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|
//==============================================================================
// Optimizer tool. This is meant to be run after the emscripten compiler has
// finished generating code. These optimizations are done on the generated
// code to further improve it. Some of the modifications also work in
// conjunction with closure compiler.
//
// TODO: Optimize traverse to modify a node we want to replace, in-place,
// instead of returning it to the previous call frame where we check?
// TODO: Share EMPTY_NODE instead of emptyNode that constructs?
//==============================================================================
// *** Environment setup code ***
var arguments_ = [];
var ENVIRONMENT_IS_NODE = typeof process === 'object';
var ENVIRONMENT_IS_WEB = typeof window === 'object';
var ENVIRONMENT_IS_WORKER = typeof importScripts === 'function';
var ENVIRONMENT_IS_SHELL = !ENVIRONMENT_IS_WEB && !ENVIRONMENT_IS_NODE && !ENVIRONMENT_IS_WORKER;
if (ENVIRONMENT_IS_NODE) {
// Expose functionality in the same simple way that the shells work
// Note that we pollute the global namespace here, otherwise we break in node
print = function(x) {
process['stdout'].write(x + '\n');
};
printErr = function(x) {
process['stderr'].write(x + '\n');
};
var nodeFS = require('fs');
var nodePath = require('path');
if (!nodeFS.existsSync) {
nodeFS.existsSync = function(path) {
try {
return !!nodeFS.readFileSync(path);
} catch(e) {
return false;
}
}
}
function find(filename) {
var prefixes = [nodePath.join(__dirname, '..', 'src'), process.cwd()];
for (var i = 0; i < prefixes.length; ++i) {
var combined = nodePath.join(prefixes[i], filename);
if (nodeFS.existsSync(combined)) {
return combined;
}
}
return filename;
}
read = function(filename) {
var absolute = find(filename);
return nodeFS['readFileSync'](absolute).toString();
};
load = function(f) {
globalEval(read(f));
};
arguments_ = process['argv'].slice(2);
} else if (ENVIRONMENT_IS_SHELL) {
// Polyfill over SpiderMonkey/V8 differences
if (!this['read']) {
this['read'] = function(f) { snarf(f) };
}
if (typeof scriptArgs != 'undefined') {
arguments_ = scriptArgs;
} else if (typeof arguments != 'undefined') {
arguments_ = arguments;
}
} else if (ENVIRONMENT_IS_WEB) {
this['print'] = printErr = function(x) {
console.log(x);
};
this['read'] = function(url) {
var xhr = new XMLHttpRequest();
xhr.open('GET', url, false);
xhr.send(null);
return xhr.responseText;
};
if (this['arguments']) {
arguments_ = arguments;
}
} else if (ENVIRONMENT_IS_WORKER) {
// We can do very little here...
this['load'] = importScripts;
} else {
throw 'Unknown runtime environment. Where are we?';
}
function globalEval(x) {
eval.call(null, x);
}
if (typeof load == 'undefined' && typeof read != 'undefined') {
this['load'] = function(f) {
globalEval(read(f));
};
}
if (typeof printErr === 'undefined') {
this['printErr'] = function(){};
}
if (typeof print === 'undefined') {
this['print'] = printErr;
}
// *** Environment setup code ***
var uglify = require('../tools/eliminator/node_modules/uglify-js');
var fs = require('fs');
var path = require('path');
// Load some modules
load('utility.js');
// Utilities
var FUNCTION = set('defun', 'function');
var LOOP = set('do', 'while', 'for');
var LOOP_FLOW = set('break', 'continue');
var ASSIGN_OR_ALTER = set('assign', 'unary-postfix', 'unary-prefix');
var CONTROL_FLOW = set('do', 'while', 'for', 'if', 'switch');
var NAME_OR_NUM = set('name', 'num');
var ASSOCIATIVE_BINARIES = set('+', '*', '|', '&', '^');
var NULL_NODE = ['name', 'null'];
var UNDEFINED_NODE = ['unary-prefix', 'void', ['num', 0]];
var TRUE_NODE = ['unary-prefix', '!', ['num', 0]];
var FALSE_NODE = ['unary-prefix', '!', ['num', 1]];
var GENERATED_FUNCTIONS_MARKER = '// EMSCRIPTEN_GENERATED_FUNCTIONS';
var generatedFunctions = false; // whether we have received only generated functions
var minifierInfo = null;
function srcToAst(src) {
return uglify.parser.parse(src);
}
function astToSrc(ast, compress) {
return uglify.uglify.gen_code(ast, {
ascii_only: true,
beautify: !compress,
indent_level: 2
});
}
// Traverses the children of a node. If the traverse function returns an object,
// replaces the child. If it returns true, stop the traversal and return true.
function traverseChildren(node, traverse, pre, post, stack) {
for (var i = 0; i < node.length; i++) {
var subnode = node[i];
if (typeof subnode == 'object' && subnode && subnode.length) {
var subresult = traverse(subnode, pre, post, stack);
if (subresult == true) return true;
if (subresult !== null && typeof subresult == 'object') node[i] = subresult;
}
}
}
// Traverses a JavaScript syntax tree rooted at the given node calling the given
// callback for each node.
// @arg node: The root of the AST.
// @arg pre: The pre to call for each node. This will be called with
// the node as the first argument and its type as the second. If true is
// returned, the traversal is stopped. If an object is returned,
// it replaces the passed node in the tree. If null is returned, we stop
// traversing the subelements (but continue otherwise).
// @arg post: A callback to call after traversing all children.
// @arg stack: If true, a stack will be implemented: If pre does not push on
// the stack, we push a 0. We pop when we leave the node. The
// stack is passed as a third parameter to the callbacks.
// @returns: If the root node was replaced, the new root node. If the traversal
// was stopped, true. Otherwise undefined.
function traverse(node, pre, post, stack) {
var type = node[0], result, len;
var relevant = typeof type == 'string';
if (relevant) {
if (stack) len = stack.length;
var result = pre(node, type, stack);
if (result == true) return true;
if (result !== null && typeof result == 'object') node = result; // Continue processing on this node
if (stack && len == stack.length) stack.push(0);
}
if (result !== null) {
if (traverseChildren(node, traverse, pre, post, stack) == true) return true;
}
if (relevant) {
if (post) {
var postResult = post(node, type, stack);
result = result || postResult;
}
if (stack) stack.pop();
}
return result;
}
// Only walk through the generated functions
function traverseGenerated(ast, pre, post, stack) {
assert(generatedFunctions);
traverse(ast, function(node) {
if (node[0] == 'defun') {
traverse(node, pre, post, stack);
return null;
}
});
}
function traverseGeneratedFunctions(ast, callback) {
assert(generatedFunctions);
if (ast[0] == 'toplevel') {
var stats = ast[1];
for (var i = 0; i < stats.length; i++) {
var curr = stats[i];
if (curr[0] == 'defun') callback(curr);
}
} else if (ast[0] == 'defun') {
callback(ast);
}
}
// Walk the ast in a simple way, with an understanding of which JS variables are defined)
function traverseWithVariables(ast, callback) {
traverse(ast, function(node, type, stack) {
if (type in FUNCTION) {
stack.push({ type: 'function', vars: node[2] });
} else if (type == 'var') {
// Find our function, add our vars
var func = stack[stack.length-1];
if (func) {
func.vars = func.vars.concat(node[1].map(function(varItem) { return varItem[0] }));
}
}
}, function(node, type, stack) {
if (type == 'toplevel' || type in FUNCTION) {
// We know all of the variables that are seen here, proceed to do relevant replacements
var allVars = stack.map(function(item) { return item ? item.vars : [] }).reduce(concatenator, []); // FIXME dictionary for speed?
traverse(node, function(node2, type2, stack2) {
// Be careful not to look into our inner functions. They have already been processed.
if (sum(stack2) > 1 || (type == 'toplevel' && sum(stack2) == 1)) return;
if (type2 in FUNCTION) stack2.push(1);
return callback(node2, type2, allVars);
}, null, []);
}
}, []);
}
function emptyNode() { // XXX do we need to create new nodes here? can't we reuse?
return ['toplevel', []]
}
function isEmptyNode(node) {
return node.length == 2 && node[0] == 'toplevel' && node[1].length == 0;
}
// Passes
// Dump the AST. Useful for debugging. For example,
// node tools/js-optimizer.js ABSOLUTE_PATH_TO_FILE dumpAst
function dumpAst(ast) {
printErr(JSON.stringify(ast, null, ' '));
}
function dumpSrc(ast) {
printErr(astToSrc(ast));
}
// Undos closure's creation of global variables with values true, false,
// undefined, null. These cut down on size, but do not affect gzip size
// and make JS engine's lives slightly harder (?)
function unGlobalize(ast) {
throw 'this is deprecated!'; // and does not work with parallel compilation
assert(ast[0] == 'toplevel');
var values = {};
// Find global renamings of the relevant values
ast[1].forEach(function(node, i) {
if (node[0] != 'var') return;
node[1] = node[1].filter(function(varItem, j) {
var ident = varItem[0];
var value = varItem[1];
if (!value) return true;
var possible = false;
if (jsonCompare(value, NULL_NODE) ||
jsonCompare(value, UNDEFINED_NODE) ||
jsonCompare(value, TRUE_NODE) ||
jsonCompare(value, FALSE_NODE)) {
possible = true;
}
if (!possible) return true;
// Make sure there are no assignments to this variable. (This isn't fast, we traverse many times..)
ast[1][i][1][j] = emptyNode();
var assigned = false;
traverseWithVariables(ast, function(node, type, allVars) {
if (type == 'assign' && node[2][0] == 'name' && node[2][1] == ident) assigned = true;
});
ast[1][i][1][j] = [ident, value];
if (!assigned) {
values[ident] = value;
return false;
}
return true;
});
if (node[1].length == 0) {
ast[1][i] = emptyNode();
}
});
traverseWithVariables(ast, function(node, type, allVars) {
if (type == 'name') {
var ident = node[1];
if (ident in values && allVars.indexOf(ident) < 0) {
return copy(values[ident]);
}
}
});
}
// Closure compiler, when inlining, will insert assignments to
// undefined for the shared variables. However, in compiled code
// - and in library/shell code too! - we should never rely on
// undefined being assigned. So we can simply remove those assignments.
