mirror of
https://github.com/tursodatabase/libsql.git
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2264 lines
89 KiB
JavaScript
2264 lines
89 KiB
JavaScript
/**
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2022-07-08
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The author disclaims copyright to this source code. In place of a
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legal notice, here is a blessing:
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* May you do good and not evil.
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* May you find forgiveness for yourself and forgive others.
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* May you share freely, never taking more than you give.
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***********************************************************************
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The whwasmutil is developed in conjunction with the Jaccwabyt
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project:
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https://fossil.wanderinghorse.net/r/jaccwabyt
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and sqlite3:
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https://sqlite.org
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This file is kept in sync between both of those trees.
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Maintenance reminder: If you're reading this in a tree other than
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one of those listed above, note that this copy may be replaced with
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upstream copies of that one from time to time. Thus the code
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installed by this function "should not" be edited outside of those
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projects, else it risks getting overwritten.
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*/
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/**
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This function is intended to simplify porting around various bits
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of WASM-related utility code from project to project.
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The primary goal of this code is to replace, where possible,
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Emscripten-generated glue code with equivalent utility code which
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can be used in arbitrary WASM environments built with toolchains
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other than Emscripten. As of this writing, this code is capable of
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acting as a replacement for Emscripten's generated glue code
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_except_ that the latter installs handlers for Emscripten-provided
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APIs such as its "FS" (virtual filesystem) API. Loading of such
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things still requires using Emscripten's glue, but the post-load
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utility APIs provided by this code are still usable as replacements
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for their sub-optimally-documented Emscripten counterparts.
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Intended usage:
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```
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globalThis.WhWasmUtilInstaller(appObject);
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delete globalThis.WhWasmUtilInstaller;
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```
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Its global-scope symbol is intended only to provide an easy way to
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make it available to 3rd-party scripts and "should" be deleted
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after calling it. That symbols is _not_ used within the library.
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Forewarning: this API explicitly targets only browser
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environments. If a given non-browser environment has the
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capabilities needed for a given feature (e.g. TextEncoder), great,
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but it does not go out of its way to account for them and does not
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provide compatibility crutches for them.
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It currently offers alternatives to the following
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Emscripten-generated APIs:
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- OPTIONALLY memory allocation, but how this gets imported is
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environment-specific. Most of the following features only work
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if allocation is available.
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- WASM-exported "indirect function table" access and
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manipulation. e.g. creating new WASM-side functions using JS
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functions, analog to Emscripten's addFunction() and
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uninstallFunction() but slightly different.
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- Get/set specific heap memory values, analog to Emscripten's
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getValue() and setValue().
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- String length counting in UTF-8 bytes (C-style and JS strings).
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- JS string to C-string conversion and vice versa, analog to
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Emscripten's stringToUTF8Array() and friends, but with slighter
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different interfaces.
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- JS string to Uint8Array conversion, noting that browsers actually
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already have this built in via TextEncoder.
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- "Scoped" allocation, such that allocations made inside of a given
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explicit scope will be automatically cleaned up when the scope is
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closed. This is fundamentally similar to Emscripten's
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stackAlloc() and friends but uses the heap instead of the stack
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because access to the stack requires C code.
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- Create JS wrappers for WASM functions, analog to Emscripten's
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ccall() and cwrap() functions, except that the automatic
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conversions for function arguments and return values can be
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easily customized by the client by assigning custom function
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signature type names to conversion functions. Essentially,
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it's ccall() and cwrap() on steroids.
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How to install...
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Passing an object to this function will install the functionality
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into that object. Afterwards, client code "should" delete the global
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symbol.
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This code requires that the target object have the following
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properties, noting that they needn't be available until the first
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time one of the installed APIs is used (as opposed to when this
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function is called) except where explicitly noted:
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- `exports` must be a property of the target object OR a property
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of `target.instance` (a WebAssembly.Module instance) and it must
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contain the symbols exported by the WASM module associated with
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this code. In an Enscripten environment it must be set to
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`Module['asm']` (versions <=3.1.43) or `wasmExports` (versions
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>=3.1.44). The exports object must contain a minimum of the
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following symbols:
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- `memory`: a WebAssembly.Memory object representing the WASM
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memory. _Alternately_, the `memory` property can be set as
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`target.memory`, in particular if the WASM heap memory is
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initialized in JS an _imported_ into WASM, as opposed to being
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initialized in WASM and exported to JS.
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- `__indirect_function_table`: the WebAssembly.Table object which
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holds WASM-exported functions. This API does not strictly
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require that the table be able to grow but it will throw if its
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`installFunction()` is called and the table cannot grow.
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In order to simplify downstream usage, if `target.exports` is not
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set when this is called then a property access interceptor
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(read-only, configurable, enumerable) gets installed as `exports`
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which resolves to `target.instance.exports`, noting that the latter
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property need not exist until the first time `target.exports` is
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accessed.
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Some APIs _optionally_ make use of the `bigIntEnabled` property of
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the target object. It "should" be set to true if the WASM
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environment is compiled with BigInt support, else it must be
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false. If it is false, certain BigInt-related features will trigger
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an exception if invoked. This property, if not set when this is
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called, will get a default value of true only if the BigInt64Array
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constructor is available, else it will default to false. Note that
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having the BigInt type is not sufficient for full int64 integration
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with WASM: the target WASM file must also have been built with
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that support. In Emscripten that's done using the `-sWASM_BIGINT`
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flag.
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Some optional APIs require that the target have the following
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methods:
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- 'alloc()` must behave like C's `malloc()`, allocating N bytes of
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memory and returning its pointer. In Emscripten this is
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conventionally made available via `Module['_malloc']`. This API
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requires that the alloc routine throw on allocation error, as
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opposed to returning null or 0.
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- 'dealloc()` must behave like C's `free()`, accepting either a
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pointer returned from its allocation counterpart or the values
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null/0 (for which it must be a no-op). allocating N bytes of
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memory and returning its pointer. In Emscripten this is
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conventionally made available via `Module['_free']`.
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APIs which require allocation routines are explicitly documented as
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such and/or have "alloc" in their names.
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This code is developed and maintained in conjunction with the
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Jaccwabyt project:
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https://fossil.wanderinghorse.net/r/jaccwabbyt
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More specifically:
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https://fossil.wanderinghorse.net/r/jaccwabbyt/file/common/whwasmutil.js
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*/
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globalThis.WhWasmUtilInstaller = function(target){
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'use strict';
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if(undefined===target.bigIntEnabled){
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target.bigIntEnabled = !!globalThis['BigInt64Array'];
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}
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/** Throws a new Error, the message of which is the concatenation of
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all args with a space between each. */
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const toss = (...args)=>{throw new Error(args.join(' '))};
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if(!target.exports){
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Object.defineProperty(target, 'exports', {
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enumerable: true, configurable: true,
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get: ()=>(target.instance && target.instance.exports)
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});
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}
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/*********
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alloc()/dealloc() auto-install...
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This would be convenient but it can also cause us to pick up
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malloc() even when the client code is using a different exported
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allocator (who, me?), which is bad. malloc() may be exported even
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if we're not explicitly using it and overriding the malloc()
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function, linking ours first, is not always feasible when using a
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malloc() proxy, as it can lead to recursion and stack overflow
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(who, me?). So... we really need the downstream code to set up
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target.alloc/dealloc() itself.
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******/
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/******
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if(target.exports){
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//Maybe auto-install alloc()/dealloc()...
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if(!target.alloc && target.exports.malloc){
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target.alloc = function(n){
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const m = this(n);
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return m || toss("Allocation of",n,"byte(s) failed.");
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}.bind(target.exports.malloc);
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}
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if(!target.dealloc && target.exports.free){
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target.dealloc = function(ptr){
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if(ptr) this(ptr);
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}.bind(target.exports.free);
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}
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}*******/
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/**
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Pointers in WASM are currently assumed to be 32-bit, but someday
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that will certainly change.
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*/
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const ptrIR = target.pointerIR || 'i32';
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const ptrSizeof = target.ptrSizeof =
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('i32'===ptrIR ? 4
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: ('i64'===ptrIR
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? 8 : toss("Unhandled ptrSizeof:",ptrIR)));
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/** Stores various cached state. */
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const cache = Object.create(null);
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/** Previously-recorded size of cache.memory.buffer, noted so that
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we can recreate the view objects if the heap grows. */
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cache.heapSize = 0;
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/** WebAssembly.Memory object extracted from target.memory or
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target.exports.memory the first time heapWrappers() is
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called. */
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cache.memory = null;
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/** uninstallFunction() puts table indexes in here for reuse and
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installFunction() extracts them. */
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cache.freeFuncIndexes = [];
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/**
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Used by scopedAlloc() and friends.
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*/
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cache.scopedAlloc = [];
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cache.utf8Decoder = new TextDecoder();
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cache.utf8Encoder = new TextEncoder('utf-8');
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/**
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For the given IR-like string in the set ('i8', 'i16', 'i32',
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'f32', 'float', 'i64', 'f64', 'double', '*'), or any string value
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ending in '*', returns the sizeof for that value
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(target.ptrSizeof in the latter case). For any other value, it
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returns the undefined value.
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*/
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target.sizeofIR = (n)=>{
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switch(n){
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case 'i8': return 1;
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case 'i16': return 2;
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case 'i32': case 'f32': case 'float': return 4;
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case 'i64': case 'f64': case 'double': return 8;
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case '*': return ptrSizeof;
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default:
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return (''+n).endsWith('*') ? ptrSizeof : undefined;
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}
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};
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/**
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If (cache.heapSize !== cache.memory.buffer.byteLength), i.e. if
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the heap has grown since the last call, updates cache.HEAPxyz.
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Returns the cache object.
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*/
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const heapWrappers = function(){
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if(!cache.memory){
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cache.memory = (target.memory instanceof WebAssembly.Memory)
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? target.memory : target.exports.memory;
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}else if(cache.heapSize === cache.memory.buffer.byteLength){
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return cache;
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}
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// heap is newly-acquired or has been resized....
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const b = cache.memory.buffer;
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cache.HEAP8 = new Int8Array(b); cache.HEAP8U = new Uint8Array(b);
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cache.HEAP16 = new Int16Array(b); cache.HEAP16U = new Uint16Array(b);
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cache.HEAP32 = new Int32Array(b); cache.HEAP32U = new Uint32Array(b);
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if(target.bigIntEnabled){
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cache.HEAP64 = new BigInt64Array(b); cache.HEAP64U = new BigUint64Array(b);
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}
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cache.HEAP32F = new Float32Array(b); cache.HEAP64F = new Float64Array(b);
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cache.heapSize = b.byteLength;
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return cache;
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};
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/** Convenience equivalent of this.heapForSize(8,false). */
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target.heap8 = ()=>heapWrappers().HEAP8;
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/** Convenience equivalent of this.heapForSize(8,true). */
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target.heap8u = ()=>heapWrappers().HEAP8U;
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/** Convenience equivalent of this.heapForSize(16,false). */
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target.heap16 = ()=>heapWrappers().HEAP16;
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/** Convenience equivalent of this.heapForSize(16,true). */
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target.heap16u = ()=>heapWrappers().HEAP16U;
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/** Convenience equivalent of this.heapForSize(32,false). */
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target.heap32 = ()=>heapWrappers().HEAP32;
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/** Convenience equivalent of this.heapForSize(32,true). */
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target.heap32u = ()=>heapWrappers().HEAP32U;
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/**
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Requires n to be one of:
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- integer 8, 16, or 32.
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- A integer-type TypedArray constructor: Int8Array, Int16Array,
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Int32Array, or their Uint counterparts.
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If this.bigIntEnabled is true, it also accepts the value 64 or a
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BigInt64Array/BigUint64Array, else it throws if passed 64 or one
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of those constructors.
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Returns an integer-based TypedArray view of the WASM heap
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memory buffer associated with the given block size. If passed
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an integer as the first argument and unsigned is truthy then
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the "U" (unsigned) variant of that view is returned, else the
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signed variant is returned. If passed a TypedArray value, the
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2nd argument is ignored. Note that Float32Array and
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Float64Array views are not supported by this function.
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Note that growth of the heap will invalidate any references to
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this heap, so do not hold a reference longer than needed and do
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not use a reference after any operation which may
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allocate. Instead, re-fetch the reference by calling this
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function again.
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Throws if passed an invalid n.
