;
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it doesn't "jump" at the reader.
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## Explicit Indication of Loop Direction
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Another idea that was brought up is to always write the range as `<lower>..<upper>`,
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but include an explicit indication when the loop must count down, e.g.
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```ts
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for i in 0..n down { ... array[i] ... } // where 'down' indicates count down
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```
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The advantages are that
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we retain the default that the first/lower bound is inclusive and the second/upper bound is exclusive,
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and the direction is explicit and does not have to be inferred.
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The direction matches starting/ending bound to lower/upper bound or upper/lower bound.
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But the awkwardness with larger steps than 1 remains:
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```ts
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for i in 0..10 down step 2 ... // i = 8 6 4 2 0 -- starts at 10-2 = 8
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for i in 0..10 down step 3 ... // i = 9 6 3 0 -- starts at 10-1 = 9
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```
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## Variable in the Middle of Range with Equalities or Inequalities
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Another approach is to put the variable in the middle of the range,
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along with equality or inequality signs around the variable, e.g.
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```ts
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for 0 <= i < 5 // 0 1 2 3 4
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for 0 <= i <= 5 // 0 1 2 3 4 5
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for 5 > i >= 0 // 4 3 2 1 0
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```
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This maximizes explicitness, but it may need tweaking to avoid parsing ambiguities or difficulties
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(recall that the bounds may be complex `const` expressions).
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This could be a future addition to consider, but it seems that it would not replace the current Rust-like syntax.
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