//
// Note: An inlined function that kept a large value referenced, may
// keep that references when inlined, if we remove the setting to
// undefined. This is not dangerous in compiled code, but might be
// in supporting code (for example, holding on to the HEAP when copying).
//
// This pass assumes that unGlobalize has been run, so undefined
// is now explicit.
function removeAssignsToUndefined(ast) {
traverse(ast, function(node, type) {
if (type == 'assign' && jsonCompare(node[3], ['unary-prefix', 'void', ['num', 0]])) {
return emptyNode();
} else if (type == 'var') {
node[1] = node[1].map(function(varItem, j) {
var ident = varItem[0];
var value = varItem[1];
if (jsonCompare(value, UNDEFINED_NODE)) return [ident];
return [ident, value];
});
}
});
// cleanup (|x = y = void 0| leaves |x = ;| right now)
var modified = true;
while (modified) {
modified = false;
traverse(ast, function(node, type) {
if (type == 'assign' && jsonCompare(node[3], emptyNode())) {
modified = true;
return emptyNode();
} else if (type == 'var') {
node[1] = node[1].map(function(varItem, j) {
var ident = varItem[0];
var value = varItem[1];
if (value && jsonCompare(value, emptyNode())) return [ident];
return [ident, value];
});
}
});
}
}
// XXX This is an invalid optimization
// We sometimes leave some settings to label that are not needed, if later in
// the relooper we realize that we have a single entry, so no checks on label
// are actually necessary. It's easy to clean those up now.
function removeUnneededLabelSettings(ast) {
traverse(ast, function(node, type) {
if (type == 'defun') { // all of our compiled code is in defun nodes
// Find all checks
var checked = {};
traverse(node, function(node, type) {
if (type == 'binary' && node[1] == '==' && node[2][0] == 'name' && node[2][1] == 'label') {
assert(node[3][0] == 'num');
checked[node[3][1]] = 1;
}
});
// Remove unneeded sets
traverse(node, function(node, type) {
if (type == 'assign' && node[2][0] == 'name' && node[2][1] == 'label') {
assert(node[3][0] == 'num');
if (!(node[3][1] in checked)) return emptyNode();
}
});
}
});
}
// Various expression simplifications. Pre run before closure (where we still have metadata), Post run after.
var USEFUL_BINARY_OPS = set('<<', '>>', '|', '&', '^');
function simplifyExpressionsPre(ast) {
// Look for (x&A)<<B>>B and replace it with X&A if possible.
function simplifySignExtends(ast) {
traverse(ast, function(node, type) {
if (type == 'binary' && node[1] == '>>' && node[3][0] == 'num' &&
node[2][0] == 'binary' && node[2][1] == '<<' && node[2][3][0] == 'num' && node[3][1] == node[2][3][1]) {
var innerNode = node[2][2];
var shifts = node[3][1];
if (innerNode[0] == 'binary' && innerNode[1] == '&' && innerNode[3][0] == 'num') {
var mask = innerNode[3][1];
if (mask << shifts >> shifts == mask) {
return innerNode;
}
}
}
});
}
// When there is a bunch of math like (((8+5)|0)+12)|0, only the external |0 is needed, one correction is enough.
// At each node, ((X|0)+Y)|0 can be transformed into (X+Y): The inner corrections are not needed
// TODO: Is the same is true for 0xff, 0xffff?
// Likewise, if we have |0 inside a block that will be >>'d, then the |0 is unnecessary because some
// 'useful' mathops already |0 anyhow.
function simplifyBitops(ast) {
var SAFE_BINARY_OPS = set('+', '-', '*'); // division is unsafe as it creates non-ints in JS; mod is unsafe as signs matter so we can't remove |0's
var ZERO = ['num', 0];
var rerun = true;
while (rerun) {
rerun = false;
traverse(ast, function process(node, type, stack) {
if (type == 'binary' && node[1] == '|') {
if (node[2][0] == 'num' && node[3][0] == 'num') {
return ['num', node[2][1] | node[3][1]];
} else if (jsonCompare(node[2], ZERO) || jsonCompare(node[3], ZERO)) {
// We might be able to remove this correction
for (var i = stack.length-1; i >= 0; i--) {
if (stack[i] == 1) {
// we will replace ourselves with the non-zero side. Recursively process that node.
var result = jsonCompare(node[2], ZERO) ? node[3] : node[2], other;
// replace node in-place
node.length = result.length;
for (var j = 0; j < result.length; j++) {
node[j] = result[j];
}
rerun = true;
return process(result, result[0], stack);
} else if (stack[i] == -1) {
break; // Too bad, we can't
} else if (asm) {
break; // we must keep a coercion right on top of a heap access in asm mode
}
}
}
stack.push(1); // From here on up, no need for this kind of correction, it's done at the top
// (Add this at the end, so it is only added if we did not remove it)
} else if (type == 'binary' && node[1] in USEFUL_BINARY_OPS) {
stack.push(1);
} else if ((type == 'binary' && node[1] in SAFE_BINARY_OPS) || type == 'num' || type == 'name') {
stack.push(0); // This node is safe in that it does not interfere with this optimization
} else {
stack.push(-1); // This node is dangerous! Give up if you see this before you see '1'
}
}, null, []);
}
// & and heap-related optimizations
var heapBits, heapUnsigned;
function parseHeap(name) {
if (name.substr(0, 4) != 'HEAP') return false;
heapUnsigned = name[4] == 'U';
heapBits = parseInt(name.substr(heapUnsigned ? 5 : 4));
return true;
}
var hasTempDoublePtr = false;
traverse(ast, function(node, type) {
if (type == 'name') {
if (node[1] == 'tempDoublePtr') hasTempDoublePtr = true;
} else if (type == 'binary' && node[1] == '&' && node[3][0] == 'num') {
if (node[2][0] == 'num') return ['num', node[2][1] & node[3][1]];
var input = node[2];
var amount = node[3][1];
if (input[0] == 'binary' && input[1] == '&' && input[3][0] == 'num') {
// Collapse X & 255 & 1
node[3][1] = amount & input[3][1];
node[2] = input[2];
} else if (input[0] == 'sub' && input[1][0] == 'name') {
// HEAP8[..] & 255 => HEAPU8[..]
var name = input[1][1];
if (parseHeap(name)) {
if (amount == Math.pow(2, heapBits)-1) {
if (!heapUnsigned) {
input[1][1] = 'HEAPU' + heapBits; // make unsigned
}
if (asm) {
// we cannot return HEAPU8 without a coercion, but at least we do HEAP8 & 255 => HEAPU8 | 0
node[1] = '|';
node[3][1] = 0;
return node;
}
return input;
}
}
}
} else if (type == 'binary' && node[1] == '>>' && node[3][0] == 'num' &&
node[2][0] == 'binary' && node[2][1] == '<<' && node[2][3][0] == 'num' &&
node[2][2][0] == 'sub' && node[2][2][1][0] == 'name') {
// collapse HEAPU?8[..] << 24 >> 24 etc. into HEAP8[..] | 0
// TODO: run this before | 0 | 0 removal, because we generate | 0
var amount = node[3][1];
var name = node[2][2][1][1];
if (amount == node[2][3][1] && parseHeap(name)) {
if (heapBits == 32 - amount) {
node[2][2][1][1] = 'HEAP' + heapBits;
node[1] = '|';
node[2] = node[2][2];
node[3][1] = 0;
return node;
}
}
} else if (type == 'assign') {
// optimizations for assigning into HEAP32 specifically
if (node[1] === true && node[2][0] == 'sub' && node[2][1][0] == 'name' && node[2][1][1] == 'HEAP32') {
// HEAP32[..] = x | 0 does not need the | 0 (unless it is a mandatory |0 of a call)
if (node[3][0] == 'binary' && node[3][1] == '|') {
if (node[3][2][0] == 'num' && node[3][2][1] == 0 && node[3][3][0] != 'call') {
node[3] = node[3][3];
} else if (node[3][3][0] == 'num' && node[3][3][1] == 0 && node[3][2][0] != 'call') {
node[3] = node[3][2];
}
}
}
var value = node[3];
if (value[0] == 'binary' && value[1] == '|') {
// canonicalize order of |0 to end
if (value[2][0] == 'num' && value[2][1] == 0) {
var temp = value[2];
value[2] = value[3];
value[3] = temp;
}
// if a seq ends in an |0, remove an external |0
// note that it is only safe to do this in assigns, like we are doing here (return (x, y|0); is not valid)
if (value[2][0] == 'seq' && value[2][2][0] == 'binary' && value[2][2][1] in USEFUL_BINARY_OPS) {
node[3] = value[2];
}
}
}
});
if (asm) {
if (hasTempDoublePtr) {
traverse(ast, function(node, type) {
if (type == 'assign') {
if (node[1] === true && node[2][0] == 'sub' && node[2][1][0] == 'name' && node[2][1][1] == 'HEAP32') {
// remove bitcasts that are now obviously pointless, e.g.