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Pedantic side note: the name "heap" is a bit of a misnomer. In a
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WASM environment, the stack and heap memory are all accessed via
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the same view(s) of the memory.
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*/
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target.heapForSize = function(n,unsigned = true){
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let ctor;
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const c = (cache.memory && cache.heapSize === cache.memory.buffer.byteLength)
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? cache : heapWrappers();
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switch(n){
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case Int8Array: return c.HEAP8; case Uint8Array: return c.HEAP8U;
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case Int16Array: return c.HEAP16; case Uint16Array: return c.HEAP16U;
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case Int32Array: return c.HEAP32; case Uint32Array: return c.HEAP32U;
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case 8: return unsigned ? c.HEAP8U : c.HEAP8;
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case 16: return unsigned ? c.HEAP16U : c.HEAP16;
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case 32: return unsigned ? c.HEAP32U : c.HEAP32;
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case 64:
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if(c.HEAP64) return unsigned ? c.HEAP64U : c.HEAP64;
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break;
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default:
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if(target.bigIntEnabled){
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if(n===globalThis['BigUint64Array']) return c.HEAP64U;
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else if(n===globalThis['BigInt64Array']) return c.HEAP64;
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break;
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}
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}
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toss("Invalid heapForSize() size: expecting 8, 16, 32,",
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"or (if BigInt is enabled) 64.");
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};
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/**
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Returns the WASM-exported "indirect function table."
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*/
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target.functionTable = function(){
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return target.exports.__indirect_function_table;
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/** -----------------^^^^^ "seems" to be a standardized export name.
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From Emscripten release notes from 2020-09-10:
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- Use `__indirect_function_table` as the import name for the
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table, which is what LLVM does.
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*/
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};
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/**
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Given a function pointer, returns the WASM function table entry
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if found, else returns a falsy value: undefined if fptr is out of
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range or null if it's in range but the table entry is empty.
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*/
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target.functionEntry = function(fptr){
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const ft = target.functionTable();
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return fptr < ft.length ? ft.get(fptr) : undefined;
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};
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/**
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Creates a WASM function which wraps the given JS function and
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returns the JS binding of that WASM function. The signature
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string must be the Jaccwabyt-format or Emscripten
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addFunction()-format function signature string. In short: in may
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have one of the following formats:
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- Emscripten: `"x..."`, where the first x is a letter representing
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the result type and subsequent letters represent the argument
|
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types. Functions with no arguments have only a single
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letter. See below.
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- Jaccwabyt: `"x(...)"` where `x` is the letter representing the
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result type and letters in the parens (if any) represent the
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argument types. Functions with no arguments use `x()`. See
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below.
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Supported letters:
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- `i` = int32
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- `p` = int32 ("pointer")
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- `j` = int64
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- `f` = float32
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- `d` = float64
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- `v` = void, only legal for use as the result type
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It throws if an invalid signature letter is used.
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Jaccwabyt-format signatures support some additional letters which
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have no special meaning here but (in this context) act as aliases
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for other letters:
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- `s`, `P`: same as `p`
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Sidebar: this code is developed together with Jaccwabyt, thus the
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support for its signature format.
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The arguments may be supplied in either order: (func,sig) or
|
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(sig,func).
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*/
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target.jsFuncToWasm = function f(func, sig){
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/** Attribution: adapted up from Emscripten-generated glue code,
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refactored primarily for efficiency's sake, eliminating
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call-local functions and superfluous temporary arrays. */
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if(!f._){/*static init...*/
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f._ = {
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// Map of signature letters to type IR values
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sigTypes: Object.assign(Object.create(null),{
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i: 'i32', p: 'i32', P: 'i32', s: 'i32',
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j: 'i64', f: 'f32', d: 'f64'
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}),
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// Map of type IR values to WASM type code values
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typeCodes: Object.assign(Object.create(null),{
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f64: 0x7c, f32: 0x7d, i64: 0x7e, i32: 0x7f
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}),
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/** Encodes n, which must be <2^14 (16384), into target array
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tgt, as a little-endian value, using the given method
|
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('push' or 'unshift'). */
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uleb128Encode: function(tgt, method, n){
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if(n<128) tgt[method](n);
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else tgt[method]( (n % 128) | 128, n>>7);
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},
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/** Intentionally-lax pattern for Jaccwabyt-format function
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pointer signatures, the intent of which is simply to
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distinguish them from Emscripten-format signatures. The
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downstream checks are less lax. */
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rxJSig: /^(\w)\((\w*)\)$/,
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/** Returns the parameter-value part of the given signature
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string. */
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sigParams: function(sig){
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const m = f._.rxJSig.exec(sig);
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return m ? m[2] : sig.substr(1);
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},
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/** Returns the IR value for the given letter or throws
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if the letter is invalid. */
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letterType: (x)=>f._.sigTypes[x] || toss("Invalid signature letter:",x),
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/** Returns an object describing the result type and parameter
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type(s) of the given function signature, or throws if the
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signature is invalid. */
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/******** // only valid for use with the WebAssembly.Function ctor, which
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// is not yet documented on MDN.
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sigToWasm: function(sig){
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const rc = {parameters:[], results: []};
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if('v'!==sig[0]) rc.results.push(f.sigTypes(sig[0]));
|
|
for(const x of f._.sigParams(sig)){
|
|
rc.parameters.push(f._.typeCodes(x));
|
|
}
|
|
return rc;
|
|
},************/
|
|
/** Pushes the WASM data type code for the given signature
|
|
letter to the given target array. Throws if letter is
|
|
invalid. */
|
|
pushSigType: (dest, letter)=>dest.push(f._.typeCodes[f._.letterType(letter)])
|
|
};
|
|
}/*static init*/
|
|
if('string'===typeof func){
|
|
const x = sig;
|
|
sig = func;
|
|
func = x;
|
|
}
|
|
const sigParams = f._.sigParams(sig);
|
|
const wasmCode = [0x01/*count: 1*/, 0x60/*function*/];
|
|
f._.uleb128Encode(wasmCode, 'push', sigParams.length);
|
|
for(const x of sigParams) f._.pushSigType(wasmCode, x);
|
|
if('v'===sig[0]) wasmCode.push(0);
|
|
else{
|
|
wasmCode.push(1);
|
|
f._.pushSigType(wasmCode, sig[0]);
|
|
}
|
|
f._.uleb128Encode(wasmCode, 'unshift', wasmCode.length)/* type section length */;
|
|
wasmCode.unshift(
|
|
0x00, 0x61, 0x73, 0x6d, /* magic: "\0asm" */
|
|
0x01, 0x00, 0x00, 0x00, /* version: 1 */
|
|
0x01 /* type section code */
|
|
);
|
|
wasmCode.push(
|
|
/* import section: */ 0x02, 0x07,
|
|
/* (import "e" "f" (func 0 (type 0))): */
|
|
0x01, 0x01, 0x65, 0x01, 0x66, 0x00, 0x00,
|
|
/* export section: */ 0x07, 0x05,
|
|
/* (export "f" (func 0 (type 0))): */
|
|
0x01, 0x01, 0x66, 0x00, 0x00
|
|
);
|
|
return (new WebAssembly.Instance(
|
|
new WebAssembly.Module(new Uint8Array(wasmCode)), {
|
|
e: { f: func }
|
|
})).exports['f'];
|
|
}/*jsFuncToWasm()*/;
|
|
|
|
/**
|
|
Documented as target.installFunction() except for the 3rd
|
|
argument: if truthy, the newly-created function pointer
|
|
is stashed in the current scoped-alloc scope and will be
|
|
cleaned up at the matching scopedAllocPop(), else it
|
|
is not stashed there.
|
|
*/
|
|
const __installFunction = function f(func, sig, scoped){
|
|
if(scoped && !cache.scopedAlloc.length){
|
|
toss("No scopedAllocPush() scope is active.");
|
|
}
|
|
if('string'===typeof func){
|
|
const x = sig;
|
|
sig = func;
|
|
func = x;
|
|
}
|
|
if('string'!==typeof sig || !(func instanceof Function)){
|
|
toss("Invalid arguments: expecting (function,signature) "+
|
|
"or (signature,function).");
|
|
}
|
|
const ft = target.functionTable();
|
|
const oldLen = ft.length;
|
|
let ptr;
|
|
while(cache.freeFuncIndexes.length){
|
|
ptr = cache.freeFuncIndexes.pop();
|
|
if(ft.get(ptr)){ /* Table was modified via a different API */
|
|
ptr = null;
|
|
continue;
|
|
}else{
|
|
break;
|
|
}
|
|
}
|
|
if(!ptr){
|
|
ptr = oldLen;
|
|
ft.grow(1);
|
|
}
|
|
try{
|
|
/*this will only work if func is a WASM-exported function*/
|
|
ft.set(ptr, func);
|
|
if(scoped){
|
|
cache.scopedAlloc[cache.scopedAlloc.length-1].push(ptr);
|
|
}
|
|
return ptr;
|
|
}catch(e){
|
|
if(!(e instanceof TypeError)){
|
|
if(ptr===oldLen) cache.freeFuncIndexes.push(oldLen);
|
|
throw e;
|
|
}
|
|
}
|
|
// It's not a WASM-exported function, so compile one...
|
|
try {
|
|
const fptr = target.jsFuncToWasm(func, sig);
|
|
ft.set(ptr, fptr);
|
|
if(scoped){
|
|
cache.scopedAlloc[cache.scopedAlloc.length-1].push(ptr);
|
|
}
|
|
}catch(e){
|
|
if(ptr===oldLen) cache.freeFuncIndexes.push(oldLen);
|
|
throw e;
|
|
}
|
|
return ptr;
|
|
};
|
|
|
|
/**
|
|
Expects a JS function and signature, exactly as for
|
|
this.jsFuncToWasm(). It uses that function to create a
|
|
WASM-exported function, installs that function to the next
|
|
available slot of this.functionTable(), and returns the
|
|
function's index in that table (which acts as a pointer to that
|
|
function). The returned pointer can be passed to
|
|
uninstallFunction() to uninstall it and free up the table slot for
|
|
reuse.
|
|
|
|
If passed (string,function) arguments then it treats the first
|
|
argument as the signature and second as the function.
|
|
|
|
As a special case, if the passed-in function is a WASM-exported
|
|
function then the signature argument is ignored and func is
|
|
installed as-is, without requiring re-compilation/re-wrapping.
|
|
|
|
This function will propagate an exception if
|
|
WebAssembly.Table.grow() throws or this.jsFuncToWasm() throws.
|
|
The former case can happen in an Emscripten-compiled
|
|
environment when building without Emscripten's
|
|
`-sALLOW_TABLE_GROWTH` flag.
|
|
|
|
Sidebar: this function differs from Emscripten's addFunction()
|
|
_primarily_ in that it does not share that function's
|
|
undocumented behavior of reusing a function if it's passed to
|
|
addFunction() more than once, which leads to uninstallFunction()
|
|
breaking clients which do not take care to avoid that case:
|
|
|
|
https://github.com/emscripten-core/emscripten/issues/17323
|
|
*/
|
|
target.installFunction = (func, sig)=>__installFunction(func, sig, false);
|
|
|
|
/**
|
|
Works exactly like installFunction() but requires that a
|
|
scopedAllocPush() is active and uninstalls the given function
|
|
when that alloc scope is popped via scopedAllocPop().
|
|
This is used for implementing JS/WASM function bindings which
|
|
should only persist for the life of a call into a single
|
|
C-side function.
|
|
*/
|
|
target.scopedInstallFunction = (func, sig)=>__installFunction(func, sig, true);
|
|
|
|
/**
|
|
Requires a pointer value previously returned from
|
|
this.installFunction(). Removes that function from the WASM
|
|
function table, marks its table slot as free for re-use, and
|
|
returns that function. It is illegal to call this before
|
|
installFunction() has been called and results are undefined if
|
|
ptr was not returned by that function. The returned function
|
|
may be passed back to installFunction() to reinstall it.
|
|
|
|
To simplify certain use cases, if passed a falsy non-0 value
|
|
(noting that 0 is a valid function table index), this function
|
|
has no side effects and returns undefined.
