Backwards compatibility

From APL Wiki
Revision as of 23:29, 10 March 2024 by Marshall (talk | contribs)
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to navigation Jump to search

In APL design, backwards compatibility is the practice of ensuring that older codebases or systems are able to work with new APL dialects, versions, or libraries. Since its early development, APL—and in particular widely used commercial dialects—has had a strong emphasis on backwards compatibility. However, there have also been several significant languages that retain core APL ideas while breaking compatibility, including Iverson's own J. Ideas from these languages are sometimes incorporated back into mainstream, backwards-compatible APLs.

APL dialects that emphasize backward compatibility typically apply greater caution when designing features in order to preserve the possibility for extension in the future, and may even consider forward compatibility—the ability for an older system to work, or fail safely, with newer features—when designing. Features designed with less care in the past may cause language inconsistencies in the future indefinitely. For example, Membership's behavior on high-rank arrays is incompatible with and less useful than major cell search, but extending it in the new way would break too much existing code for commercial APLs to consider it.

Scope

Different features in an APL implementation are usually subject to different levels of backwards compatibility constraint. The results of primitives, and the meaning of syntax, are always considered the most important to maintain, while system functions are often handled more loosely and I-beams or user commands may have very low backwards compatibility requirements.

The specific error messages produced by any given error is considered less important keep constant. The standards indeed leave it up to the implementations too decide the order in which various aspects of code validity is checked. For example 'ABC'×1 2 3 4 could be a LENGTH ERROR (3 vs. 4 elements) or a DOMAIN ERROR (attempting to multiply characters). Implementations are known to change the precedence of such errors.

Errors can disappear altogether when the domains of primitives are extended, or additional syntax is added. For example, it is common practice to insert a deliberate error into a function, in order to force execution to halt, and the tracing interface to appear. The traditional way to do so was to insert a line with one a function on it. The FinnAPL idiom library includes

738. Syntax error to stop execution
*

but this will simply print * in dialects that allow primitive functions to be named. Another common phrase was *** as this is easy to search for while being exceedingly unlikely to appear in code. However, with the adoption of trains, this too became valid, and is likely to print verbatim rather than stop execution. APLcart includes ... for the same purpose, relying on the continued prohibition against immediately adjacent dyadic operators other than for outer product (∘.g).

Dialects

APL dialects that historically have strongly emphasized backwards compatibility include:

In the 1970s and early 1980s it was common to create new APL implementations to run on new hardware. These implementations almost always shared the primitive set of APL.SV or another IBM APL, but often developed new system functions or other peripheral functionality to better match the host system.

Even the languages listed above may make changes to existing behavior. APL2 broke from APL\360 by promoting bracket indexing to higher precedence than stranding, a decision that wasn't taken up by its contemporary Dyalog APL, but was shared by some later dialects including APLX and GNU APL. More recently, Dyalog APL 13.0 broke compatibility for the Power function while introducing complex numbers, which were controversial feature for that and other reasons. Some dialects include a compatibility setting as a system variable.

Notable APL dialects or offshoots that discard backwards compatibility with APL in significant ways include:

Of these, J has built a large enough user base to develop its own backwards compatibility concerns, even though early J design was fairly loose with respect to backwards compatibility. Beginning with version 8.07 in 2018 it has removed various features that are considered less important. BQN now strongly emphasizes backwards compatibility.

Newer and less commercial APLs such as APL\iv, April, or ngn/apl tend to be less focused on backwards compatibility than historical ones. These dialects tend to take most design choices from a well-known APL such as Dyalog APL or GNU APL, but make small breaks for experimentation or address particular issues. They typically do not support features that were historically important but are now rarely used, such as shared variables or Branch, and may discard features that are still in use but have an adequate replacement, for example removing tradfns in favor of dfns.

See also

External links

APL development [edit]
Interface SessionTyping glyphs (on Linux) ∙ FontsText editors
Publications IntroductionsLearning resourcesSimple examplesAdvanced examplesMnemonicsISO 8485:1989ISO/IEC 13751:2001A Dictionary of APLCase studiesDocumentation suitesBooksPapersVideosAPL Quote QuadVector journalTerminology (Chinese, German) ∙ Neural networksError trapping with Dyalog APL (in forms)
Sharing code Backwards compatibilityAPLcartAPLTreeAPL-CationDfns workspaceTatinCider
Implementation ResourcesOpen-sourceMagic functionPerformanceAPL hardware
Developers Timeline of corporationsAPL2000DyalogIBMIPSASTSC