// HEAP32[$45 >> 2] = HEAPF32[tempDoublePtr >> 2] = ($14 < $28 ? $14 : $28) - $42, HEAP32[tempDoublePtr >> 2] | 0;
var value = node[3];
if (value[0] == 'seq' && value[1][0] == 'assign' && value[1][2][0] == 'sub' && value[1][2][1][0] == 'name' && value[1][2][1][1] == 'HEAPF32' &&
value[1][2][2][0] == 'binary' && value[1][2][2][2][0] == 'name' && value[1][2][2][2][1] == 'tempDoublePtr') {
// transform to HEAPF32[$45 >> 2] = ($14 < $28 ? $14 : $28) - $42;
node[2][1][1] = 'HEAPF32';
node[3] = value[1][3];
}
}
} else if (type == 'seq') {
// (HEAP32[tempDoublePtr >> 2] = HEAP32[$37 >> 2], +HEAPF32[tempDoublePtr >> 2])
// ==>
// +HEAPF32[$37 >> 2]
if (node[0] == 'seq' && node[1][0] == 'assign' && node[1][2][0] == 'sub' && node[1][2][1][0] == 'name' &&
(node[1][2][1][1] == 'HEAP32' || node[1][2][1][1] == 'HEAPF32') &&
node[1][2][2][0] == 'binary' && node[1][2][2][2][0] == 'name' && node[1][2][2][2][1] == 'tempDoublePtr' &&
node[1][3][0] == 'sub' && node[1][3][1][0] == 'name' && (node[1][3][1][1] == 'HEAP32' || node[1][3][1][1] == 'HEAPF32')) {
if (node[1][2][1][1] == 'HEAP32') {
node[1][3][1][1] = 'HEAPF32';
return ['unary-prefix', '+', node[1][3]];
} else {
node[1][3][1][1] = 'HEAP32';
return ['binary', '|', node[1][3], ['num', 0]];
}
}
}
});
// finally, wipe out remaining ones by finding cases where all assignments to X are bitcasts, and all uses are writes to
// the other heap type, then eliminate the bitcast
var bitcastVars = {};
traverse(ast, function(node, type) {
if (type == 'assign' && node[1] === true && node[2][0] == 'name') {
var value = node[3];
if (value[0] == 'seq' && value[1][0] == 'assign' && value[1][2][0] == 'sub' && value[1][2][1][0] == 'name' &&
(value[1][2][1][1] == 'HEAP32' || value[1][2][1][1] == 'HEAPF32') &&
value[1][2][2][0] == 'binary' && value[1][2][2][2][0] == 'name' && value[1][2][2][2][1] == 'tempDoublePtr') {
var name = node[2][1];
if (!bitcastVars[name]) bitcastVars[name] = {
define_HEAP32: 0, define_HEAPF32: 0, use_HEAP32: 0, use_HEAPF32: 0, bad: false, namings: 0, defines: [], uses: []
};
bitcastVars[name]['define_' + value[1][2][1][1]]++;
bitcastVars[name].defines.push(node);
}
}
});
traverse(ast, function(node, type) {
if (type == 'name' && bitcastVars[node[1]]) {
bitcastVars[node[1]].namings++;
} else if (type == 'assign' && node[1] === true) {
var value = node[3];
if (value[0] == 'name') {
var name = value[1];
if (bitcastVars[name]) {
var target = node[2];
if (target[0] == 'sub' && target[1][0] == 'name' && (target[1][1] == 'HEAP32' || target[1][1] == 'HEAPF32')) {
bitcastVars[name]['use_' + target[1][1]]++;
bitcastVars[name].uses.push(node);
}
}
}
}
});
var asmData = normalizeAsm(ast);
for (var v in bitcastVars) {
var info = bitcastVars[v];
// good variables define only one type, use only one type, have definitions and uses, and define as a different type than they use
if (info.define_HEAP32*info.define_HEAPF32 == 0 && info.use_HEAP32*info.use_HEAPF32 == 0 &&
info.define_HEAP32+info.define_HEAPF32 > 0 && info.use_HEAP32+info.use_HEAPF32 > 0 &&
info.define_HEAP32*info.use_HEAP32 == 0 && info.define_HEAPF32*info.use_HEAPF32 == 0 &&
v in asmData.vars && info.namings == info.define_HEAP32+info.define_HEAPF32+info.use_HEAP32+info.use_HEAPF32) {
var correct = info.use_HEAP32 ? 'HEAPF32' : 'HEAP32';
info.defines.forEach(function(define) {
define[3] = define[3][1][3];
if (correct == 'HEAP32') {
define[3] = ['binary', '|', define[3], ['num', 0]];
} else {
define[3] = ['unary-prefix', '+', define[3]];
}
// do we want a simplifybitops on the new values here?
});
info.uses.forEach(function(use) {
use[2][1][1] = correct;
});
asmData.vars[v] = 1 - asmData.vars[v];
}
}
denormalizeAsm(ast, asmData);
}
// optimize num >> num, in asm we need this here since we do not run optimizeShifts
traverse(ast, function(node, type) {
if (type == 'binary' && node[1] == '>>' && node[2][0] == 'num' && node[3][0] == 'num') {
node[0] = 'num';
node[1] = node[2][1] >> node[3][1];
node.length = 2;
}
});
}
}
// The most common mathop is addition, e.g. in getelementptr done repeatedly. We can join all of those,
// by doing (num+num) ==> newnum, and (name+num)+num = name+newnum
function joinAdditions(ast) {
var rerun = true;
while (rerun) {
rerun = false;
traverse(ast, function(node, type) {
if (type == 'binary' && node[1] == '+') {
if (node[2][0] == 'num' && node[3][0] == 'num') {
rerun = true;
return ['num', node[2][1] + node[3][1]];
}
for (var i = 2; i <= 3; i++) {
var ii = 5-i;
for (var j = 2; j <= 3; j++) {
if (node[i][0] == 'num' && node[ii][0] == 'binary' && node[ii][1] == '+' && node[ii][j][0] == 'num') {
rerun = true;
node[ii][j][1] += node[i][1];
return node[ii];
}
}
}
}
});
}
}
// if (x == 0) can be if (!x), etc.
function simplifyZeroComp(ast) {
traverse(ast, function(node, type) {
var binary;
if (type == 'if' && (binary = node[1])[0] == 'binary') {
if ((binary[1] == '!=' || binary[1] == '!==') && binary[3][0] == 'num' && binary[3][1] == 0) {
node[1] = binary[2];
return node;
} else if ((binary[1] == '==' || binary[1] == '===') && binary[3][0] == 'num' && binary[3][1] == 0) {
node[1] = ['unary-prefix', '!', binary[2]];
return node;
}
}
});
}
function asmOpts(fun) {
// 1. Add final returns when necessary
// 2. Remove unneeded coercions on function calls that have no targets (eliminator removed it)
var returnType = null;
traverse(fun, function(node, type) {
if (type == 'return' && node[1]) {
returnType = detectAsmCoercion(node[1]);
} else if (type == 'stat') {
var inner = node[1];
if ((inner[0] == 'binary' && inner[1] in ASSOCIATIVE_BINARIES && inner[2][0] == 'call' && inner[3][0] == 'num') ||
(inner[0] == 'unary-prefix' && inner[1] == '+' && inner[2][0] == 'call')) {
node[1] = inner[2];
}
}
});
// Add a final return if one is missing.
if (returnType !== null) {
var stats = getStatements(fun);
var last = stats[stats.length-1];
if (last[0] != 'return') {
var returnValue = ['num', 0];
if (returnType == ASM_DOUBLE) returnValue = ['unary-prefix', '+', returnValue];
stats.push(['return', returnValue]);
}
}
}
traverseGeneratedFunctions(ast, function(func) {
simplifySignExtends(func);
simplifyBitops(func);
joinAdditions(func);
// simplifyZeroComp(func); TODO: investigate performance
if (asm) asmOpts(func);
});
}
// In typed arrays mode 2, we can have
// HEAP[x >> 2]
// very often. We can in some cases do the shift on the variable itself when it is set,
// to greatly reduce the number of shift operations.
// TODO: when shifting a variable, if there are other uses, keep an unshifted version too, to prevent slowdowns?
function optimizeShiftsInternal(ast, conservative) {
var MAX_SHIFTS = 3;
traverseGeneratedFunctions(ast, function(fun) {
var funMore = true;
var funFinished = {};
while (funMore) {
funMore = false;
// Recognize variables and parameters
var vars = {};
function newVar(name, param, addUse) {
if (!vars[name]) {
vars[name] = {
param: param,
defs: addUse ? 1 : 0,
uses: 0,
timesShifted: [0, 0, 0, 0], // zero shifts of size 0, 1, 2, 3
benefit: 0,
primaryShift: -1
};
}
}
// params
if (fun[2]) {
fun[2].forEach(function(arg) {
newVar(arg, true, true);
});
}
// vars
// XXX if var has >>=, ignore it here? That means a previous pass already optimized it
var hasSwitch = traverse(fun, function(node, type) {
if (type == 'var') {
node[1].forEach(function(arg) {
newVar(arg[0], false, arg[1]);
});
} else if (type == 'switch') {
// The relooper can't always optimize functions, and we currently don't work with
// switch statements when optimizing shifts. Bail.
return true;
}
});
if (hasSwitch) {
break;
}
// uses and defs TODO: weight uses by being inside a loop (powers). without that, we
// optimize for code size, not speed.
traverse(fun, function(node, type, stack) {
stack.push(node);
if (type == 'name' && vars[node[1]] && stack[stack.length-2][0] != 'assign') {
vars[node[1]].uses++;
} else if (type == 'assign' && node[2][0] == 'name' && vars[node[2][1]]) {
vars[node[2][1]].defs++;
}
}, null, []);
// First, break up elements inside a shift. This lets us see clearly what to do next.