|
|
*/
|
|
target.uninstallFunction = function(ptr){
|
|
if(!ptr && 0!==ptr) return undefined;
|
|
const fi = cache.freeFuncIndexes;
|
|
const ft = target.functionTable();
|
|
fi.push(ptr);
|
|
const rc = ft.get(ptr);
|
|
ft.set(ptr, null);
|
|
return rc;
|
|
};
|
|
|
|
/**
|
|
Given a WASM heap memory address and a data type name in the form
|
|
(i8, i16, i32, i64, float (or f32), double (or f64)), this
|
|
fetches the numeric value from that address and returns it as a
|
|
number or, for the case of type='i64', a BigInt (noting that that
|
|
type triggers an exception if this.bigIntEnabled is
|
|
falsy). Throws if given an invalid type.
|
|
|
|
If the first argument is an array, it is treated as an array of
|
|
addresses and the result is an array of the values from each of
|
|
those address, using the same 2nd argument for determining the
|
|
value type to fetch.
|
|
|
|
As a special case, if type ends with a `*`, it is considered to
|
|
be a pointer type and is treated as the WASM numeric type
|
|
appropriate for the pointer size (`i32`).
|
|
|
|
While likely not obvious, this routine and its poke()
|
|
counterpart are how pointer-to-value _output_ parameters
|
|
in WASM-compiled C code can be interacted with:
|
|
|
|
```
|
|
const ptr = alloc(4);
|
|
poke(ptr, 0, 'i32'); // clear the ptr's value
|
|
aCFuncWithOutputPtrToInt32Arg( ptr ); // e.g. void foo(int *x);
|
|
const result = peek(ptr, 'i32'); // fetch ptr's value
|
|
dealloc(ptr);
|
|
```
|
|
|
|
scopedAlloc() and friends can be used to make handling of
|
|
`ptr` safe against leaks in the case of an exception:
|
|
|
|
```
|
|
let result;
|
|
const scope = scopedAllocPush();
|
|
try{
|
|
const ptr = scopedAlloc(4);
|
|
poke(ptr, 0, 'i32');
|
|
aCFuncWithOutputPtrArg( ptr );
|
|
result = peek(ptr, 'i32');
|
|
}finally{
|
|
scopedAllocPop(scope);
|
|
}
|
|
```
|
|
|
|
As a rule poke() must be called to set (typically zero
|
|
out) the pointer's value, else it will contain an essentially
|
|
random value.
|
|
|
|
ACHTUNG: calling this often, e.g. in a loop, can have a noticably
|
|
painful impact on performance. Rather than doing so, use
|
|
heapForSize() to fetch the heap object and read directly from it.
|
|
|
|
See: poke()
|
|
*/
|
|
target.peek = function f(ptr, type='i8'){
|
|
if(type.endsWith('*')) type = ptrIR;
|
|
const c = (cache.memory && cache.heapSize === cache.memory.buffer.byteLength)
|
|
? cache : heapWrappers();
|
|
const list = Array.isArray(ptr) ? [] : undefined;
|
|
let rc;
|
|
do{
|
|
if(list) ptr = arguments[0].shift();
|
|
switch(type){
|
|
case 'i1':
|
|
case 'i8': rc = c.HEAP8[ptr>>0]; break;
|
|
case 'i16': rc = c.HEAP16[ptr>>1]; break;
|
|
case 'i32': rc = c.HEAP32[ptr>>2]; break;
|
|
case 'float': case 'f32': rc = c.HEAP32F[ptr>>2]; break;
|
|
case 'double': case 'f64': rc = Number(c.HEAP64F[ptr>>3]); break;
|
|
case 'i64':
|
|
if(target.bigIntEnabled){
|
|
rc = BigInt(c.HEAP64[ptr>>3]);
|
|
break;
|
|
}
|
|
/* fallthru */
|
|
default:
|
|
toss('Invalid type for peek():',type);
|
|
}
|
|
if(list) list.push(rc);
|
|
}while(list && arguments[0].length);
|
|
return list || rc;
|
|
};
|
|
|
|
/**
|
|
The counterpart of peek(), this sets a numeric value at
|
|
the given WASM heap address, using the type to define how many
|
|
bytes are written. Throws if given an invalid type. See
|
|
peek() for details about the type argument. If the 3rd
|
|
argument ends with `*` then it is treated as a pointer type and
|
|
this function behaves as if the 3rd argument were `i32`.
|
|
|
|
If the first argument is an array, it is treated like a list
|
|
of pointers and the given value is written to each one.
|
|
|
|
Returns `this`. (Prior to 2022-12-09 it returns this function.)
|
|
|
|
ACHTUNG: calling this often, e.g. in a loop, can have a noticably
|
|
painful impact on performance. Rather than doing so, use
|
|
heapForSize() to fetch the heap object and assign directly to it
|
|
or use the heap's set() method.
|
|
*/
|
|
target.poke = function(ptr, value, type='i8'){
|
|
if (type.endsWith('*')) type = ptrIR;
|
|
const c = (cache.memory && cache.heapSize === cache.memory.buffer.byteLength)
|
|
? cache : heapWrappers();
|
|
for(const p of (Array.isArray(ptr) ? ptr : [ptr])){
|
|
switch (type) {
|
|
case 'i1':
|
|
case 'i8': c.HEAP8[p>>0] = value; continue;
|
|
case 'i16': c.HEAP16[p>>1] = value; continue;
|
|
case 'i32': c.HEAP32[p>>2] = value; continue;
|
|
case 'float': case 'f32': c.HEAP32F[p>>2] = value; continue;
|
|
case 'double': case 'f64': c.HEAP64F[p>>3] = value; continue;
|
|
case 'i64':
|
|
if(c.HEAP64){
|
|
c.HEAP64[p>>3] = BigInt(value);
|
|
continue;
|
|
}
|
|
/* fallthru */
|
|
default:
|
|
toss('Invalid type for poke(): ' + type);
|
|
}
|
|
}
|
|
return this;
|
|
};
|
|
|
|
/**
|
|
Convenience form of peek() intended for fetching
|
|
pointer-to-pointer values. If passed a single non-array argument
|
|
it returns the value of that one pointer address. If passed
|
|
multiple arguments, or a single array of arguments, it returns an
|
|
array of their values.
|
|
*/
|
|
target.peekPtr = (...ptr)=>target.peek( (1===ptr.length ? ptr[0] : ptr), ptrIR );
|
|
|
|
/**
|
|
A variant of poke() intended for setting pointer-to-pointer
|
|
values. Its differences from poke() are that (1) it defaults to a
|
|
value of 0 and (2) it always writes to the pointer-sized heap
|
|
view.
|
|
*/
|
|
target.pokePtr = (ptr, value=0)=>target.poke(ptr, value, ptrIR);
|
|
|
|
/**
|
|
Convenience form of peek() intended for fetching i8 values. If
|
|
passed a single non-array argument it returns the value of that
|
|
one pointer address. If passed multiple arguments, or a single
|
|
array of arguments, it returns an array of their values.
|
|
*/
|
|
target.peek8 = (...ptr)=>target.peek( (1===ptr.length ? ptr[0] : ptr), 'i8' );
|
|
/**
|
|
Convience form of poke() intended for setting individual bytes.
|
|
Its difference from poke() is that it always writes to the
|
|
i8-sized heap view.
|
|
*/
|
|
target.poke8 = (ptr, value)=>target.poke(ptr, value, 'i8');
|
|
/** i16 variant of peek8(). */
|
|
target.peek16 = (...ptr)=>target.peek( (1===ptr.length ? ptr[0] : ptr), 'i16' );
|
|
/** i16 variant of poke8(). */
|
|
target.poke16 = (ptr, value)=>target.poke(ptr, value, 'i16');
|
|
/** i32 variant of peek8(). */
|
|
target.peek32 = (...ptr)=>target.peek( (1===ptr.length ? ptr[0] : ptr), 'i32' );
|
|
/** i32 variant of poke8(). */
|
|
target.poke32 = (ptr, value)=>target.poke(ptr, value, 'i32');
|
|
/** i64 variant of peek8(). Will throw if this build is not
|
|
configured for BigInt support. */
|
|
target.peek64 = (...ptr)=>target.peek( (1===ptr.length ? ptr[0] : ptr), 'i64' );
|
|
/** i64 variant of poke8(). Will throw if this build is not
|
|
configured for BigInt support. Note that this returns
|
|
a BigInt-type value, not a Number-type value. */
|
|
target.poke64 = (ptr, value)=>target.poke(ptr, value, 'i64');
|
|
/** f32 variant of peek8(). */
|
|
target.peek32f = (...ptr)=>target.peek( (1===ptr.length ? ptr[0] : ptr), 'f32' );
|
|
/** f32 variant of poke8(). */
|
|
target.poke32f = (ptr, value)=>target.poke(ptr, value, 'f32');
|
|
/** f64 variant of peek8(). */
|
|
target.peek64f = (...ptr)=>target.peek( (1===ptr.length ? ptr[0] : ptr), 'f64' );
|
|
/** f64 variant of poke8(). */
|
|
target.poke64f = (ptr, value)=>target.poke(ptr, value, 'f64');
|
|
|
|
/** Deprecated alias for getMemValue() */
|
|
target.getMemValue = target.peek;
|
|
/** Deprecated alias for peekPtr() */
|
|
target.getPtrValue = target.peekPtr;
|
|
/** Deprecated alias for poke() */
|
|
target.setMemValue = target.poke;
|
|
/** Deprecated alias for pokePtr() */
|
|
target.setPtrValue = target.pokePtr;
|
|
|
|
/**
|
|
Returns true if the given value appears to be legal for use as
|
|
a WASM pointer value. Its _range_ of values is not (cannot be)
|
|
validated except to ensure that it is a 32-bit integer with a
|
|
value of 0 or greater. Likewise, it cannot verify whether the
|
|
value actually refers to allocated memory in the WASM heap.
|
|
*/
|
|
target.isPtr32 = (ptr)=>('number'===typeof ptr && (ptr===(ptr|0)) && ptr>=0);
|
|
|
|
/**
|
|
isPtr() is an alias for isPtr32(). If/when 64-bit WASM pointer
|
|
support becomes widespread, it will become an alias for either
|
|
isPtr32() or the as-yet-hypothetical isPtr64(), depending on a
|
|
configuration option.
|
|
*/
|
|
target.isPtr = target.isPtr32;
|
|
|
|
/**
|
|
Expects ptr to be a pointer into the WASM heap memory which
|
|
refers to a NUL-terminated C-style string encoded as UTF-8.
|
|
Returns the length, in bytes, of the string, as for `strlen(3)`.
|
|
As a special case, if !ptr or if it's not a pointer then it
|
|
returns `null`. Throws if ptr is out of range for
|
|
target.heap8u().
|
|
*/
|
|
target.cstrlen = function(ptr){
|
|
if(!ptr || !target.isPtr(ptr)) return null;
|
|
const h = heapWrappers().HEAP8U;
|
|
let pos = ptr;
|
|
for( ; h[pos] !== 0; ++pos ){}
|
|
return pos - ptr;
|
|
};
|
|
|
|
/** Internal helper to use in operations which need to distinguish
|
|
between SharedArrayBuffer heap memory and non-shared heap. */
|
|
const __SAB = ('undefined'===typeof SharedArrayBuffer)
|
|
? function(){} : SharedArrayBuffer;
|
|
const __utf8Decode = function(arrayBuffer, begin, end){
|
|
return cache.utf8Decoder.decode(
|
|
(arrayBuffer.buffer instanceof __SAB)
|
|
? arrayBuffer.slice(begin, end)
|
|
: arrayBuffer.subarray(begin, end)
|
|
);
|
|
};
|
|
|
|
/**
|
|
Expects ptr to be a pointer into the WASM heap memory which
|
|
refers to a NUL-terminated C-style string encoded as UTF-8. This
|
|
function counts its byte length using cstrlen() then returns a
|
|
JS-format string representing its contents. As a special case, if
|
|
ptr is falsy or not a pointer, `null` is returned.
|
|
*/
|
|
target.cstrToJs = function(ptr){
|
|
const n = target.cstrlen(ptr);
|
|
return n ? __utf8Decode(heapWrappers().HEAP8U, ptr, ptr+n) : (null===n ? n : "");
|
|
};
|
|
|
|
/**
|
|
Given a JS string, this function returns its UTF-8 length in
|
|
bytes. Returns null if str is not a string.
