/* * Copyright 2015 WebAssembly Community Group participants * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ // // WebAssembly intepreter for asm2wasm output, in a js environment. // // Receives asm.js, generates a runnable module that executes the code in a WebAssembly // interpreter. This is suitable as a polyfill for WebAssembly support in browsers. // #include #include "asm2wasm.h" #include "wasm-interpreter.h" #include "wasm-s-parser.h" using namespace cashew; using namespace wasm; namespace wasm { int debug = 0; } // global singletons Asm2WasmBuilder* asm2wasm = nullptr; SExpressionParser* sExpressionParser = nullptr; SExpressionWasmBuilder* sExpressionWasmBuilder = nullptr; ModuleInstance* instance = nullptr; AllocatingModule* module = nullptr; bool wasmJSDebug = false; static void prepare2wasm() { assert(asm2wasm == nullptr && sExpressionParser == nullptr && sExpressionWasmBuilder == nullptr && instance == nullptr); // singletons #if WASM_JS_DEBUG wasmJSDebug = 1; #else wasmJSDebug = EM_ASM_INT_V({ return !!Module['outside']['WASM_JS_DEBUG'] }); // Set WASM_JS_DEBUG on the outside Module to get debugging #endif } // receives asm.js code, parses into wasm. // note: this modifies the input. extern "C" void EMSCRIPTEN_KEEPALIVE load_asm2wasm(char *input) { prepare2wasm(); Asm2WasmPreProcessor pre; input = pre.process(input); // proceed to parse and wasmify if (wasmJSDebug) std::cerr << "asm parsing...\n"; cashew::Parser builder; Ref asmjs = builder.parseToplevel(input); module = new AllocatingModule(); module->memory.initial = EM_ASM_INT_V({ return Module['providedTotalMemory']; // we receive the size of memory from emscripten }); module->memory.max = pre.memoryGrowth ? -1 : module->memory.initial; if (wasmJSDebug) std::cerr << "wasming...\n"; asm2wasm = new Asm2WasmBuilder(*module, pre.memoryGrowth, debug); asm2wasm->processAsm(asmjs); if (wasmJSDebug) std::cerr << "optimizing...\n"; asm2wasm->optimize(); if (wasmJSDebug) std::cerr << "mapping globals...\n"; for (auto& pair : asm2wasm->mappedGlobals) { auto name = pair.first; auto& global = pair.second; if (!global.import) continue; // non-imports are initialized to zero in the typed array anyhow, so nothing to do here double value = EM_ASM_DOUBLE({ return Module['lookupImport'](Pointer_stringify($0), Pointer_stringify($1)) }, global.module.str, global.base.str); unsigned address = global.address; switch (global.type) { case i32: EM_ASM_({ Module['info'].parent['HEAP32'][$0 >> 2] = $1 }, address, value); break; case f32: EM_ASM_({ Module['info'].parent['HEAPF32'][$0 >> 2] = $1 }, address, value); break; case f64: EM_ASM_({ Module['info'].parent['HEAPF64'][$0 >> 3] = $1 }, address, value); break; default: abort(); } } } // loads wasm code in s-expression format extern "C" void EMSCRIPTEN_KEEPALIVE load_s_expr2wasm(char *input, char *mappedGlobals) { prepare2wasm(); if (wasmJSDebug) std::cerr << "wasm-s-expression parsing...\n"; sExpressionParser = new SExpressionParser(input); Element& root = *sExpressionParser->root; if (wasmJSDebug) std::cout << root << '\n'; if (wasmJSDebug) std::cerr << "wasming...\n"; module = new AllocatingModule(); // A .wast may have multiple modules, with some asserts after them, but we just read the first here. sExpressionWasmBuilder = new SExpressionWasmBuilder(*module, *root[0], [&]() { std::cerr << "error in parsing s-expressions to wasm\n"; abort(); }); module->memory.initial = EM_ASM_INT_V({ return Module['providedTotalMemory']; // we receive the size of memory from emscripten }); module->memory.max = (module->exportsMap.find(GROW_WASM_MEMORY) != module->exportsMap.end()) ? -1 : module->memory.initial; // global mapping is done in js in post.js } // instantiates the loaded wasm (which might be from asm2wasm, or // s-expressions, or something else) with a JS external interface. extern "C" void EMSCRIPTEN_KEEPALIVE instantiate() { if (wasmJSDebug) std::cerr << "instantiating module: \n" << *module << '\n'; if (wasmJSDebug) std::cerr << "generating exports...\n"; EM_ASM({ Module['asmExports'] = {}; }); for (auto& pair : module->exportsMap) { auto& curr = pair.second; EM_ASM_({ var name = Pointer_stringify($0); Module['asmExports'][name] = function() { Module['tempArguments'] = Array.prototype.slice.call(arguments); Module['_call_from_js']($0); return Module['tempReturn']; }; }, curr->name.str); } if (wasmJSDebug) std::cerr << "creating instance...