traverse(fun, function(node, type) {
if (type == 'binary' && node[1] == '>>' && node[3][0] == 'num') {
var shifts = node[3][1];
if (shifts <= MAX_SHIFTS) {
// Push the >> inside the value elements
function addShift(subNode) {
if (subNode[0] == 'binary' && subNode[1] == '+') {
subNode[2] = addShift(subNode[2]);
subNode[3] = addShift(subNode[3]);
return subNode;
}
if (subNode[0] == 'name' && !subNode[2]) { // names are returned with a shift, but we also note their being shifted
var name = subNode[1];
if (vars[name]) {
vars[name].timesShifted[shifts]++;
subNode[2] = true;
}
}
return ['binary', '>>', subNode, ['num', shifts]];
}
return addShift(node[2]);
}
}
});
traverse(fun, function(node, type) {
if (node[0] == 'name' && node[2]) {
return node.slice(0, 2); // clean up our notes
}
});
// At this point, shifted expressions are split up, and we know who the vars are and their info, so we can decide
// TODO: vars that depend on other vars
for (var name in vars) {
var data = vars[name];
var totalTimesShifted = sum(data.timesShifted);
if (totalTimesShifted == 0) {
continue;
}
if (totalTimesShifted != Math.max.apply(null, data.timesShifted)) {
// TODO: Handle multiple different shifts
continue;
}
if (funFinished[name]) continue;
// We have one shift size (and possible unshifted uses). Consider replacing this variable with a shifted clone. If
// the estimated benefit is >0, we will do it
if (data.defs == 1) {
data.benefit = totalTimesShifted - 2*(data.defs + (data.param ? 1 : 0));
}
if (conservative) data.benefit = 0;
if (data.benefit > 0) {
funMore = true; // We will reprocess this function
for (var i = 0; i < 4; i++) {
if (data.timesShifted[i]) {
data.primaryShift = i;
}
}
}
}
//printErr(JSON.stringify(vars));
function cleanNotes() { // We need to mark 'name' nodes as 'processed' in some passes here; this cleans the notes up
traverse(fun, function(node, type) {
if (node[0] == 'name' && node[2]) {
return node.slice(0, 2);
}
});
}
cleanNotes();
// Apply changes
function needsShift(name) {
return vars[name] && vars[name].primaryShift >= 0;
}
for (var name in vars) { // add shifts for params and var's for all new variables
var data = vars[name];
if (needsShift(name)) {
if (data.param) {
fun[3].unshift(['var', [[name + '$s' + data.primaryShift, ['binary', '>>', ['name', name], ['num', data.primaryShift]]]]]);
} else {
fun[3].unshift(['var', [[name + '$s' + data.primaryShift]]]);
}
}
}
traverse(fun, function(node, type, stack) { // add shift to assignments
stack.push(node);
if (node[0] == 'assign' && node[1] === true && node[2][0] == 'name' && needsShift(node[2][1]) && !node[2][2]) {
var name = node[2][1];
var data = vars[name];
var parent = stack[stack.length-3];
var statements = getStatements(parent);
assert(statements, 'Invalid parent for assign-shift: ' + dump(parent));
var i = statements.indexOf(stack[stack.length-2]);
statements.splice(i+1, 0, ['stat', ['assign', true, ['name', name + '$s' + data.primaryShift], ['binary', '>>', ['name', name, true], ['num', data.primaryShift]]]]);
} else if (node[0] == 'var') {
var args = node[1];
for (var i = 0; i < args.length; i++) {
var arg = args[i];
var name = arg[0];
var data = vars[name];
if (arg[1] && needsShift(name)) {
args.splice(i+1, 0, [name + '$s' + data.primaryShift, ['binary', '>>', ['name', name, true], ['num', data.primaryShift]]]);
}
}
return node;
}
}, null, []);
cleanNotes();
traverse(fun, function(node, type, stack) { // replace shifted name with new variable
stack.push(node);
if (node[0] == 'binary' && node[1] == '>>' && node[2][0] == 'name' && needsShift(node[2][1]) && node[3][0] == 'num') {
var name = node[2][1];
var data = vars[name];
var parent = stack[stack.length-2];
// Don't modify in |x$sN = x >> 2|, in normal assigns and in var assigns
if (parent[0] == 'assign' && parent[2][0] == 'name' && parent[2][1] == name + '$s' + data.primaryShift) return;
if (parent[0] == name + '$s' + data.primaryShift) return;
if (node[3][1] == data.primaryShift) {
return ['name', name + '$s' + data.primaryShift];
}
}
}, null, []);
cleanNotes();
var SIMPLE_SHIFTS = set('<<', '>>');
var more = true;
while (more) { // combine shifts in the same direction as an optimization
more = false;
traverse(fun, function(node, type) {
if (node[0] == 'binary' && node[1] in SIMPLE_SHIFTS && node[2][0] == 'binary' && node[2][1] == node[1] &&
node[3][0] == 'num' && node[2][3][0] == 'num') { // do not turn a << b << c into a << b + c; while logically identical, it is slower
more = true;
return ['binary', node[1], node[2][2], ['num', node[3][1] + node[2][3][1]]];
}
});
}
// Before recombining, do some additional optimizations
traverse(fun, function(node, type) {
// Apply constant shifts onto constants
if (type == 'binary' && node[1] == '>>' && node[2][0] == 'num' && node[3][0] == 'num' && node[3][1] <= MAX_SHIFTS) {
var subNode = node[2];
var shifts = node[3][1];
var result = subNode[1] / Math.pow(2, shifts);
if (result % 1 == 0) {
subNode[1] = result;
return subNode;
}
}
// Optimize the case of ($a*80)>>2 into ($a*20)|0
if (type == 'binary' && node[1] in SIMPLE_SHIFTS &&
node[2][0] == 'binary' && node[2][1] == '*') {
var mulNode = node[2];
if (mulNode[2][0] == 'num') {
var temp = mulNode[2];
mulNode[2] = mulNode[3];
mulNode[3] = temp;
}
if (mulNode[3][0] == 'num') {
if (node[1] == '<<') {
mulNode[3][1] *= Math.pow(2, node[3][1]);
node[1] = '|';
node[3][1] = 0;
return node;
} else {
if (mulNode[3][1] % Math.pow(2, node[3][1]) == 0) {
mulNode[3][1] /= Math.pow(2, node[3][1]);
node[1] = '|';
node[3][1] = 0;
return node;
}
}
}
}
/* XXX - theoretically useful optimization(s), but commented out as not helpful in practice
// Transform (x << 2) >> 2 into x & mask or something even simpler
if (type == 'binary' && node[1] == '>>' && node[3][0] == 'num' &&
node[2][0] == 'binary' && node[2][1] == '<<' && node[2][3][0] == 'num' && node[3][1] == node[2][3][1]) {
var subNode = node[2];
var shifts = node[3][1];
var mask = ((0xffffffff << shifts) >>> shifts) | 0;
return ['binary', '&', subNode[2], ['num', mask]];
//return ['binary', '|', subNode[2], ['num', 0]];
//return subNode[2];
}
*/
});
// Re-combine remaining shifts, to undo the breaking up we did before. may require reordering inside +'s
traverse(fun, function(node, type, stack) {
stack.push(node);
if (type == 'binary' && node[1] == '+' && (stack[stack.length-2][0] != 'binary' || stack[stack.length-2][1] != '+')) {
// 'Flatten' added items
var addedItems = [];
function flatten(node) {
if (node[0] == 'binary' && node[1] == '+') {
flatten(node[2]);
flatten(node[3]);
} else {
addedItems.push(node);
}
}
flatten(node);
var originalOrder = addedItems.slice();
function key(node) { // a unique value for all relevant shifts for recombining, non-unique for stuff we don't need to bother with
function originalOrderKey(item) {
return -originalOrder.indexOf(item);
}
if (node[0] == 'binary' && node[1] in SIMPLE_SHIFTS) {
if (node[3][0] == 'num' && node[3][1] <= MAX_SHIFTS) return 2*node[3][1] + (node[1] == '>>' ? 100 : 0); // 0-106
return (node[1] == '>>' ? 20000 : 10000) + originalOrderKey(node);
}
if (node[0] == 'num') return -20000 + node[1];
return -10000 + originalOrderKey(node); // Don't modify the original order if we don't modify anything
}
for (var i = 0; i < addedItems.length; i++) {
if (addedItems[i][0] == 'string') return; // this node is not relevant for us
}
addedItems.sort(function(node1, node2) {
return key(node1) - key(node2);
});
// Regenerate items, now sorted
var i = 0;
while (i < addedItems.length-1) { // re-combine inside addedItems
var k = key(addedItems[i]), k1 = key(addedItems[i+1]);
if (k == k1 && k >= 0 && k1 <= 106) {
addedItems[i] = ['binary', addedItems[i][1], ['binary', '+', addedItems[i][2], addedItems[i+1][2]], addedItems[i][3]];
addedItems.splice(i+1, 1);
} else {
i++;
}
}
var num = 0;
for (i = 0; i < addedItems.length; i++) { // combine all numbers into one
if (addedItems[i][0] == 'num') {
num += addedItems[i][1];
addedItems.splice(i, 1);
i--;
}
}
if (num != 0) { // add the numbers into an existing shift, we
// prefer (x+5)>>7 over (x>>7)+5 , since >>'s result is known to be 32-bit and is more easily optimized.
// Also, in the former we can avoid the parentheses, which saves a little space (the number will be bigger,
// so it might take more space, but normally at most one more digit).
var added = false;
for (i = 0; i < addedItems.length; i++) {
if (addedItems[i][0] == 'binary' && addedItems[i][1] == '>>' && addedItems[i][3][0] == 'num' && addedItems[i][3][1] <= MAX_SHIFTS) {
addedItems[i] = ['binary', '>>', ['binary', '+', addedItems[i][2], ['num', num << addedItems[i][3][1]]], addedItems[i][3]];
added = true;
}
}
if (!added) {
addedItems.unshift(['num', num]);
}
}
var ret = addedItems.pop();
while (addedItems.length > 0) { // re-create AST from addedItems
ret = ['binary', '+', ret, addedItems.pop()];
}
return ret;
}
}, null, []);
// Note finished variables
for (var name in vars) {
funFinished[name] = true;
}
}
});
}
function optimizeShiftsConservative(ast) {
optimizeShiftsInternal(ast, true);
}
function optimizeShiftsAggressive(ast) {
optimizeShiftsInternal(ast, false);
}
// We often have branchings that are simplified so one end vanishes, and
// we then get
// if (!(x < 5))
// or such. Simplifying these saves space and time.