|
|
*/
|
|
target.jstrlen = function(str){
|
|
/** Attribution: derived from Emscripten's lengthBytesUTF8() */
|
|
if('string'!==typeof str) return null;
|
|
const n = str.length;
|
|
let len = 0;
|
|
for(let i = 0; i < n; ++i){
|
|
let u = str.charCodeAt(i);
|
|
if(u>=0xd800 && u<=0xdfff){
|
|
u = 0x10000 + ((u & 0x3FF) << 10) | (str.charCodeAt(++i) & 0x3FF);
|
|
}
|
|
if(u<=0x7f) ++len;
|
|
else if(u<=0x7ff) len += 2;
|
|
else if(u<=0xffff) len += 3;
|
|
else len += 4;
|
|
}
|
|
return len;
|
|
};
|
|
|
|
/**
|
|
Encodes the given JS string as UTF8 into the given TypedArray
|
|
tgt, starting at the given offset and writing, at most, maxBytes
|
|
bytes (including the NUL terminator if addNul is true, else no
|
|
NUL is added). If it writes any bytes at all and addNul is true,
|
|
it always NUL-terminates the output, even if doing so means that
|
|
the NUL byte is all that it writes.
|
|
|
|
If maxBytes is negative (the default) then it is treated as the
|
|
remaining length of tgt, starting at the given offset.
|
|
|
|
If writing the last character would surpass the maxBytes count
|
|
because the character is multi-byte, that character will not be
|
|
written (as opposed to writing a truncated multi-byte character).
|
|
This can lead to it writing as many as 3 fewer bytes than
|
|
maxBytes specifies.
|
|
|
|
Returns the number of bytes written to the target, _including_
|
|
the NUL terminator (if any). If it returns 0, it wrote nothing at
|
|
all, which can happen if:
|
|
|
|
- str is empty and addNul is false.
|
|
- offset < 0.
|
|
- maxBytes == 0.
|
|
- maxBytes is less than the byte length of a multi-byte str[0].
|
|
|
|
Throws if tgt is not an Int8Array or Uint8Array.
|
|
|
|
Design notes:
|
|
|
|
- In C's strcpy(), the destination pointer is the first
|
|
argument. That is not the case here primarily because the 3rd+
|
|
arguments are all referring to the destination, so it seems to
|
|
make sense to have them grouped with it.
|
|
|
|
- Emscripten's counterpart of this function (stringToUTF8Array())
|
|
returns the number of bytes written sans NUL terminator. That
|
|
is, however, ambiguous: str.length===0 or maxBytes===(0 or 1)
|
|
all cause 0 to be returned.
|
|
*/
|
|
target.jstrcpy = function(jstr, tgt, offset = 0, maxBytes = -1, addNul = true){
|
|
/** Attribution: the encoding bits are taken from Emscripten's
|
|
stringToUTF8Array(). */
|
|
if(!tgt || (!(tgt instanceof Int8Array) && !(tgt instanceof Uint8Array))){
|
|
toss("jstrcpy() target must be an Int8Array or Uint8Array.");
|
|
}
|
|
if(maxBytes<0) maxBytes = tgt.length - offset;
|
|
if(!(maxBytes>0) || !(offset>=0)) return 0;
|
|
let i = 0, max = jstr.length;
|
|
const begin = offset, end = offset + maxBytes - (addNul ? 1 : 0);
|
|
for(; i < max && offset < end; ++i){
|
|
let u = jstr.charCodeAt(i);
|
|
if(u>=0xd800 && u<=0xdfff){
|
|
u = 0x10000 + ((u & 0x3FF) << 10) | (jstr.charCodeAt(++i) & 0x3FF);
|
|
}
|
|
if(u<=0x7f){
|
|
if(offset >= end) break;
|
|
tgt[offset++] = u;
|
|
}else if(u<=0x7ff){
|
|
if(offset + 1 >= end) break;
|
|
tgt[offset++] = 0xC0 | (u >> 6);
|
|
tgt[offset++] = 0x80 | (u & 0x3f);
|
|
}else if(u<=0xffff){
|
|
if(offset + 2 >= end) break;
|
|
tgt[offset++] = 0xe0 | (u >> 12);
|
|
tgt[offset++] = 0x80 | ((u >> 6) & 0x3f);
|
|
tgt[offset++] = 0x80 | (u & 0x3f);
|
|
}else{
|
|
if(offset + 3 >= end) break;
|
|
tgt[offset++] = 0xf0 | (u >> 18);
|
|
tgt[offset++] = 0x80 | ((u >> 12) & 0x3f);
|
|
tgt[offset++] = 0x80 | ((u >> 6) & 0x3f);
|
|
tgt[offset++] = 0x80 | (u & 0x3f);
|
|
}
|
|
}
|
|
if(addNul) tgt[offset++] = 0;
|
|
return offset - begin;
|
|
};
|
|
|
|
/**
|
|
Works similarly to C's strncpy(), copying, at most, n bytes (not
|
|
characters) from srcPtr to tgtPtr. It copies until n bytes have
|
|
been copied or a 0 byte is reached in src. _Unlike_ strncpy(), it
|
|
returns the number of bytes it assigns in tgtPtr, _including_ the
|
|
NUL byte (if any). If n is reached before a NUL byte in srcPtr,
|
|
tgtPtr will _not_ be NULL-terminated. If a NUL byte is reached
|
|
before n bytes are copied, tgtPtr will be NUL-terminated.
|
|
|
|
If n is negative, cstrlen(srcPtr)+1 is used to calculate it, the
|
|
+1 being for the NUL byte.
|
|
|
|
Throws if tgtPtr or srcPtr are falsy. Results are undefined if:
|
|
|
|
- either is not a pointer into the WASM heap or
|
|
|
|
- srcPtr is not NUL-terminated AND n is less than srcPtr's
|
|
logical length.
|
|
|
|
ACHTUNG: it is possible to copy partial multi-byte characters
|
|
this way, and converting such strings back to JS strings will
|
|
have undefined results.
|
|
*/
|
|
target.cstrncpy = function(tgtPtr, srcPtr, n){
|
|
if(!tgtPtr || !srcPtr) toss("cstrncpy() does not accept NULL strings.");
|
|
if(n<0) n = target.cstrlen(strPtr)+1;
|
|
else if(!(n>0)) return 0;
|
|
const heap = target.heap8u();
|
|
let i = 0, ch;
|
|
for(; i < n && (ch = heap[srcPtr+i]); ++i){
|
|
heap[tgtPtr+i] = ch;
|
|
}
|
|
if(i<n) heap[tgtPtr + i++] = 0;
|
|
return i;
|
|
};
|
|
|
|
/**
|
|
For the given JS string, returns a Uint8Array of its contents
|
|
encoded as UTF-8. If addNul is true, the returned array will have
|
|
a trailing 0 entry, else it will not.
|
|
*/
|
|
target.jstrToUintArray = (str, addNul=false)=>{
|
|
return cache.utf8Encoder.encode(addNul ? (str+"\0") : str);
|
|
// Or the hard way...
|
|
/** Attribution: derived from Emscripten's stringToUTF8Array() */
|
|
//const a = [], max = str.length;
|
|
//let i = 0, pos = 0;
|
|
//for(; i < max; ++i){
|
|
// let u = str.charCodeAt(i);
|
|
// if(u>=0xd800 && u<=0xdfff){
|
|
// u = 0x10000 + ((u & 0x3FF) << 10) | (str.charCodeAt(++i) & 0x3FF);
|
|
// }
|
|
// if(u<=0x7f) a[pos++] = u;
|
|
// else if(u<=0x7ff){
|
|
// a[pos++] = 0xC0 | (u >> 6);
|
|
// a[pos++] = 0x80 | (u & 63);
|
|
// }else if(u<=0xffff){
|
|
// a[pos++] = 0xe0 | (u >> 12);
|
|
// a[pos++] = 0x80 | ((u >> 6) & 63);
|
|
// a[pos++] = 0x80 | (u & 63);
|
|
// }else{
|
|
// a[pos++] = 0xf0 | (u >> 18);
|
|
// a[pos++] = 0x80 | ((u >> 12) & 63);
|
|
// a[pos++] = 0x80 | ((u >> 6) & 63);
|
|
// a[pos++] = 0x80 | (u & 63);
|
|
// }
|
|
// }
|
|
// return new Uint8Array(a);
|
|
};
|
|
|
|
const __affirmAlloc = (obj,funcName)=>{
|
|
if(!(obj.alloc instanceof Function) ||
|
|
!(obj.dealloc instanceof Function)){
|
|
toss("Object is missing alloc() and/or dealloc() function(s)",
|
|
"required by",funcName+"().");
|
|
}
|
|
};
|
|
|
|
const __allocCStr = function(jstr, returnWithLength, allocator, funcName){
|
|
__affirmAlloc(target, funcName);
|
|
if('string'!==typeof jstr) return null;
|
|
if(0){/* older impl, possibly more widely compatible? */
|
|
const n = target.jstrlen(jstr),
|
|
ptr = allocator(n+1);
|
|
target.jstrcpy(jstr, target.heap8u(), ptr, n+1, true);
|
|
return returnWithLength ? [ptr, n] : ptr;
|
|
}else{/* newer, (probably) faster and (certainly) simpler impl */
|
|
const u = cache.utf8Encoder.encode(jstr),
|
|
ptr = allocator(u.length+1),
|
|
heap = heapWrappers().HEAP8U;
|
|
heap.set(u, ptr);
|
|
heap[ptr + u.length] = 0;
|
|
return returnWithLength ? [ptr, u.length] : ptr;
|
|
}
|
|
};
|
|
|
|
/**
|
|
Uses target.alloc() to allocate enough memory for jstrlen(jstr)+1
|
|
bytes of memory, copies jstr to that memory using jstrcpy(),
|
|
NUL-terminates it, and returns the pointer to that C-string.
|
|
Ownership of the pointer is transfered to the caller, who must
|
|
eventually pass the pointer to dealloc() to free it.
|
|
|
|
If passed a truthy 2nd argument then its return semantics change:
|
|
it returns [ptr,n], where ptr is the C-string's pointer and n is
|
|
its cstrlen().
|
|
|
|
Throws if `target.alloc` or `target.dealloc` are not functions.
|
|
*/
|
|
target.allocCString =
|
|
(jstr, returnWithLength=false)=>__allocCStr(jstr, returnWithLength,
|
|
target.alloc, 'allocCString()');
|
|
|
|
/**
|
|
Starts an "allocation scope." All allocations made using
|
|
scopedAlloc() are recorded in this scope and are freed when the
|
|
value returned from this function is passed to
|
|
scopedAllocPop().
|
|
|
|
This family of functions requires that the API's object have both
|
|
`alloc()` and `dealloc()` methods, else this function will throw.
|
|
|
|
Intended usage:
|
|
|
|
```
|
|
const scope = scopedAllocPush();
|
|
try {
|
|
const ptr1 = scopedAlloc(100);
|
|
const ptr2 = scopedAlloc(200);
|
|
const ptr3 = scopedAlloc(300);
|
|
...
|
|
// Note that only allocations made via scopedAlloc()
|
|
// are managed by this allocation scope.
|
|
}finally{
|
|
scopedAllocPop(scope);
|
|
}
|
|
```
|
|
|
|
The value returned by this function must be treated as opaque by
|
|
the caller, suitable _only_ for passing to scopedAllocPop().
|
|
Its type and value are not part of this function's API and may
|
|
change in any given version of this code.
|
|
|
|
`scopedAlloc.level` can be used to determine how many scoped
|
|
alloc levels are currently active.
|
|
*/
|
|
target.scopedAllocPush = function(){
|
|
__affirmAlloc(target, 'scopedAllocPush');
|
|
const a = [];
|
|
cache.scopedAlloc.push(a);
|
|
return a;
|
|
};
|
|
|
|
/**
|
|
Cleans up all allocations made using scopedAlloc() in the context
|
|
of the given opaque state object, which must be a value returned
|
|
by scopedAllocPush(). See that function for an example of how to
|
|
use this function.
|
|
|
|
Though scoped allocations are managed like a stack, this API
|
|
behaves properly if allocation scopes are popped in an order
|
|
other than the order they were pushed.
|
|
|
|
If called with no arguments, it pops the most recent
|
|
scopedAllocPush() result:
|
|
|
|
```
|
|
scopedAllocPush();
|
|
try{ ... } finally { scopedAllocPop(); }
|
|
```
|
|
|
|
It's generally recommended that it be passed an explicit argument
|
|
to help ensure that push/push are used in matching pairs, but in
|
|
trivial code that may be a non-issue.