\n"; struct JSExternalInterface : ModuleInstance::ExternalInterface { void init(Module& wasm) override { // if we have memory segments, create a new buffer here, just like native wasm support would. // otherwise, no need to. if (wasm.memory.segments.size() > 0) { EM_ASM_({ Module['outside']['newBuffer'] = new ArrayBuffer($0); }, wasm.memory.initial); for (auto segment : wasm.memory.segments) { EM_ASM_({ var source = Module['HEAP8'].subarray($1, $1 + $2); var target = new Int8Array(Module['outside']['newBuffer']); target.set(source, $0); }, segment.offset, segment.data, segment.size); } } } Literal callImport(Import *import, ModuleInstance::LiteralList& arguments) override { if (wasmJSDebug) std::cout << "calling import " << import->name.str << '\n'; EM_ASM({ Module['tempArguments'] = []; }); for (auto& argument : arguments) { if (argument.type == i32) { EM_ASM_({ Module['tempArguments'].push($0) }, argument.geti32()); } else if (argument.type == f32) { EM_ASM_({ Module['tempArguments'].push($0) }, argument.getf32()); } else if (argument.type == f64) { EM_ASM_({ Module['tempArguments'].push($0) }, argument.getf64()); } else { abort(); } } double ret = EM_ASM_DOUBLE({ var mod = Pointer_stringify($0); var base = Pointer_stringify($1); var tempArguments = Module['tempArguments']; Module['tempArguments'] = null; var lookup = Module['lookupImport'](mod, base); return lookup.apply(null, tempArguments); }, import->module.str, import->base.str); if (wasmJSDebug) std::cout << "calling import returning " << ret << '\n'; switch (import->type->result) { case none: return Literal(0); case i32: return Literal((int32_t)ret); case f32: return Literal((float)ret); case f64: return Literal((double)ret); default: abort(); } } Literal load(Load* load, size_t addr) override { assert(load->align >= load->bytes); if (!isWasmTypeFloat(load->type)) { if (load->bytes == 1) { if (load->signed_) { return Literal(EM_ASM_INT({ return Module['info'].parent['HEAP8'][$0] }, addr)); } else { return Literal(EM_ASM_INT({ return Module['info'].parent['HEAPU8'][$0] }, addr)); } } else if (load->bytes == 2) { if (load->signed_) { return Literal(EM_ASM_INT({ return Module['info'].parent['HEAP16'][$0 >> 1] }, addr)); } else { return Literal(EM_ASM_INT({ return Module['info'].parent['HEAPU16'][$0 >> 1] }, addr)); } } else if (load->bytes == 4) { if (load->signed_) { return Literal(EM_ASM_INT({ return Module['info'].parent['HEAP32'][$0 >> 2] }, addr)); } else { return Literal(EM_ASM_INT({ return Module['info'].parent['HEAPU32'][$0 >> 2] }, addr)); } } abort(); } else { if (load->bytes == 4) { return Literal((float)EM_ASM_DOUBLE({ return Module['info'].parent['HEAPF32'][$0 >> 2] }, addr)); } else if (load->bytes == 8) { return Literal(EM_ASM_DOUBLE({ return Module['info'].parent['HEAPF64'][$0 >> 3] }, addr)); } abort(); } } void store(Store* store, size_t addr, Literal value) override { assert(store->align >= store->bytes); if (!isWasmTypeFloat(store->type)) { if (store->bytes == 1) { EM_ASM_INT({ Module['info'].parent['HEAP8'][$0] = $1 }, addr, value.geti32()); } else if (store->bytes == 2) { EM_ASM_INT({ Module['info'].parent['HEAP16'][$0 >> 1] = $1 }, addr, value.geti32()); } else if (store->bytes == 4) { EM_ASM_INT({ Module['info'].parent['HEAP32'][$0 >> 2] = $1 }, addr, value.geti32()); } else { abort(); } } else { if (store->bytes == 4) { EM_ASM_DOUBLE({ Module['info'].parent['HEAPF32'][$0 >> 2] = $1 }, addr, value.getf32()); } else if (store->bytes == 8) { EM_ASM_DOUBLE({ Module['info'].parent['HEAPF64'][$0 >> 3] = $1 }, addr, value.getf64()); } else { abort(); } } } void growMemory(size_t oldSize, size_t newSize) override { EM_ASM_({ var size = $0; var buffer; try { buffer = new ArrayBuffer(size); } catch(e) { // fail to grow memory. post.js notices this since the buffer is unchanged return; } var oldHEAP8 = Module['outside']['HEAP8']; var temp = new Int8Array(buffer); temp.set(oldHEAP8); Module['outside']['buffer'] = buffer; }, newSize); } void trap(const char* why) override { EM_ASM_({ abort("wasm trap: " + Pointer_stringify($0)); }, why); } }; instance = new ModuleInstance(*module, new JSExternalInterface()); } // Does a call from js into an export of the module. extern "C" void EMSCRIPTEN_KEEPALIVE call_from_js(const char *target) { if (wasmJSDebug) std::cout << "call_from_js " << target << '\n'; IString exportName(target); IString functionName = instance->wasm.exportsMap[exportName]->value; Function *function = instance->wasm.functionsMap[functionName]; assert(function); size_t seen = EM_ASM_INT_V({ return Module['tempArguments'].length }); size_t actual = function->params.size(); ModuleInstance::LiteralList arguments; for (size_t i = 0; i < actual; i++) { WasmType type = function->params[i].type; // add the parameter, with a zero value if JS did not provide it. if (type == i32) { arguments.push_back(Literal(i < seen ? EM_ASM_INT({ return Module['tempArguments'][$0] }, i) : (int32_t)0)); } else if (type == f32) { arguments.push_back(Literal(i < seen ? (float)EM_ASM_DOUBLE({ return Module['tempArguments'][$0] }, i) : (float)0.0)); } else if (type == f64) { arguments.push_back(Literal(i < seen ? EM_ASM_DOUBLE({ return Module['tempArguments'][$0] }, i) : (double)0.0)); } else { abort(); } } Literal ret = instance->callExport(exportName, arguments); if (wasmJSDebug) std::cout << "call_from_js returning " << ret << '\n'; if (ret.type == none) EM_ASM({ Module['tempReturn'] = undefined }); else if (ret.type == i32) EM_ASM_({ Module['tempReturn'] = $0 }, ret.i32); else if (ret.type == f32) EM_ASM_({ Module['tempReturn'] = $0 }, ret.f32); else if (ret.type == f64) EM_ASM_({ Module['tempReturn'] = $0 }, ret.f64); else abort(); }