function simplifyNotCompsDirect(node) {
if (node[0] == 'unary-prefix' && node[1] == '!') {
if (node[2][0] == 'binary') {
switch(node[2][1]) {
case '<': return ['binary', '>=', node[2][2], node[2][3]];
case '>': return ['binary', '<=', node[2][2], node[2][3]];
case '<=': return ['binary', '>', node[2][2], node[2][3]];
case '>=': return ['binary', '<', node[2][2], node[2][3]];
case '==': return ['binary', '!=', node[2][2], node[2][3]];
case '!=': return ['binary', '==', node[2][2], node[2][3]];
case '===': return ['binary', '!==', node[2][2], node[2][3]];
case '!==': return ['binary', '===', node[2][2], node[2][3]];
}
} else if (node[2][0] == 'unary-prefix' && node[2][1] == '!') {
return node[2][2];
}
}
return node;
}
function simplifyNotComps(ast) {
traverse(ast, simplifyNotCompsDirect);
}
function simplifyExpressionsPost(ast) {
simplifyNotComps(ast);
}
var NO_SIDE_EFFECTS = set('num', 'name');
function hasSideEffects(node) { // this is 99% incomplete!
if (node[0] in NO_SIDE_EFFECTS) return false;
if (node[0] == 'unary-prefix') return hasSideEffects(node[2]);
if (node[0] == 'binary') return hasSideEffects(node[2]) || hasSideEffects(node[3]);
return true;
}
// Clear out empty ifs and blocks, and redundant blocks/stats and so forth
// Operates on generated functions only
function vacuum(ast) {
function isEmpty(node) {
if (!node) return true;
if (node[0] == 'toplevel' && (!node[1] || node[1].length == 0)) return true;
if (node[0] == 'block' && (!node[1] || (typeof node[1] != 'object') || node[1].length == 0 || (node[1].length == 1 && isEmpty(node[1])))) return true;
return false;
}
function simplifyList(node, si) {
var changed = false;
// Merge block items into this list, thus removing unneeded |{ .. }|'s
var statements = node[si];
var i = 0;
while (i < statements.length) {
var subNode = statements[i];
if (subNode[0] == 'block') {
statements.splice.apply(statements, [i, 1].concat(subNode[1] || []));
changed = true;
} else {
i++;
}
}
// Remove empty items
var pre = node[si].length;
node[si] = node[si].filter(function(node) { return !isEmpty(node) });
if (node[si].length < pre) changed = true;
if (changed) {
return node;
}
}
function vacuumInternal(node) {
traverseChildren(node, vacuumInternal);
var ret;
switch(node[0]) {
case 'block': {
if (node[1] && node[1].length == 1 && node[1][0][0] == 'block') {
return node[1][0];
} else if (typeof node[1] == 'object') {
ret = simplifyList(node, 1);
if (ret) return ret;
}
} break;
case 'stat': {
if (node[1][0] == 'block') {
return node[1];
}
} break;
case 'defun': {
if (node[3].length == 1 && node[3][0][0] == 'block') {
node[3] = node[3][0][1];
return node;
} else {
ret = simplifyList(node, 3);
if (ret) return ret;
}
} break;
case 'do': {
if (node[1][0] == 'num' && node[2][0] == 'toplevel' && (!node[2][1] || node[2][1].length == 0)) {
return emptyNode();
} else if (isEmpty(node[2]) && !hasSideEffects(node[1])) {
return emptyNode();
}
} break;
case 'label': {
if (node[2][0] == 'toplevel' && (!node[2][1] || node[2][1].length == 0)) {
return emptyNode();
}
} break;
case 'if': {
var empty2 = isEmpty(node[2]), empty3 = isEmpty(node[3]), has3 = node.length == 4;
if (!empty2 && empty3 && has3) { // empty else clauses
return node.slice(0, 3);
} else if (empty2 && !empty3) { // empty if blocks
return ['if', ['unary-prefix', '!', node[1]], node[3]];
} else if (empty2 && empty3) {
if (hasSideEffects(node[1])) {
return ['stat', node[1]];
} else {
return emptyNode();
}
}
} break;
}
}
traverseGeneratedFunctions(ast, function(node) {
vacuumInternal(node);
simplifyNotComps(node);
});
}
function getStatements(node) {
if (node[0] == 'defun') {
return node[3];
} else if (node[0] == 'block') {
return node[1];
} else {
return null;
}
}
// Multiple blocks from the relooper are, in general, implemented by
// if (label == x) { } else if ..
// and branching into them by
// if (condition) { label == x } else ..
// We can hoist the multiple block into the condition, thus removing code and one 'if' check
function hoistMultiples(ast) {
traverseGeneratedFunctions(ast, function(node) {
traverse(node, function(node, type) {
var statements = getStatements(node);
if (!statements) return;
var modified = false;
for (var i = 0; i < statements.length-1; i++) {
var modifiedI = false;
var pre = statements[i];
if (pre[0] != 'if') continue;
var post = statements[i+1];
// Look into some block types. shell() will then recreate the shell that we looked into
var postInner = post;
var shellLabel = false, shellDo = false;
while (true) {
if (postInner[0] == 'label') {
shellLabel = postInner[1];
postInner = postInner[2];
} else if (postInner[0] == 'do') {
shellDo = postInner[1];
postInner = postInner[2][1][0];
} else {
break; // give up
}
}
if (postInner[0] != 'if') continue;
// Look into this if, and its elseifs
while (postInner && postInner[0] == 'if') {
var cond = postInner[1];
if (cond[0] == 'binary' && cond[1] == '==' && cond[2][0] == 'name' && cond[2][1] == 'label') {
assert(cond[3][0] == 'num');
// We have a valid Multiple check here. Try to hoist it, look for the source in |pre| and its else's
var labelNum = cond[3][1];
var labelBlock = postInner[2];
assert(labelBlock[0] == 'block');
var found = false;
traverse(pre, function(preNode, preType) {
if (!found && preType == 'assign' && preNode[2][0] == 'name' && preNode[2][1] == 'label') {
assert(preNode[3][0] == 'num');
if (preNode[3][1] == labelNum) {
// That's it! Hoist away. We can also throw away the label setting as its goal has already been achieved
found = true;
modifiedI = true;
postInner[2] = ['block', []];
return labelBlock;
}
}
});
}
postInner = postInner[3]; // Proceed to look in the else clause
}
if (modifiedI) {
if (shellDo) {
statements[i] = ['do', shellDo, ['block', [statements[i]]]];
}
if (shellLabel) {
statements[i] = ['label', shellLabel, statements[i]];
}
}
}
if (modified) return node;
});
// After hoisting in this function, it is safe to remove { label = x; } blocks, because
// if they were leading to the next code right after them, they would be hoisted, and if they
// are going to some other place entirely, they would break or continue. The only risky
// situation is if the code after us is a multiple, in which case we might be checking for
// this label inside it (or in a later multiple, even)
function tryEliminate(node) {
if (node[0] == 'if') {
var replaced;
if (replaced = tryEliminate(node[2])) node[2] = replaced;
if (node[3] && (replaced = tryEliminate(node[3]))) node[3] = replaced;
} else {
if (node[0] == 'block' && node[1] && node[1].length > 0) {
var subNode = node[1][node[1].length-1];
if (subNode[0] == 'stat' && subNode[1][0] == 'assign' && subNode[1][2][0] == 'name' &&
subNode[1][2][1] == 'label' && subNode[1][3][0] == 'num') {
if (node[1].length == 1) {
return emptyNode();
} else {
node[1].splice(node[1].length-1, 1);
return node;
}
}
}
}
return false;
}
function getActualStatement(node) { // find the actual active statement, ignoring a label and one-time do loop
if (node[0] == 'label') node = node[2];
if (node[0] == 'do') node = node[2];
if (node[0] == 'block' && node[1].length == 1) node = node[1][0];
return node;
}
vacuum(node);
traverse(node, function(node, type) {
var statements = getStatements(node);
if (!statements) return;
for (var i = 0; i < statements.length-1; i++) {
var curr = getActualStatement(statements[i]);
var next = statements[i+1];
if (curr[0] == 'if' && next[0] != 'if' && next[0] != 'label' && next[0] != 'do' && next[0] != 'while') {
tryEliminate(curr);
}
}
});
});
vacuum(ast);
// Afterpass: Reduce
// if (..) { .. break|continue } else { .. }
// to
// if (..) { .. break|continue } ..
traverseGenerated(ast, function(container, type) {
var statements = getStatements(container);
if (!statements) return;
for (var i = 0; i < statements.length; i++) {
var node = statements[i];
if (node[0] == 'if' && node[2][0] == 'block' && node[3] && node[3][0] == 'block') {
var stat1 = node[2][1], stat2 = node[3][1];
// If break|continue in the latter and not the former, reverse them
if (!(stat1[stat1.length-1][0] in LOOP_FLOW) && (stat2[stat2.length-1][0] in LOOP_FLOW)) {
var temp = node[3];
node[3] = node[2];
node[2] = temp;
node[1] = simplifyNotCompsDirect(['unary-prefix', '!', node[1]]);
stat1 = node[2][1];
stat2 = node[3][1];
}
if (stat1[stat1.length-1][0] in LOOP_FLOW) {
statements.splice.apply(statements, [i+1, 0].concat(stat2));
node[3] = null;
}
}
}
});
}
// Simplifies loops
// WARNING: This assumes all loops and breaks/continues are labelled
function loopOptimizer(ast) {
// Remove unneeded labels and one-time (do while(0)) loops. It is convenient to do these both at once.
function passTwo(ast) {
var neededDos = [];
// Find unneeded labels
traverseGenerated(ast, function(node, type, stack) {
if (type == 'label' && node[2][0] in LOOP) {
// this is a labelled loop. we don't know if it's needed yet. Mark its label for removal for now now.
stack.push(node);
node[1] = '+' + node[1];
} else if (type in LOOP) {
stack.push(node);
} else if (type in LOOP_FLOW) {
// Find topmost loop, and its label if there is one
var lastLabel = null, lastLoop = null, i = stack.length-1;
while (i >= 0 && !lastLoop) {
if (stack[i][0] in LOOP) lastLoop = stack[i];
i--;
}
assert(lastLoop, 'Cannot break/continue without a Label');
while (i >= 0 && !lastLabel) {
if (stack[i][0] in LOOP) break; // another loop in the middle - no label for lastLoop
if (stack[i][0] == 'label') lastLabel = stack[i];
i--;
}
var ident = node[1]; // there may not be a label ident if this is a simple break; or continue;
var plus = '+' + ident;
if (lastLabel && ident && (ident == lastLabel[1] || plus == lastLabel[1])) {
// If this is a 'do' loop, this break means we actually need it.
neededDos.push(lastLoop);
// We don't need the control flow command to have a label - it's referring to the current loop
return [node[0]];
} else {
if (!ident) {
// No label on the break/continue, so keep the last loop alive (no need for its label though)
neededDos.push(lastLoop);
} else {
// Find the label node that needs to stay alive
stack.forEach(function(label) {
if (!label) return;
if (label[1] == plus) label[1] = label[1].substr(1); // Remove '+', marking it as needed
});
}
}
}
}, null, []);
// We return whether another pass is necessary
var more = false;
// Remove unneeded labels
traverseGenerated(ast, function(node, type) {
if (type == 'label' && node[1][0] == '+') {
more = true;
var ident = node[1].substr(1);
// Remove label from loop flow commands
traverse(node[2], function(node2, type) {
if (type in LOOP_FLOW && node2[1] == ident) {
return [node2[0]];
}
});
return node[2]; // Remove the label itself on the loop
}
});
// Remove unneeded one-time loops. We need such loops if (1) they have a label, or (2) they have a direct break so they are in neededDos.