|
|
*/
|
|
target.scopedAllocPop = function(state){
|
|
__affirmAlloc(target, 'scopedAllocPop');
|
|
const n = arguments.length
|
|
? cache.scopedAlloc.indexOf(state)
|
|
: cache.scopedAlloc.length-1;
|
|
if(n<0) toss("Invalid state object for scopedAllocPop().");
|
|
if(0===arguments.length) state = cache.scopedAlloc[n];
|
|
cache.scopedAlloc.splice(n,1);
|
|
for(let p; (p = state.pop()); ){
|
|
if(target.functionEntry(p)){
|
|
//console.warn("scopedAllocPop() uninstalling function",p);
|
|
target.uninstallFunction(p);
|
|
}
|
|
else target.dealloc(p);
|
|
}
|
|
};
|
|
|
|
/**
|
|
Allocates n bytes of memory using this.alloc() and records that
|
|
fact in the state for the most recent call of scopedAllocPush().
|
|
Ownership of the memory is given to scopedAllocPop(), which
|
|
will clean it up when it is called. The memory _must not_ be
|
|
passed to this.dealloc(). Throws if this API object is missing
|
|
the required `alloc()` or `dealloc()` functions or no scoped
|
|
alloc is active.
|
|
|
|
See scopedAllocPush() for an example of how to use this function.
|
|
|
|
The `level` property of this function can be queried to query how
|
|
many scoped allocation levels are currently active.
|
|
|
|
See also: scopedAllocPtr(), scopedAllocCString()
|
|
*/
|
|
target.scopedAlloc = function(n){
|
|
if(!cache.scopedAlloc.length){
|
|
toss("No scopedAllocPush() scope is active.");
|
|
}
|
|
const p = target.alloc(n);
|
|
cache.scopedAlloc[cache.scopedAlloc.length-1].push(p);
|
|
return p;
|
|
};
|
|
|
|
Object.defineProperty(target.scopedAlloc, 'level', {
|
|
configurable: false, enumerable: false,
|
|
get: ()=>cache.scopedAlloc.length,
|
|
set: ()=>toss("The 'active' property is read-only.")
|
|
});
|
|
|
|
/**
|
|
Works identically to allocCString() except that it allocates the
|
|
memory using scopedAlloc().
|
|
|
|
Will throw if no scopedAllocPush() call is active.
|
|
*/
|
|
target.scopedAllocCString =
|
|
(jstr, returnWithLength=false)=>__allocCStr(jstr, returnWithLength,
|
|
target.scopedAlloc, 'scopedAllocCString()');
|
|
|
|
// impl for allocMainArgv() and scopedAllocMainArgv().
|
|
const __allocMainArgv = function(isScoped, list){
|
|
const pList = target[
|
|
isScoped ? 'scopedAlloc' : 'alloc'
|
|
]((list.length + 1) * target.ptrSizeof);
|
|
let i = 0;
|
|
list.forEach((e)=>{
|
|
target.pokePtr(pList + (target.ptrSizeof * i++),
|
|
target[
|
|
isScoped ? 'scopedAllocCString' : 'allocCString'
|
|
](""+e));
|
|
});
|
|
target.pokePtr(pList + (target.ptrSizeof * i), 0);
|
|
return pList;
|
|
};
|
|
|
|
/**
|
|
Creates an array, using scopedAlloc(), suitable for passing to a
|
|
C-level main() routine. The input is a collection with a length
|
|
property and a forEach() method. A block of memory
|
|
(list.length+1) entries long is allocated and each pointer-sized
|
|
block of that memory is populated with a scopedAllocCString()
|
|
conversion of the (""+value) of each element, with the exception
|
|
that the final entry is a NULL pointer. Returns a pointer to the
|
|
start of the list, suitable for passing as the 2nd argument to a
|
|
C-style main() function.
|
|
|
|
Throws if scopedAllocPush() is not active.
|
|
|
|
Design note: the returned array is allocated with an extra NULL
|
|
pointer entry to accommodate certain APIs, but client code which
|
|
does not need that functionality should treat the returned array
|
|
as list.length entries long.
|
|
*/
|
|
target.scopedAllocMainArgv = (list)=>__allocMainArgv(true, list);
|
|
|
|
/**
|
|
Identical to scopedAllocMainArgv() but uses alloc() instead of
|
|
scopedAlloc().
|
|
*/
|
|
target.allocMainArgv = (list)=>__allocMainArgv(false, list);
|
|
|
|
/**
|
|
Expects to be given a C-style string array and its length. It
|
|
returns a JS array of strings and/or nulls: any entry in the
|
|
pArgv array which is NULL results in a null entry in the result
|
|
array. If argc is 0 then an empty array is returned.
|
|
|
|
Results are undefined if any entry in the first argc entries of
|
|
pArgv are neither 0 (NULL) nor legal UTF-format C strings.
|
|
|
|
To be clear, the expected C-style arguments to be passed to this
|
|
function are `(int, char **)` (optionally const-qualified).
|
|
*/
|
|
target.cArgvToJs = (argc, pArgv)=>{
|
|
const list = [];
|
|
for(let i = 0; i < argc; ++i){
|
|
const arg = target.peekPtr(pArgv + (target.ptrSizeof * i));
|
|
list.push( arg ? target.cstrToJs(arg) : null );
|
|
}
|
|
return list;
|
|
};
|
|
|
|
/**
|
|
Wraps function call func() in a scopedAllocPush() and
|
|
scopedAllocPop() block, such that all calls to scopedAlloc() and
|
|
friends from within that call will have their memory freed
|
|
automatically when func() returns. If func throws or propagates
|
|
an exception, the scope is still popped, otherwise it returns the
|
|
result of calling func().
|
|
*/
|
|
target.scopedAllocCall = function(func){
|
|
target.scopedAllocPush();
|
|
try{ return func() } finally{ target.scopedAllocPop() }
|
|
};
|
|
|
|
/** Internal impl for allocPtr() and scopedAllocPtr(). */
|
|
const __allocPtr = function(howMany, safePtrSize, method){
|
|
__affirmAlloc(target, method);
|
|
const pIr = safePtrSize ? 'i64' : ptrIR;
|
|
let m = target[method](howMany * (safePtrSize ? 8 : ptrSizeof));
|
|
target.poke(m, 0, pIr)
|
|
if(1===howMany){
|
|
return m;
|
|
}
|
|
const a = [m];
|
|
for(let i = 1; i < howMany; ++i){
|
|
m += (safePtrSize ? 8 : ptrSizeof);
|
|
a[i] = m;
|
|
target.poke(m, 0, pIr);
|
|
}
|
|
return a;
|
|
};
|
|
|
|
/**
|
|
Allocates one or more pointers as a single chunk of memory and
|
|
zeroes them out.
|
|
|
|
The first argument is the number of pointers to allocate. The
|
|
second specifies whether they should use a "safe" pointer size (8
|
|
bytes) or whether they may use the default pointer size
|
|
(typically 4 but also possibly 8).
|
|
|
|
How the result is returned depends on its first argument: if
|
|
passed 1, it returns the allocated memory address. If passed more
|
|
than one then an array of pointer addresses is returned, which
|
|
can optionally be used with "destructuring assignment" like this:
|
|
|
|
```
|
|
const [p1, p2, p3] = allocPtr(3);
|
|
```
|
|
|
|
ACHTUNG: when freeing the memory, pass only the _first_ result
|
|
value to dealloc(). The others are part of the same memory chunk
|
|
and must not be freed separately.
|
|
|
|
The reason for the 2nd argument is..
|
|
|
|
When one of the returned pointers will refer to a 64-bit value,
|
|
e.g. a double or int64, an that value must be written or fetched,
|
|
e.g. using poke() or peek(), it is important that
|
|
the pointer in question be aligned to an 8-byte boundary or else
|
|
it will not be fetched or written properly and will corrupt or
|
|
read neighboring memory. It is only safe to pass false when the
|
|
client code is certain that it will only get/fetch 4-byte values
|
|
(or smaller).
|
|
*/
|
|
target.allocPtr =
|
|
(howMany=1, safePtrSize=true)=>__allocPtr(howMany, safePtrSize, 'alloc');
|
|
|
|
/**
|
|
Identical to allocPtr() except that it allocates using scopedAlloc()
|
|
instead of alloc().
|
|
*/
|
|
target.scopedAllocPtr =
|
|
(howMany=1, safePtrSize=true)=>__allocPtr(howMany, safePtrSize, 'scopedAlloc');
|
|
|
|
/**
|
|
If target.exports[name] exists, it is returned, else an
|
|
exception is thrown.
|
|
*/
|
|
target.xGet = function(name){
|
|
return target.exports[name] || toss("Cannot find exported symbol:",name);
|
|
};
|
|
|
|
const __argcMismatch =
|
|
(f,n)=>toss(f+"() requires",n,"argument(s).");
|
|
|
|
/**
|
|
Looks up a WASM-exported function named fname from
|
|
target.exports. If found, it is called, passed all remaining
|
|
arguments, and its return value is returned to xCall's caller. If
|
|
not found, an exception is thrown. This function does no
|
|
conversion of argument or return types, but see xWrap() and
|
|
xCallWrapped() for variants which do.
|
|
|
|
As a special case, if passed only 1 argument after the name and
|
|
that argument in an Array, that array's entries become the
|
|
function arguments. (This is not an ambiguous case because it's
|
|
not legal to pass an Array object to a WASM function.)
|
|
*/
|
|
target.xCall = function(fname, ...args){
|
|
const f = target.xGet(fname);
|
|
if(!(f instanceof Function)) toss("Exported symbol",fname,"is not a function.");
|
|
if(f.length!==args.length) __argcMismatch(fname,f.length)
|
|
/* This is arguably over-pedantic but we want to help clients keep
|
|
from shooting themselves in the foot when calling C APIs. */;
|
|
return (2===arguments.length && Array.isArray(arguments[1]))
|
|
? f.apply(null, arguments[1])
|
|
: f.apply(null, args);
|
|
};
|
|
|
|
/**
|
|
State for use with xWrap()
|
|
*/
|
|
cache.xWrap = Object.create(null);
|
|
cache.xWrap.convert = Object.create(null);
|
|
/** Map of type names to argument conversion functions. */
|
|
cache.xWrap.convert.arg = new Map;
|
|
/** Map of type names to return result conversion functions. */
|
|
cache.xWrap.convert.result = new Map;
|
|
const xArg = cache.xWrap.convert.arg, xResult = cache.xWrap.convert.result;
|
|
|
|
if(target.bigIntEnabled){
|
|
xArg.set('i64', (i)=>BigInt(i));
|
|
}
|
|
const __xArgPtr = 'i32' === ptrIR
|
|
? ((i)=>(i | 0)) : ((i)=>(BigInt(i) | BigInt(0)));
|
|
xArg.set('i32', __xArgPtr )
|
|
.set('i16', (i)=>((i | 0) & 0xFFFF))
|
|
.set('i8', (i)=>((i | 0) & 0xFF))
|
|
.set('f32', (i)=>Number(i).valueOf())
|
|
.set('float', xArg.get('f32'))
|
|
.set('f64', xArg.get('f32'))
|
|
.set('double', xArg.get('f64'))
|
|
.set('int', xArg.get('i32'))
|
|
.set('null', (i)=>i)
|
|
.set(null, xArg.get('null'))
|
|
.set('**', __xArgPtr)
|
|
.set('*', __xArgPtr);
|
|
xResult.set('*', __xArgPtr)
|
|
.set('pointer', __xArgPtr)
|
|
.set('number', (v)=>Number(v))
|
|
.set('void', (v)=>undefined)
|
|
.set('null', (v)=>v)
|
|
.set(null, xResult.get('null'));
|
|
|
|
{ /* Copy certain xArg[...] handlers to xResult[...] and
|
|
add pointer-style variants of them. */
|
|
const copyToResult = ['i8', 'i16', 'i32', 'int',
|
|
'f32', 'float', 'f64', 'double'];
|
|
if(target.bigIntEnabled) copyToResult.push('i64');
|
|
const adaptPtr = xArg.get(ptrIR);
|
|
for(const t of copyToResult){
|
|
xArg.set(t+'*', adaptPtr);
|
|
xResult.set(t+'*', adaptPtr);
|
|
xResult.set(t, (xArg.get(t) || toss("Missing arg converter:",t)));
|
|
}
|
|
}
|
|
|
|
/**
|
|
In order for args of type string to work in various contexts in
|
|
the sqlite3 API, we need to pass them on as, variably, a C-string
|
|
or a pointer value. Thus for ARGs of type 'string' and
|
|
'*'/'pointer' we behave differently depending on whether the
|
|
argument is a string or not:
|
|
|
|
- If v is a string, scopeAlloc() a new C-string from it and return
|
|
that temp string's pointer.