// First, add all labeled loops of this nature to neededDos
traverseGenerated(ast, function(node, type) {
if (type == 'label' && node[2][0] == 'do') {
neededDos.push(node[2]);
}
});
// Remove unneeded dos, we know who they are now
traverseGenerated(ast, function(node, type) {
if (type == 'do' && neededDos.indexOf(node) < 0) {
assert(jsonCompare(node[1], ['num', 0]), 'Trying to remove a one-time do loop that is not one of our generated ones.;');
more = true;
return node[2];
}
});
return more;
}
// Go
// TODO: pass 1: Removal of unneeded continues, breaks if they get us to where we are already going. That will
// help the next pass.
// Multiple pass two runs may be needed, as we remove one-time loops and so forth
do {
var more = passTwo(ast);
vacuum(ast);
} while (more);
vacuum(ast);
}
function unVarify(vars, ret) { // transform var x=1, y=2 etc. into (x=1, y=2), i.e., the same assigns, but without a var definition
ret = ret || [];
ret[0] = 'stat';
if (vars.length == 1) {
ret[1] = ['assign', true, ['name', vars[0][0]], vars[0][1]];
} else {
ret[1] = [];
var curr = ret[1];
for (var i = 0; i < vars.length-1; i++) {
curr[0] = 'seq';
curr[1] = ['assign', true, ['name', vars[i][0]], vars[i][1]];
if (i != vars.length-2) curr = curr[2] = [];
}
curr[2] = ['assign', true, ['name', vars[vars.length-1][0]], vars[vars.length-1][1]];
}
return ret;
}
// asm.js support code - normalize (convert asm.js code to 'normal' JS, without
// annotations, plus explicit metadata) and denormalize (vice versa)
var ASM_INT = 0;
var ASM_DOUBLE = 1;
function detectAsmCoercion(node) {
// for params, +x vs x|0, for vars, 0.0 vs 0
if (node[0] == 'num' && node[1].toString().indexOf('.') >= 0) return ASM_DOUBLE;
return node[0] == 'unary-prefix' ? ASM_DOUBLE : ASM_INT;
}
function makeAsmParamCoercion(param, type) {
return type == ASM_INT ? ['binary', '|', ['name', param], ['num', 0]] : ['unary-prefix', '+', ['name', param]];
}
function makeAsmVarDef(v, type) {
return [v, type == ASM_INT ? ['num', 0] : ['unary-prefix', '+', ['num', 0]]];
}
function normalizeAsm(func) {
//printErr('pre-normalize \n\n' + astToSrc(func) + '\n\n');
var data = {
params: {}, // ident => ASM_* type
vars: {}, // ident => ASM_* type
};
// process initial params
var stats = func[3];
var i = 0;
while (i < stats.length) {
var node = stats[i];
if (node[0] != 'stat' || node[1][0] != 'assign' || node[1][2][0] != 'name') break;
node = node[1];
var name = node[2][1];
if (func[2] && func[2].indexOf(name) < 0) break; // not an assign into a parameter, but a global
data.params[name] = detectAsmCoercion(node[3]);
stats[i] = emptyNode();
i++;
}
// process initial variable definitions
outer:
while (i < stats.length) {
var node = stats[i];
if (node[0] != 'var') break;
for (var j = 0; j < node[1].length; j++) {
var v = node[1][j];
var name = v[0];
var value = v[1];
if (!(name in data.vars)) {
assert(value[0] == 'num' || (value[0] == 'unary-prefix' && value[2][0] == 'num')); // must be valid coercion no-op
data.vars[name] = detectAsmCoercion(value);
v.length = 1; // make an un-assigning var
} else {
break outer;
}
}
i++;
}
// finally, look for other var definitions and collect them
while (i < stats.length) {
traverse(stats[i], function(node, type) {
if (type == 'var') {
for (var j = 0; j < node[1].length; j++) {
var v = node[1][j];
var name = v[0];
var value = v[1];
if (!(name in data.vars)) {
if (value[0] != 'name') {
data.vars[name] = detectAsmCoercion(value); // detect by coercion
} else {
var origin = value[1];
data.vars[name] = data.vars[origin] || ASM_INT; // detect by origin variable, or assume int for non-locals
}
}
}
unVarify(node[1], node);
} else if (type == 'dot') {
if (node[1][0] == 'name' && node[1][1] == 'Math') {
// transform Math.max to Math_max; we forward in the latter version
node[0] = 'name';
node[1] = 'Math_' + node[2];
}
}
});
i++;
}
//printErr('normalized \n\n' + astToSrc(func) + '\n\nwith: ' + JSON.stringify(data));
return data;
}
function denormalizeAsm(func, data) {
//printErr('pre-denormalize \n\n' + astToSrc(func) + '\n\nwith: ' + JSON.stringify(data));
var stats = func[3];
// Remove var definitions, if any
for (var i = 0; i < stats.length; i++) {
if (stats[i][0] == 'var') {
stats[i] = emptyNode();
} else {
if (!isEmptyNode(stats[i])) break;
}
}
// each param needs a line; reuse emptyNodes as much as we can
var numParams = 0;
for (var i in data.params) numParams++;
var emptyNodes = 0;
while (emptyNodes < stats.length) {
if (!isEmptyNode(stats[emptyNodes])) break;
emptyNodes++;
}
var neededEmptyNodes = numParams + 1; // params plus one big var
if (neededEmptyNodes > emptyNodes) {
var args = [0, 0];
for (var i = 0; i < neededEmptyNodes - emptyNodes; i++) args[i+2] = 0;
stats.splice.apply(stats, args);
}
// add param coercions
var next = 0;
func[2].forEach(function(param) {
stats[next++] = ['stat', ['assign', true, ['name', param], makeAsmParamCoercion(param, data.params[param])]];
});
// add variable definitions
var varDefs = [];
for (var v in data.vars) {
varDefs.push(makeAsmVarDef(v, data.vars[v]));
}
if (varDefs.length) {
stats[next] = ['var', varDefs];
} else {
stats[next] = emptyNode();
}
//printErr('denormalized \n\n' + astToSrc(func) + '\n\n');
}
// Very simple 'registerization', coalescing of variables into a smaller number,
// as part of minification. Globals-level minification began in a previous pass,
// we receive minifierInfo which tells us how to rename globals. (Only in asm.js.)
//
// We do not optimize when there are switches, so this pass only makes sense with
// relooping.
// TODO: Consider how this fits in with the rest of the optimization toolchain. Do
// we still need the eliminator? Closure? And in what order? Perhaps just
// closure simple?
function registerize(ast) {
traverseGeneratedFunctions(ast, function(fun) {
if (asm) var asmData = normalizeAsm(fun);
// Add parameters as a first (fake) var (with assignment), so they get taken into consideration
var params = {}; // note: params are special, they can never share a register between them (see later)
if (fun[2] && fun[2].length) {
var assign = ['num', 0];
fun[3].unshift(['var', fun[2].map(function(param) {
params[param] = 1;
return [param, assign];
})]);
}
if (asm) {
// copy params into vars
for (var p in asmData.params) asmData.vars[p] = asmData.params[p];
//printErr('fake params: \n\n' + astToSrc(fun) + '\n\n');
}
// Replace all var definitions with assignments; we will add var definitions at the top after we registerize
// We also mark local variables - i.e., having a var definition
var localVars = {};
var hasSwitch = false; // we cannot optimize variables if there is a switch, unless in asm mode
traverse(fun, function(node, type) {
if (type == 'var') {
node[1].forEach(function(defined) { localVars[defined[0]] = 1 });
var vars = node[1].filter(function(varr) { return varr[1] });
if (vars.length >= 1) {
return unVarify(vars);
} else {
return emptyNode();
}
} else if (type == 'switch') {
hasSwitch = true;
}
});
vacuum(fun);
if (minifierInfo) {
assert(asm);
var usedGlobals = {};
var nextLocal = 0;
// Minify globals using the mapping we were given
traverse(fun, function(node, type) {
if (type == 'name') {
var name = node[1];
var minified = minifierInfo.globals[name];
if (minified) {
assert(!localVars[name], name); // locals must not shadow globals, or else we don't know which is which
if (localVars[minified]) {
// trying to minify a global into a name used locally. rename all the locals
var newName = '$_newLocal_' + (nextLocal++);
assert(!localVars[newName]);
if (params[minified]) {
params[newName] = 1;
delete params[minified];
}
localVars[newName] = 1;
delete localVars[minified];
asmData.vars[newName] = asmData.vars[minified];
delete asmData.vars[minified];
asmData.params[newName] = asmData.params[minified];
delete asmData.params[minified];
traverse(fun, function(node, type) {
if (type == 'name' && node[1] == minified) {
node[1] = newName;
}
});
if (fun[2]) {
for (var i = 0; i < fun[2].length; i++) {
if (fun[2][i] == minified) fun[2][i] = newName;
}
}
}
node[1] = minified;
usedGlobals[minified] = 1;
}
}
});
assert(fun[1] in minifierInfo.globals, fun[1]);
fun[1] = minifierInfo.globals[fun[1]];
assert(fun[1]);
var nextRegName = 0;
}
var regTypes = {};
function getNewRegName(num, name) {
if (!asm) return 'r' + num;
var type = asmData.vars[name];
if (!minifierInfo) {
var ret = (type ? 'd' : 'i') + num;
regTypes[ret] = type;
return ret;
}
// find the next free minified name that is not used by a global that shows up in this function
while (nextRegName < minifierInfo.names.length) {
var ret = minifierInfo.names[nextRegName++];
if (!usedGlobals[ret]) {
regTypes[ret] = type;
return ret;
}
}
assert('ran out of names');
}
// Find the # of uses of each variable.
// While doing so, check if all a variable's uses are dominated in a simple
// way by a simple assign, if so, then we can assign its register to it
// just for its definition to its last use, and not to the entire toplevel loop,
// we call such variables "optimizable"
var varUses = {};
var level = 1;
var levelDominations = {};
var varLevels = {};
var possibles = {};
var unoptimizables = {};
function purgeLevel() {
// Invalidate all dominating on this level, further users make it unoptimizable
for (var name in levelDominations[level]) {
varLevels[name] = 0;
}
levelDominations[level] = null;
level--;
}
traverse(fun, function possibilifier(node, type) {
if (type == 'name') {
var name = node[1];
if (localVars[name]) {
if (!varUses[name]) varUses[name] = 0;
varUses[name]++;
if (possibles[name] && !varLevels[name]) unoptimizables[name] = 1; // used outside of simple domination
}
} else if (type == 'assign' && typeof node[1] != 'string') {
if (node[2] && node[2][0] == 'name') {
var name = node[2][1];
// if local and not yet used, this might be optimizable if we dominate
// all other uses
if (localVars[name] && !varUses[name] && !varLevels[name]) {
possibles[name] = 1;
varLevels[name] = level;
if (!levelDominations[level]) levelDominations[level] = {};
levelDominations[level][name] = 1;
}
}
} else if (type in CONTROL_FLOW) {
// recurse children, in the context of a loop
switch(type) {
case 'while': case 'do': {
traverse(node[1], possibilifier);
level++;
traverse(node[2], possibilifier);
purgeLevel();
break;
}
case 'for': {
traverse(node[1], possibilifier);
for (var i = 2; i <= 4; i++) {
level++;
traverse(node[i], possibilifier);
purgeLevel();
}
break;
}
case 'if': {
traverse(node[1], possibilifier);
level++;
traverse(node[2], possibilifier);
purgeLevel();
if (node[3]) {
level++;
traverse(node[3], possibilifier);
purgeLevel();
}
break;
}
case 'switch': {
traverse(node[1], possibilifier);
var cases = node[2];
for (var i = 0; i < cases.length; i++) {
level++;
traverse(cases[i][1], possibilifier);
purgeLevel();
}
break;
}
default: throw dumpAst(node);
}
return null; // prevent recursion into children, which we already did
}
});
var optimizables = {};
if (!hasSwitch || asm) {
for (var possible in possibles) {
if (!unoptimizables[possible]) optimizables[possible] = 1;
}
}
//printErr('optimizables: ' + JSON.stringify(optimizables));
//printErr('unoptimizables: ' + JSON.stringify(unoptimizables));
// Go through the function's code, assigning 'registers'.
// The only tricky bit is to keep variables locked on a register through loops,
// since they can potentially be returned to. Optimizable variables lock onto
// loops that they enter, unoptimizable variables lock in a conservative way
// into the topmost loop.
// Note that we cannot lock onto a variable in a loop if it was used and free'd
// before! (then they could overwrite us in the early part of the loop). For now
// we just use a fresh register to make sure we avoid this, but it could be
// optimized to check for safe registers (free, and not used in this loop level).
var varRegs = {}; // maps variables to the register they will use all their life
var freeRegsClasses = asm ? [[], []] : []; // two classes for asm, one otherwise
var nextReg = 1;
var fullNames = {};
var loopRegs = {}; // for each loop nesting level, the list of bound variables
var loops = 0; // 0 is toplevel, 1 is first loop, etc
var saved = 0;
var activeOptimizables = {};
var optimizableLoops = {};
var paramRegs = {}; // true if the register is used by a parameter (and so needs no def at start of function; also cannot
// be shared with another param, each needs its own)
function decUse(name) {
if (!varUses[name]) return false; // no uses left, or not a relevant variable
if (optimizables[name]) activeOptimizables[name] = 1;
var reg = varRegs[name];
if (asm) assert(name in asmData.vars, name);
var freeRegs = asm ? freeRegsClasses[asmData.vars[name]] : freeRegsClasses;
if (!reg) {
// acquire register
if (optimizables[name] && freeRegs.length > 0 &&
!(params[name] && paramRegs[freeRegs[freeRegs.length-1]])) { // do not share registers between parameters
reg = freeRegs.pop();
saved++;
} else {
reg = nextReg++;
fullNames[reg] = getNewRegName(reg, name);
if (params[name]) paramRegs[reg] = 1;
}
varRegs[name] = reg;
}
varUses[name]--;
assert(varUses[name] >= 0);
if (varUses[name] == 0) {
if (optimizables[name]) delete activeOptimizables[name];
// If we are not in a loop, or we are optimizable and not bound to a loop
// (we might have been in one but left it), we can free the register now.
if (loops == 0 || (optimizables[name] && !optimizableLoops[name])) {
// free register
freeRegs.push(reg);
} else {
// when the relevant loop is exited, we will free the register
var releventLoop = optimizables[name] ? (optimizableLoops[name] || 1) : 1;
if (!loopRegs[releventLoop]) loopRegs[releventLoop] = [];
loopRegs[releventLoop].push(reg);
}
}
return true;
}
traverse(fun, function(node, type) { // XXX we rely on traversal order being the same as execution order here
if (type == 'name') {
var name = node[1];
if (decUse(name)) {
node[1] = fullNames[varRegs[name]];
}
} else if (type in LOOP) {
loops++;
// Active optimizables lock onto this loop, if not locked onto one that encloses this one
for (var name in activeOptimizables) {
if (!optimizableLoops[name]) {
optimizableLoops[name] = loops;
}
}
}
}, function(node, type) {
if (type in LOOP) {
// Free registers that were locked to this loop
if (loopRegs[loops]) {
if (asm) {
loopRegs[loops].forEach(function(loopReg) {
freeRegsClasses[regTypes[fullNames[loopReg]]].push(loopReg);
});
} else {
freeRegsClasses = freeRegsClasses.concat(loopRegs[loops]);
}
loopRegs[loops].length = 0;
}
loops--;
}
});
if (fun[2] && fun[2].length) {
fun[2].length = 0; // clear params, we will fill with registers
fun[3].shift(); // remove fake initial var
}
//printErr('var regs: ' + JSON.stringify(varRegs) + '\n\nparam regs: ' + JSON.stringify(paramRegs));
if (!asm) {
if (nextReg > 1) {
var vars = [];
for (var i = 1; i < nextReg; i++) {
var reg = fullNames[i];
if (!paramRegs[i]) {
vars.push([reg]);
} else {
fun[2].push(reg);
}
}
if (vars.length > 0) getStatements(fun).unshift(['var', vars]);
}
} else {
//printErr('unfake params: \n\n' + astToSrc(fun) + '\n\n');
var finalAsmData = {
params: {},
vars: {},
};
for (var i = 1; i < nextReg; i++) {
var reg = fullNames[i];
var type = regTypes[reg];
if (!paramRegs[i]) {
finalAsmData.vars[reg] = type;
} else {
finalAsmData.params[reg] = type;
fun[2].push(reg);
}
}
denormalizeAsm(fun, finalAsmData);
}
});
}
// Eliminator aka Expressionizer
//
// The goal of this pass is to eliminate unneeded variables (which represent one of the infinite registers in the LLVM
// model) and thus to generate complex expressions where possible, for example
//
// var x = a(10);
// var y = HEAP[20];
// print(x+y);
//
// can be transformed into
//
// print(a(10)+HEAP[20]);
//
// The basic principle is to scan along the code in the order of parsing/execution, and keep a list of tracked
// variables that are current contenders for elimination. We must untrack when we see something that we cannot
// cross, for example, a write to memory means we must invalidate variables that depend on reading from
// memory, since if we change the order then we do not preserve the computation.
//
// We rely on some assumptions about emscripten-generated code here, which means we can do a lot more than
// a general JS optimization can. For example, we assume that 'sub' nodes (indexing like HEAP[..]) are
// memory accesses or FUNCTION_TABLE accesses, and in both cases that the symbol cannot be replaced although
// the contents can. So we assume FUNCTION_TABLE might have its contents changed but not be pointed to
// a different object, which allows
//
// var x = f();
// FUNCTION_TABLE[x]();
//
// to be optimized (f could replace FUNCTION_TABLE, so in general JS eliminating x is not valid).