|
|
|
|
- Else return the value from the arg adapter defined for ptrIR.
|
|
|
|
TODO? Permit an Int8Array/Uint8Array and convert it to a string?
|
|
Would that be too much magic concentrated in one place, ready to
|
|
backfire? We handle that at the client level in sqlite3 with a
|
|
custom argument converter.
|
|
*/
|
|
const __xArgString = function(v){
|
|
if('string'===typeof v) return target.scopedAllocCString(v);
|
|
return v ? __xArgPtr(v) : null;
|
|
};
|
|
xArg.set('string', __xArgString)
|
|
.set('utf8', __xArgString)
|
|
.set('pointer', __xArgString);
|
|
//xArg.set('*', __xArgString);
|
|
|
|
xResult.set('string', (i)=>target.cstrToJs(i))
|
|
.set('utf8', xResult.get('string'))
|
|
.set('string:dealloc', (i)=>{
|
|
try { return i ? target.cstrToJs(i) : null }
|
|
finally{ target.dealloc(i) }
|
|
})
|
|
.set('utf8:dealloc', xResult.get('string:dealloc'))
|
|
.set('json', (i)=>JSON.parse(target.cstrToJs(i)))
|
|
.set('json:dealloc', (i)=>{
|
|
try{ return i ? JSON.parse(target.cstrToJs(i)) : null }
|
|
finally{ target.dealloc(i) }
|
|
});
|
|
|
|
/**
|
|
Internal-use-only base class for FuncPtrAdapter and potentially
|
|
additional stateful argument adapter classes.
|
|
|
|
Note that its main interface (convertArg()) is strictly
|
|
internal, not to be exposed to client code, as it may still
|
|
need re-shaping. Only the constructors of concrete subclasses
|
|
should be exposed to clients, and those in such a way that
|
|
does not hinder internal redesign of the convertArg()
|
|
interface.
|
|
*/
|
|
const AbstractArgAdapter = class {
|
|
constructor(opt){
|
|
this.name = opt.name || 'unnamed adapter';
|
|
}
|
|
/**
|
|
Gets called via xWrap() to "convert" v to whatever type
|
|
this specific class supports.
|
|
|
|
argIndex is the argv index of _this_ argument in the
|
|
being-xWrap()'d call. argv is the current argument list
|
|
undergoing xWrap() argument conversion. argv entries to the
|
|
left of argIndex will have already undergone transformation and
|
|
those to the right will not have (they will have the values the
|
|
client-level code passed in, awaiting conversion). The RHS
|
|
indexes must never be relied upon for anything because their
|
|
types are indeterminate, whereas the LHS values will be
|
|
WASM-compatible values by the time this is called.
|
|
*/
|
|
convertArg(v,argv,argIndex){
|
|
toss("AbstractArgAdapter must be subclassed.");
|
|
}
|
|
};
|
|
|
|
/**
|
|
An attempt at adding function pointer conversion support to
|
|
xWrap(). This type is recognized by xWrap() as a proxy for
|
|
converting a JS function to a C-side function, either
|
|
permanently, for the duration of a single call into the C layer,
|
|
or semi-contextual, where it may keep track of a single binding
|
|
for a given context and uninstall the binding if it's replaced.
|
|
|
|
The constructor requires an options object with these properties:
|
|
|
|
- name (optional): string describing the function binding. This
|
|
is solely for debugging and error-reporting purposes. If not
|
|
provided, an empty string is assumed.
|
|
|
|
- signature: a function signature string compatible with
|
|
jsFuncToWasm().
|
|
|
|
- bindScope (string): one of ('transient', 'context',
|
|
'singleton'). Bind scopes are:
|
|
|
|
- 'transient': it will convert JS functions to WASM only for
|
|
the duration of the xWrap()'d function call, using
|
|
scopedInstallFunction(). Before that call returns, the
|
|
WASM-side binding will be uninstalled.
|
|
|
|
- 'singleton': holds one function-pointer binding for this
|
|
instance. If it's called with a different function pointer,
|
|
it uninstalls the previous one after converting the new
|
|
value. This is only useful for use with "global" functions
|
|
which do not rely on any state other than this function
|
|
pointer. If the being-converted function pointer is intended
|
|
to be mapped to some sort of state object (e.g. an
|
|
`sqlite3*`) then "context" (see below) is the proper mode.
|
|
|
|
- 'context': similar to singleton mode but for a given
|
|
"context", where the context is a key provided by the user
|
|
and possibly dependent on a small amount of call-time
|
|
context. This mode is the default if bindScope is _not_ set
|
|
but a property named contextKey (described below) is.
|
|
|
|
- 'permanent': the function is installed and left there
|
|
forever. There is no way to recover its pointer address
|
|
later on.
|
|
|
|
- callProxy (function): if set, this must be a function which
|
|
will act as a proxy for any "converted" JS function. It is
|
|
passed the being-converted function value and must return
|
|
either that function or a function which acts on its
|
|
behalf. The returned function will be the one which gets
|
|
installed into the WASM function table. The proxy must perform
|
|
any required argument conversion (noting that it will be called
|
|
from C code, so will receive C-format arguments) before passing
|
|
them on to the being-converted function. Whether or not the
|
|
proxy itself must return a value depends on the context. If it
|
|
does, it must be a WASM-friendly value, as it will be returning
|
|
from a call made from native code.
|
|
|
|
- contextKey (function): is only used if bindScope is 'context'
|
|
or if bindScope is not set and this function is, in which case
|
|
'context' is assumed. This function gets bound to this object,
|
|
so its "this" is this object. It gets passed (argv,argIndex),
|
|
where argIndex is the index of _this_ function pointer in its
|
|
_wrapping_ function's arguments and argv is the _current_
|
|
still-being-xWrap()-processed args array. All arguments to the
|
|
left of argIndex will have been processed by xWrap() by the
|
|
time this is called. argv[argIndex] will be the value the user
|
|
passed in to the xWrap()'d function for the argument this
|
|
FuncPtrAdapter is mapped to. Arguments to the right of
|
|
argv[argIndex] will not yet have been converted before this is
|
|
called. The function must return a key which uniquely
|
|
identifies this function mapping context for _this_
|
|
FuncPtrAdapter instance (other instances are not considered),
|
|
taking into account that C functions often take some sort of
|
|
state object as one or more of their arguments. As an example,
|
|
if the xWrap()'d function takes `(int,T*,functionPtr,X*)` and
|
|
this FuncPtrAdapter is the argv[2]nd arg, contextKey(argv,2)
|
|
might return 'T@'+argv[1], or even just argv[1]. Note,
|
|
however, that the (X*) argument will not yet have been
|
|
processed by the time this is called and should not be used as
|
|
part of that key because its pre-conversion data type might be
|
|
unpredictable. Similarly, care must be taken with C-string-type
|
|
arguments: those to the left in argv will, when this is called,
|
|
be WASM pointers, whereas those to the right might (and likely
|
|
do) have another data type. When using C-strings in keys, never
|
|
use their pointers in the key because most C-strings in this
|
|
constellation are transient.
|
|
|
|
Yes, that ^^^ is quite awkward, but it's what we have.
|
|
|
|
The constructor only saves the above state for later, and does
|
|
not actually bind any functions. Its convertArg() method is
|
|
called via xWrap() to perform any bindings.
|
|
|
|
Shortcomings:
|
|
|
|
- These "reverse" bindings, i.e. calling into a JS-defined
|
|
function from a WASM-defined function (the generated proxy
|
|
wrapper), lack all type conversion support. That means, for
|
|
example, that...
|
|
|
|
- Function pointers which include C-string arguments may still
|
|
need a level of hand-written wrappers around them, depending on
|
|
how they're used, in order to provide the client with JS
|
|
strings. Alternately, clients will need to perform such conversions
|
|
on their own, e.g. using cstrtojs(). Or maybe we can find a way
|
|
to perform such conversions here, via addition of an xWrap()-style
|
|
function signature to the options argument.
|
|
*/
|
|
xArg.FuncPtrAdapter = class FuncPtrAdapter extends AbstractArgAdapter {
|
|
constructor(opt) {
|
|
super(opt);
|
|
if(xArg.FuncPtrAdapter.warnOnUse){
|
|
console.warn('xArg.FuncPtrAdapter is an internal-only API',
|
|
'and is not intended to be invoked from',
|
|
'client-level code. Invoked with:',opt);
|
|
}
|
|
this.name = opt.name || "unnamed";
|
|
this.signature = opt.signature;
|
|
if(opt.contextKey instanceof Function){
|
|
this.contextKey = opt.contextKey;
|
|
if(!opt.bindScope) opt.bindScope = 'context';
|
|
}
|
|
this.bindScope = opt.bindScope
|
|
|| toss("FuncPtrAdapter options requires a bindScope (explicit or implied).");
|
|
if(FuncPtrAdapter.bindScopes.indexOf(opt.bindScope)<0){
|
|
toss("Invalid options.bindScope ("+opt.bindMod+") for FuncPtrAdapter. "+
|
|
"Expecting one of: ("+FuncPtrAdapter.bindScopes.join(', ')+')');
|
|
}
|
|
this.isTransient = 'transient'===this.bindScope;
|
|
this.isContext = 'context'===this.bindScope;
|
|
this.isPermanent = 'permanent'===this.bindScope;
|
|
this.singleton = ('singleton'===this.bindScope) ? [] : undefined;
|
|
//console.warn("FuncPtrAdapter()",opt,this);
|
|
this.callProxy = (opt.callProxy instanceof Function)
|
|
? opt.callProxy : undefined;
|
|
}
|
|
|
|
/**
|
|
Note that static class members are defined outside of the class
|
|
to work around an emcc toolchain build problem: one of the
|
|
tools in emsdk v3.1.42 does not support the static keyword.
|
|
*/
|
|
|
|
/* Dummy impl. Overwritten per-instance as needed. */
|
|
contextKey(argv,argIndex){
|
|
return this;
|
|
}
|
|
|
|
/* Returns this objects mapping for the given context key, in the
|
|
form of an an array, creating the mapping if needed. The key
|
|
may be anything suitable for use in a Map. */
|
|
contextMap(key){
|
|
const cm = (this.__cmap || (this.__cmap = new Map));
|
|
let rc = cm.get(key);
|
|
if(undefined===rc) cm.set(key, (rc = []));
|
|
return rc;
|
|
}
|
|
|
|
/**
|
|
Gets called via xWrap() to "convert" v to a WASM-bound function
|
|
pointer. If v is one of (a pointer, null, undefined) then
|
|
(v||0) is returned and any earlier function installed by this
|
|
mapping _might_, depending on how it's bound, be uninstalled.
|
|
If v is not one of those types, it must be a Function, for
|
|
which it creates (if needed) a WASM function binding and
|
|
returns the WASM pointer to that binding. If this instance is
|
|
not in 'transient' mode, it will remember the binding for at
|
|
least the next call, to avoid recreating the function binding
|
|
unnecessarily.
|
|
|
|
If it's passed a pointer(ish) value for v, it does _not_
|
|
perform any function binding, so this object's bindMode is
|
|
irrelevant for such cases.
|
|
|
|
See the parent class's convertArg() docs for details on what
|
|
exactly the 2nd and 3rd arguments are.
|
|
*/
|
|
convertArg(v,argv,argIndex){
|
|
//FuncPtrAdapter.debugOut("FuncPtrAdapter.convertArg()",this.name,this.signature,this.transient,v);
|
|
let pair = this.singleton;
|
|
if(!pair && this.isContext){
|
|
pair = this.contextMap(this.contextKey(argv,argIndex));
|
|
//FuncPtrAdapter.debugOut(this.name, this.signature, "contextKey() =",this.contextKey(argv,argIndex), pair);
|
|
}
|
|
if(pair && pair[0]===v) return pair[1];
|
|
if(v instanceof Function){
|
|
/* Install a WASM binding and return its pointer. */
|
|
//FuncPtrAdapter.debugOut("FuncPtrAdapter.convertArg()",this.name,this.signature,this.transient,v,pair);
|
|
if(this.callProxy) v = this.callProxy(v);
|
|
const fp = __installFunction(v, this.signature, this.isTransient);
|
|
if(FuncPtrAdapter.debugFuncInstall){
|
|
FuncPtrAdapter.debugOut("FuncPtrAdapter installed", this,
|
|
this.contextKey(argv,argIndex), '@'+fp, v);
|
|
}
|
|
if(pair){
|
|
/* Replace existing stashed mapping */
|
|
if(pair[1]){
|
|
if(FuncPtrAdapter.debugFuncInstall){
|
|
FuncPtrAdapter.debugOut("FuncPtrAdapter uninstalling", this,
|
|
this.contextKey(argv,argIndex), '@'+pair[1], v);
|
|
}
|
|
try{
|
|
/* Because the pending native call might rely on the
|
|
pointer we're replacing, e.g. as is normally the case
|
|
with sqlite3's xDestroy() methods, we don't
|
|
immediately uninstall but instead add its pointer to
|
|
the scopedAlloc stack, which will be cleared when the
|
|
xWrap() mechanism is done calling the native
|
|
function. We're relying very much here on xWrap()
|
|
having pushed an alloc scope.
|
|
*/
|
|
cache.scopedAlloc[cache.scopedAlloc.length-1].push(pair[1]);
|
|
}
|
|
catch(e){/*ignored*/}
|
|
}
|
|
pair[0] = v;
|
|
pair[1] = fp;
|
|
}
|
|
return fp;
|
|
}else if(target.isPtr(v) || null===v || undefined===v){
|
|
//FuncPtrAdapter.debugOut("FuncPtrAdapter.convertArg()",this.name,this.signature,this.transient,v,pair);
|
|
if(pair && pair[1] && pair[1]!==v){
|
|
/* uninstall stashed mapping and replace stashed mapping with v. */
|
|
if(FuncPtrAdapter.debugFuncInstall){
|
|
FuncPtrAdapter.debugOut("FuncPtrAdapter uninstalling", this,
|
|
this.contextKey(argv,argIndex), '@'+pair[1], v);
|
|
}
|
|
try{ cache.scopedAlloc[cache.scopedAlloc.length-1].push(pair[1]) }
|
|
catch(e){/*ignored*/}
|
|
pair[0] = pair[1] = (v | 0);
|
|
}
|
|
return v || 0;
|
|
}else{
|
|
throw new TypeError("Invalid FuncPtrAdapter argument type. "+
|
|
"Expecting a function pointer or a "+
|
|
(this.name ? this.name+' ' : '')+
|
|
"function matching signature "+
|
|
this.signature+".");
|
|
}
|
|
}/*convertArg()*/
|
|
}/*FuncPtrAdapter*/;
|
|
|
|
/** If true, the constructor emits a warning. The intent is that
|
|
this be set to true after bootstrapping of the higher-level
|
|
client library is complete, to warn downstream clients that
|
|
they shouldn't be relying on this implemenation detail which
|
|
does not have a stable interface. */
|
|
xArg.FuncPtrAdapter.warnOnUse = false;
|
|
|
|
/** If true, convertArg() will FuncPtrAdapter.debugOut() when it
|
|
(un)installs a function binding to/from WASM. Note that
|
|
deinstallation of bindScope=transient bindings happens
|
|
via scopedAllocPop() so will not be output. */
|
|
xArg.FuncPtrAdapter.debugFuncInstall = false;
|
|
|
|
/** Function used for debug output. */
|
|
xArg.FuncPtrAdapter.debugOut = console.debug.bind(console);
|
|
|
|
xArg.FuncPtrAdapter.bindScopes = [
|
|
'transient', 'context', 'singleton', 'permanent'
|
|
];
|
|
|
|
const __xArgAdapterCheck =
|
|
(t)=>xArg.get(t) || toss("Argument adapter not found:",t);
|
|
|
|
const __xResultAdapterCheck =
|
|
(t)=>xResult.get(t) || toss("Result adapter not found:",t);
|
|
|
|
cache.xWrap.convertArg = (t,...args)=>__xArgAdapterCheck(t)(...args);
|
|
cache.xWrap.convertArgNoCheck = (t,...args)=>xArg.get(t)(...args);
|
|
|
|
cache.xWrap.convertResult =
|
|
(t,v)=>(null===t ? v : (t ? __xResultAdapterCheck(t)(v) : undefined));
|
|
cache.xWrap.convertResultNoCheck =
|
|
(t,v)=>(null===t ? v : (t ? xResult.get(t)(v) : undefined));
|
|
|
|
/**
|
|
Creates a wrapper for another function which converts the arguments
|
|
of the wrapper to argument types accepted by the wrapped function,
|
|
then converts the wrapped function's result to another form
|
|
for the wrapper.
|
|
|
|
The first argument must be one of:
|
|
|
|
- A JavaScript function.
|
|
- The name of a WASM-exported function. In the latter case xGet()
|
|
is used to fetch the exported function, which throws if it's not
|
|
found.
|
|
- A pointer into the indirect function table. e.g. a pointer
|
|
returned from target.installFunction().
|
|
|
|
It returns either the passed-in function or a wrapper for that
|
|
function which converts the JS-side argument types into WASM-side
|
|
types and converts the result type.
|
|
|
|
The second argument, `resultType`, describes the conversion for
|
|
the wrapped functions result. A literal `null` or the string
|
|
`'null'` both mean to return the original function's value as-is
|
|
(mnemonic: there is "null" conversion going on). Literal
|
|
`undefined` or the string `"void"` both mean to ignore the
|
|
function's result and return `undefined`. Aside from those two
|
|
special cases, the `resultType` value may be one of the values
|
|
described below or any mapping installed by the client using
|
|
xWrap.resultAdapter().
|
|
|
|
If passed 3 arguments and the final one is an array, that array
|
|
must contain a list of type names (see below) for adapting the
|
|
arguments from JS to WASM. If passed 2 arguments, more than 3,
|
|
or the 3rd is not an array, all arguments after the 2nd (if any)
|
|
are treated as type names. i.e.:
|
|
|
|
```
|
|
xWrap('funcname', 'i32', 'string', 'f64');
|
|
// is equivalent to:
|
|
xWrap('funcname', 'i32', ['string', 'f64']);
|
|
```
|
|
|
|
This function enforces that the given list of arguments has the
|
|
same arity as the being-wrapped function (as defined by its
|
|
`length` property) and it will throw if that is not the case.
|
|
Similarly, the created wrapper will throw if passed a differing
|
|
argument count.
|
|
|
|
Type names are symbolic names which map the arguments to an
|
|
adapter function to convert, if needed, the value before passing
|
|
it on to WASM or to convert a return result from WASM. The list
|
|
of built-in names:
|
|
|
|
- `i8`, `i16`, `i32` (args and results): all integer conversions
|
|
which convert their argument to an integer and truncate it to
|
|
the given bit length.
|
|
|
|
- `N*` (args): a type name in the form `N*`, where N is a numeric
|
|
type name, is treated the same as WASM pointer.
|
|
|
|
- `*` and `pointer` (args): are assumed to be WASM pointer values
|
|
and are returned coerced to an appropriately-sized pointer
|
|
value (i32 or i64). Non-numeric values will coerce to 0 and
|
|
out-of-range values will have undefined results (just as with
|
|
any pointer misuse).
|
|
|
|
- `*` and `pointer` (results): aliases for the current
|
|
WASM pointer numeric type.
|
|
|
|
- `**` (args): is simply a descriptive alias for the WASM pointer
|
|
type. It's primarily intended to mark output-pointer arguments.
|
|
|
|
- `i64` (args and results): passes the value to BigInt() to
|
|
convert it to an int64. Only available if bigIntEnabled is
|
|
true.
|
|
|
|
- `f32` (`float`), `f64` (`double`) (args and results): pass
|
|
their argument to Number(). i.e. the adapter does not currently
|
|
distinguish between the two types of floating-point numbers.
|
|
|
|
- `number` (results): converts the result to a JS Number using
|
|
Number(theValue).valueOf(). Note that this is for result
|
|
conversions only, as it's not possible to generically know
|
|
which type of number to convert arguments to.
|
|
|
|
Non-numeric conversions include:
|
|
|
|
- `null` literal or `"null"` string (args and results): perform
|
|
no translation and pass the arg on as-is. This is primarily
|
|
useful for results but may have a use or two for arguments.
|
|
|
|
- `string` or `utf8` (args): has two different semantics in order
|
|
to accommodate various uses of certain C APIs
|
|
(e.g. output-style strings)...
|
|
|
|
- If the arg is a string, it creates a _temporary_
|
|
UTF-8-encoded C-string to pass to the exported function,
|
|
cleaning it up before the wrapper returns. If a long-lived
|
|
C-string pointer is required, that requires client-side code
|
|
to create the string, then pass its pointer to the function.
|
|
|
|
- Else the arg is assumed to be a pointer to a string the
|
|
client has already allocated and it's passed on as
|
|
a WASM pointer.
|
|
|
|
- `string` or `utf8` (results): treats the result value as a
|
|
const C-string, encoded as UTF-8, copies it to a JS string,
|
|
and returns that JS string.
|
|
|
|
- `string:dealloc` or `utf8:dealloc) (results): treats the result value
|
|
as a non-const UTF-8 C-string, ownership of which has just been
|
|
transfered to the caller. It copies the C-string to a JS
|
|
string, frees the C-string, and returns the JS string. If such
|
|
a result value is NULL, the JS result is `null`. Achtung: when
|
|
using an API which returns results from a specific allocator,
|
|
e.g. `my_malloc()`, this conversion _is not legal_. Instead, an
|
|
equivalent conversion which uses the appropriate deallocator is
|
|
required. For example:
|
|
|
|
```js
|
|
target.xWrap.resultAdapter('string:my_free',(i)=>{
|
|
try { return i ? target.cstrToJs(i) : null }
|
|
finally{ target.exports.my_free(i) }
|
|
};
|
|
```
|
|
|
|
- `json` (results): treats the result as a const C-string and
|
|
returns the result of passing the converted-to-JS string to
|
|
JSON.parse(). Returns `null` if the C-string is a NULL pointer.
|
|
|
|
- `json:dealloc` (results): works exactly like `string:dealloc` but
|
|
returns the same thing as the `json` adapter. Note the
|
|
warning in `string:dealloc` regarding maching allocators and
|
|
deallocators.
|
|
|
|
The type names for results and arguments are validated when
|
|
xWrap() is called and any unknown names will trigger an
|
|
exception.
|
|
|
|
Clients may map their own result and argument adapters using
|
|
xWrap.resultAdapter() and xWrap.argAdapter(), noting that not all
|
|
type conversions are valid for both arguments _and_ result types
|
|
as they often have different memory ownership requirements.
|
|
|
|
Design note: the ability to pass in a JS function as the first
|
|
argument is of relatively limited use, primarily for testing
|
|
argument and result converters. JS functions, by and large, will
|
|
not want to deal with C-type arguments.
|
|
|
|
TODOs:
|
|
|
|
- Figure out how/whether we can (semi-)transparently handle
|
|
pointer-type _output_ arguments. Those currently require
|
|
explicit handling by allocating pointers, assigning them before
|
|
the call using poke(), and fetching them with
|
|
peek() after the call. We may be able to automate some
|
|
or all of that.
|
|
|
|
- Figure out whether it makes sense to extend the arg adapter
|
|
interface such that each arg adapter gets an array containing
|
|
the results of the previous arguments in the current call. That
|
|
might allow some interesting type-conversion feature. Use case:
|
|
handling of the final argument to sqlite3_prepare_v2() depends
|
|
on the type (pointer vs JS string) of its 2nd
|
|
argument. Currently that distinction requires hand-writing a
|
|
wrapper for that function. That case is unusual enough that
|
|
abstracting it into this API (and taking on the associated
|
|
costs) may well not make good sense.
|
|
*/
|
|
target.xWrap = function(fArg, resultType, ...argTypes){
|
|
if(3===arguments.length && Array.isArray(arguments[2])){
|
|
argTypes = arguments[2];
|
|
}
|
|
if(target.isPtr(fArg)){
|
|
fArg = target.functionEntry(fArg)
|
|
|| toss("Function pointer not found in WASM function table.");
|
|
}
|
|
const fIsFunc = (fArg instanceof Function);
|
|
const xf = fIsFunc ? fArg : target.xGet(fArg);
|
|
if(fIsFunc) fArg = xf.name || 'unnamed function';
|
|
if(argTypes.length!==xf.length) __argcMismatch(fArg, xf.length);
|
|
if((null===resultType) && 0===xf.length){
|
|
/* Func taking no args with an as-is return. We don't need a wrapper.
|
|
We forego the argc check here, though. */
|
|
return xf;
|
|
}
|
|
/*Verify the arg type conversions are valid...*/;
|
|
if(undefined!==resultType && null!==resultType) __xResultAdapterCheck(resultType);
|
|
for(const t of argTypes){
|
|
if(t instanceof AbstractArgAdapter) xArg.set(t, (...args)=>t.convertArg(...args));
|
|
else __xArgAdapterCheck(t);
|
|
}
|
|
const cxw = cache.xWrap;
|
|
if(0===xf.length){
|
|
// No args to convert, so we can create a simpler wrapper...
|
|
return (...args)=>(args.length
|
|
? __argcMismatch(fArg, xf.length)
|
|
: cxw.convertResult(resultType, xf.call(null)));
|
|
}
|
|
return function(...args){
|
|
if(args.length!==xf.length) __argcMismatch(fArg, xf.length);
|
|
const scope = target.scopedAllocPush();
|
|
try{
|
|
/*
|
|
Maintenance reminder re. arguments passed to convertArg():
|
|
The public interface of argument adapters is that they take
|
|
ONE argument and return a (possibly) converted result for
|
|
it. The passing-on of arguments after the first is an
|
|
internal implementation detail for the sake of
|
|
AbstractArgAdapter, and not to be relied on or documented
|
|
for other cases. The fact that this is how
|
|
AbstractArgAdapter.convertArgs() gets its 2nd+ arguments,
|
|
and how FuncPtrAdapter.contextKey() gets its args, is also
|
|
an implementation detail and subject to change. i.e. the
|
|
public interface of 1 argument is stable. The fact that any
|
|
arguments may be passed in after that one, and what those
|
|
arguments are, is _not_ part of the public interface and is
|
|
_not_ stable.
|
|
*/
|
|
for(const i in args) args[i] = cxw.convertArgNoCheck(
|
|
argTypes[i], args[i], args, i
|
|
);
|
|
return cxw.convertResultNoCheck(resultType, xf.apply(null,args));
|
|
}finally{
|
|
target.scopedAllocPop(scope);
|
|
}
|
|
};
|
|
}/*xWrap()*/;
|
|
|
|
/** Internal impl for xWrap.resultAdapter() and argAdapter(). */
|
|
const __xAdapter = function(func, argc, typeName, adapter, modeName, xcvPart){
|
|
if('string'===typeof typeName){
|
|
if(1===argc) return xcvPart.get(typeName);
|
|
else if(2===argc){
|
|
if(!adapter){
|
|
delete xcvPart.get(typeName);
|
|
return func;
|
|
}else if(!(adapter instanceof Function)){
|
|
toss(modeName,"requires a function argument.");
|
|
}
|
|
xcvPart.set(typeName, adapter);
|
|
return func;
|
|
}
|
|
}
|
|
toss("Invalid arguments to",modeName);
|
|
};
|
|
|
|
/**
|
|
Gets, sets, or removes a result value adapter for use with
|
|
xWrap(). If passed only 1 argument, the adapter function for the
|
|
given type name is returned. If the second argument is explicit
|
|
falsy (as opposed to defaulted), the adapter named by the first
|
|
argument is removed. If the 2nd argument is not falsy, it must be
|
|
a function which takes one value and returns a value appropriate
|
|
for the given type name. The adapter may throw if its argument is
|
|
not of a type it can work with. This function throws for invalid
|
|
arguments.
|
|
|
|
Example:
|
|
|
|
```
|
|
xWrap.resultAdapter('twice',(v)=>v+v);
|
|
```
|
|
|
|
xWrap.resultAdapter() MUST NOT use the scopedAlloc() family of
|
|
APIs to allocate a result value. xWrap()-generated wrappers run
|
|
in the context of scopedAllocPush() so that argument adapters can
|
|
easily convert, e.g., to C-strings, and have them cleaned up
|
|
automatically before the wrapper returns to the caller. Likewise,
|
|
if a _result_ adapter uses scoped allocation, the result will be
|
|
freed before because they would be freed before the wrapper
|
|
returns, leading to chaos and undefined behavior.
|
|
|
|
Except when called as a getter, this function returns itself.
|
|
*/
|
|
target.xWrap.resultAdapter = function f(typeName, adapter){
|
|
return __xAdapter(f, arguments.length, typeName, adapter,
|
|
'resultAdapter()', xResult);
|
|
};
|
|
|
|
/**
|
|
Functions identically to xWrap.resultAdapter() but applies to
|
|
call argument conversions instead of result value conversions.
|
|
|
|
xWrap()-generated wrappers perform argument conversion in the
|
|
context of a scopedAllocPush(), so any memory allocation
|
|
performed by argument adapters really, really, really should be
|
|
made using the scopedAlloc() family of functions unless
|
|
specifically necessary. For example:
|
|
|
|
```
|
|
xWrap.argAdapter('my-string', function(v){
|
|
return ('string'===typeof v)
|
|
? myWasmObj.scopedAllocCString(v) : null;
|
|
};
|
|
```
|
|
|
|
Contrariwise, xWrap.resultAdapter() must _not_ use scopedAlloc()
|
|
to allocate its results because they would be freed before the
|
|
xWrap()-created wrapper returns.
|
|
|
|
Note that it is perfectly legitimate to use these adapters to
|
|
perform argument validation, as opposed (or in addition) to
|
|
conversion.
|
|
*/
|
|
target.xWrap.argAdapter = function f(typeName, adapter){
|
|
return __xAdapter(f, arguments.length, typeName, adapter,
|
|
'argAdapter()', xArg);
|
|
};
|
|
|
|
target.xWrap.FuncPtrAdapter = xArg.FuncPtrAdapter;
|
|
|
|
/**
|
|
Functions like xCall() but performs argument and result type
|
|
conversions as for xWrap(). The first, second, and third
|
|
arguments are as documented for xWrap(), except that the 3rd
|
|
argument may be either a falsy value or empty array to represent
|
|
nullary functions. The 4th+ arguments are arguments for the call,
|
|
with the special case that if the 4th argument is an array, it is
|
|
used as the arguments for the call. Returns the converted result
|
|
of the call.
|
|
|
|
This is just a thin wrapper around xWrap(). If the given function
|
|
is to be called more than once, it's more efficient to use
|
|
xWrap() to create a wrapper, then to call that wrapper as many
|
|
times as needed. For one-shot calls, however, this variant is
|
|
arguably more efficient because it will hypothetically free the
|
|
wrapper function quickly.
|
|
*/
|
|
target.xCallWrapped = function(fArg, resultType, argTypes, ...args){
|
|
if(Array.isArray(arguments[3])) args = arguments[3];
|
|
return target.xWrap(fArg, resultType, argTypes||[]).apply(null, args||[]);
|
|
};
|
|
|
|
/**
|
|
This function is ONLY exposed in the public API to facilitate
|
|
testing. It should not be used in application-level code, only
|
|
in test code.
|
|
|
|
Expects to be given (typeName, value) and returns a conversion
|
|
of that value as has been registered using argAdapter().
|
|
It throws if no adapter is found.
|
|
|
|
ACHTUNG: the adapter may require that a scopedAllocPush() is
|
|
active and it may allocate memory within that scope. It may also
|
|
require additional arguments, depending on the type of
|
|
conversion.
|
|
*/
|
|
target.xWrap.testConvertArg = cache.xWrap.convertArg;
|
|
|
|
/**
|
|
This function is ONLY exposed in the public API to facilitate
|
|
testing. It should not be used in application-level code, only
|
|
in test code.
|
|
|
|
Expects to be given (typeName, value) and returns a conversion
|
|
of that value as has been registered using resultAdapter().
|
|
It throws if no adapter is found.
|
|
|
|
ACHTUNG: the adapter may allocate memory which the caller may need
|
|
to know how to free.
|
|
*/
|
|
target.xWrap.testConvertResult = cache.xWrap.convertResult;
|
|
|
|
return target;
|
|
};
|
|
|
|
/**
|
|
yawl (Yet Another Wasm Loader) provides very basic wasm loader.
|
|
It requires a config object:
|
|
|
|
- `uri`: required URI of the WASM file to load.
|
|
|
|
- `onload(loadResult,config)`: optional callback. The first
|
|
argument is the result object from
|
|
WebAssembly.instantiate[Streaming](). The 2nd is the config
|
|
object passed to this function. Described in more detail below.
|
|
|
|
- `imports`: optional imports object for
|
|
WebAssembly.instantiate[Streaming](). The default is an empty set
|
|
of imports. If the module requires any imports, this object
|
|
must include them.
|
|
|
|
- `wasmUtilTarget`: optional object suitable for passing to
|
|
WhWasmUtilInstaller(). If set, it gets passed to that function
|
|
after the promise resolves. This function sets several properties
|
|
on it before passing it on to that function (which sets many
|
|
more):
|
|
|
|
- `module`, `instance`: the properties from the
|
|
instantiate[Streaming]() result.
|
|
|
|
- If `instance.exports.memory` is _not_ set then it requires that
|
|
`config.imports.env.memory` be set (else it throws), and
|
|
assigns that to `target.memory`.
|
|
|
|
- If `wasmUtilTarget.alloc` is not set and
|
|
`instance.exports.malloc` is, it installs
|
|
`wasmUtilTarget.alloc()` and `wasmUtilTarget.dealloc()`
|
|
wrappers for the exports `malloc` and `free` functions.
|
|
|
|
It returns a function which, when called, initiates loading of the
|
|
module and returns a Promise. When that Promise resolves, it calls
|
|
the `config.onload` callback (if set) and passes it
|
|
`(loadResult,config)`, where `loadResult` is the result of
|
|
WebAssembly.instantiate[Streaming](): an object in the form:
|
|
|
|
```
|
|
{
|
|
module: a WebAssembly.Module,
|
|
instance: a WebAssembly.Instance
|
|
}
|
|
```
|
|
|
|
(Note that the initial `then()` attached to the promise gets only
|
|
that object, and not the `config` one.)
|
|
|
|
Error handling is up to the caller, who may attach a `catch()` call
|
|
to the promise.
|
|
*/
|
|
globalThis.WhWasmUtilInstaller.yawl = function(config){
|
|
const wfetch = ()=>fetch(config.uri, {credentials: 'same-origin'});
|
|
const wui = this;
|
|
const finalThen = function(arg){
|
|
//log("finalThen()",arg);
|
|
if(config.wasmUtilTarget){
|
|
const toss = (...args)=>{throw new Error(args.join(' '))};
|
|
const tgt = config.wasmUtilTarget;
|
|
tgt.module = arg.module;
|
|
tgt.instance = arg.instance;
|
|
//tgt.exports = tgt.instance.exports;
|
|
if(!tgt.instance.exports.memory){
|
|
/**
|
|
WhWasmUtilInstaller requires either tgt.exports.memory
|
|
(exported from WASM) or tgt.memory (JS-provided memory
|
|
imported into WASM).
|
|
*/
|
|
tgt.memory = (config.imports && config.imports.env
|
|
&& config.imports.env.memory)
|
|
|| toss("Missing 'memory' object!");
|
|
}
|
|
if(!tgt.alloc && arg.instance.exports.malloc){
|
|
const exports = arg.instance.exports;
|
|
tgt.alloc = function(n){
|
|
return exports.malloc(n) || toss("Allocation of",n,"bytes failed.");
|
|
};
|
|
tgt.dealloc = function(m){exports.free(m)};
|
|
}
|
|
wui(tgt);
|
|
}
|
|
if(config.onload) config.onload(arg,config);
|
|
return arg /* for any then() handler attached to
|
|
yetAnotherWasmLoader()'s return value */;
|
|
};
|
|
const loadWasm = WebAssembly.instantiateStreaming
|
|
? function loadWasmStreaming(){
|
|
return WebAssembly.instantiateStreaming(wfetch(), config.imports||{})
|
|
.then(finalThen);
|
|
}
|
|
: function loadWasmOldSchool(){ // Safari < v15
|
|
return wfetch()
|
|
.then(response => response.arrayBuffer())
|
|
.then(bytes => WebAssembly.instantiate(bytes, config.imports||{}))
|
|
.then(finalThen);
|
|
};
|
|
return loadWasm;
|
|
}.bind(globalThis.WhWasmUtilInstaller)/*yawl()*/;
|