//
// In memSafe mode, we are more careful and assume functions can replace HEAP and FUNCTION_TABLE, which
// can happen in ALLOW_MEMORY_GROWTH mode
var ELIMINATION_SAFE_NODES = set('var', 'assign', 'call', 'if', 'toplevel', 'do', 'return', 'label', 'switch'); // do is checked carefully, however
var NODES_WITHOUT_ELIMINATION_SIDE_EFFECTS = set('name', 'num', 'string', 'binary', 'sub', 'unary-prefix');
var IGNORABLE_ELIMINATOR_SCAN_NODES = set('num', 'toplevel', 'string', 'break', 'continue', 'dot'); // dot can only be STRING_TABLE.*
var ABORTING_ELIMINATOR_SCAN_NODES = set('new', 'object', 'function', 'defun', 'for', 'while', 'array', 'throw'); // we could handle some of these, TODO, but nontrivial (e.g. for while, the condition is hit multiple times after the body)
function isTempDoublePtrAccess(node) { // these are used in bitcasts; they are not really affecting memory, and should cause no invalidation
assert(node[0] == 'sub');
return (node[2][0] == 'name' && node[2][1] == 'tempDoublePtr') ||
(node[2][0] == 'binary' && ((node[2][2][0] == 'name' && node[2][2][1] == 'tempDoublePtr') ||
(node[2][3][0] == 'name' && node[2][3][1] == 'tempDoublePtr')));
}
function eliminate(ast, memSafe) {
// Find variables that have a single use, and if they can be eliminated, do so
traverseGeneratedFunctions(ast, function(func, type) {
if (asm) var asmData = normalizeAsm(func);
//printErr('eliminate in ' + func[1]);
// First, find the potentially eliminatable functions: that have one definition and one use
var definitions = {};
var uses = {};
var namings = {};
var values = {};
var locals = {};
var varsToRemove = {}; // variables being removed, that we can eliminate all 'var x;' of (this refers to 'var' nodes we should remove)
// 1 means we should remove it, 2 means we successfully removed it
var varsToTryToRemove = {}; // variables that have 0 uses, but have side effects - when we scan we can try to remove them
// add arguments as locals
if (func[2]) {
for (var i = 0; i < func[2].length; i++) {
locals[func[2][i]] = true;
}
}
// examine body and note locals
var hasSwitch = false;
traverse(func, function(node, type) {
if (type === 'var') {
var node1 = node[1];
for (var i = 0; i < node1.length; i++) {
var node1i = node1[i];
var name = node1i[0];
var value = node1i[1];
if (value) {
if (!(name in definitions)) definitions[name] = 0;
definitions[name]++;
if (!values[name]) values[name] = value;
}
if (!uses[name]) uses[name] = 0;
locals[name] = true;
}
} else if (type === 'name') {
var name = node[1];
if (!uses[name]) uses[name] = 0;
uses[name]++;
} else if (type == 'assign') {
var target = node[2];
if (target[0] == 'name') {
var name = target[1];
if (!(name in definitions)) definitions[name] = 0;
definitions[name]++;
if (!uses[name]) uses[name] = 0;
if (!values[name]) values[name] = node[3];
if (node[1] === true) { // not +=, -= etc., just =
uses[name]--; // because the name node will show up by itself in the previous case
if (!namings[name]) namings[name] = 0;
namings[name]++; // offset it here, this tracks the total times we are named
}
}
} else if (type == 'switch') {
hasSwitch = true;
}
});
for (var used in uses) {
namings[used] = (namings[used] || 0) + uses[used];
}
// we cannot eliminate variables if there is a switch
if (hasSwitch && !asm) return;
var potentials = {}; // local variables with 1 definition and 1 use
var sideEffectFree = {}; // whether a local variable has no side effects in its definition
function unprocessVariable(name) {
if (name in potentials) delete potentials[name];
if (name in varsToRemove) delete varsToRemove[name];
if (name in sideEffectFree) delete sideEffectFree[name];
if (name in varsToTryToRemove) delete varsToTryToRemove[name];
}
function processVariable(name) {
if (definitions[name] == 1 && uses[name] == 1) {
potentials[name] = 1;
} else if (uses[name] == 0 && (!definitions[name] || definitions[name] <= 1)) { // no uses, no def or 1 def (cannot operate on phis, and the llvm optimizer will remove unneeded phis anyhow)
var hasSideEffects = false;
var value = values[name];
if (value) {
// TODO: merge with other side effect code
// First, pattern-match
// (HEAP32[((tempDoublePtr)>>2)]=((HEAP32[(($_sroa_0_0__idx1)>>2)])|0),HEAP32[(((tempDoublePtr)+(4))>>2)]=((HEAP32[((($_sroa_0_0__idx1)+(4))>>2)])|0),(+(HEAPF64[(tempDoublePtr)>>3])))
// which has no side effects and is the special form of converting double to i64.
if (!(value[0] == 'seq' && value[1][0] == 'assign' && value[1][2][0] == 'sub' && value[1][2][2][0] == 'binary' && value[1][2][2][1] == '>>' &&
value[1][2][2][2][0] == 'name' && value[1][2][2][2][1] == 'tempDoublePtr')) {
// If not that, then traverse and scan normally.
traverse(value, function(node, type) {
if (!(type in NODES_WITHOUT_ELIMINATION_SIDE_EFFECTS)) {
hasSideEffects = true; // cannot remove this unused variable, constructing it has side effects
return true;
}
});
}
}
if (!hasSideEffects) {
varsToRemove[name] = !definitions[name] ? 2 : 1; // remove it normally
sideEffectFree[name] = true;
// Each time we remove a variable with 0 uses, if its value has no
// side effects and vanishes too, then we can remove a use from variables
// appearing in it, and possibly eliminate again
if (value) {
traverse(value, function(node, type) {
if (type == 'name') {
var name = node[1];
node[1] = ''; // we can remove this - it will never be shown, and should not be left to confuse us as we traverse
if (name in locals) {
uses[name]--; // cannot be infinite recursion since we descend an energy function
assert(uses[name] >= 0);
unprocessVariable(name);
processVariable(name);
}
}
});
}
} else {
varsToTryToRemove[name] = 1; // try to remove it later during scanning
}
}
}
for (var name in locals) {
processVariable(name);
}
//printErr('defs: ' + JSON.stringify(definitions));
//printErr('uses: ' + JSON.stringify(uses));
//printErr('values: ' + JSON.stringify(values));
//printErr('locals: ' + JSON.stringify(locals));
//printErr('varsToRemove: ' + JSON.stringify(varsToRemove));
//printErr('varsToTryToRemove: ' + JSON.stringify(varsToTryToRemove));
values = null;
//printErr('potentials: ' + JSON.stringify(potentials));
// We can now proceed through the function. In each list of statements, we try to eliminate
var tracked = {};
var globalsInvalidated = false; // do not repeat invalidations, until we track something new
var memoryInvalidated = false;
var callsInvalidated = false;
function track(name, value, defNode) { // add a potential that has just been defined to the tracked list, we hope to eliminate it
var usesGlobals = false, usesMemory = false, deps = {}, doesCall = false;
var ignoreName = false; // one-time ignorings of names, as first op in sub and call
traverse(value, function(node, type) {
if (type == 'name') {
if (!ignoreName) {
var name = node[1];
if (!(name in locals)) {
usesGlobals = true;
}
if (!(name in potentials)) { // deps do not matter for potentials - they are defined once, so no complexity
deps[name] = 1;
}
} else {
ignoreName = false;
}
} else if (type == 'sub') {
usesMemory = true;
ignoreName = true;
} else if (type == 'call') {
usesGlobals = true;
usesMemory = true;
doesCall = true;
ignoreName = true;
} else {
ignoreName = false;
}
});
tracked[name] = {
usesGlobals: usesGlobals,
usesMemory: usesMemory,
defNode: defNode,
deps: deps,
doesCall: doesCall
};
globalsInvalidated = false;
memoryInvalidated = false;
callsInvalidated = false;
//printErr('track ' + [name, JSON.stringify(tracked[name])]);
}
var temp = [];
// TODO: invalidate using a sequence number for each type (if you were tracked before the last invalidation, you are cancelled). remove for.in loops
function invalidateGlobals() {
//printErr('invalidate globals');
temp.length = 0;
for (var name in tracked) {
var info = tracked[name];
if (info.usesGlobals) {
temp.push(name);
}
}
for (var i = 0; i < temp.length; i++) {
delete tracked[temp[i]];
}
}
function invalidateMemory() {
//printErr('invalidate memory');
temp.length = 0;
for (var name in tracked) {
var info = tracked[name];
if (info.usesMemory) {
temp.push(name);
}
}
for (var i = 0; i < temp.length; i++) {
delete tracked[temp[i]];
}
}
function invalidateByDep(dep) {
//printErr('invalidate by dep ' + dep);
temp.length = 0;
for (var name in tracked) {
var info = tracked[name];
if (info.deps[dep]) {
temp.push(name);
}
}
for (var i = 0; i < temp.length; i++) {
delete tracked[temp[i]];
}
}
function invalidateCalls() {
//printErr('invalidate calls');
temp.length = 0;
for (var name in tracked) {
var info = tracked[name];
if (info.doesCall) {
temp.push(name);
}
}
for (var i = 0; i < temp.length; i++) {
delete tracked[temp[i]];
}
}
// Generate the sequence of execution. This determines what is executed before what, so we know what can be reordered. Using
// that, performs invalidations and eliminations
function scan(node) {
//printErr('scan: ' + JSON.stringify(node).substr(0, 50) + ' : ' + keys(tracked));
var abort = false;
var allowTracking = true; // false inside an if; also prevents recursing in an if
//var nesting = 1; // printErr-related
function traverseInOrder(node, ignoreSub, ignoreName) {
if (abort) return;
//nesting++; // printErr-related
//printErr(spaces(2*(nesting+1)) + 'trav: ' + JSON.stringify(node).substr(0, 50) + ' : ' + keys(tracked) + ' : ' + [allowTracking, ignoreSub, ignoreName]);
var type = node[0];
if (type == 'assign') {
var target = node[2];
var value = node[3];
var nameTarget = target[0] == 'name';
traverseInOrder(target, true, nameTarget); // evaluate left
traverseInOrder(value); // evaluate right
// do the actual assignment
if (nameTarget) {
var name = target[1];
if (!(name in potentials)) {
if (!(name in varsToTryToRemove)) {
// expensive check for invalidating specific tracked vars. This list is generally quite short though, because of
// how we just eliminate in short spans and abort when control flow happens TODO: history numbers instead
invalidateByDep(name); // can happen more than once per dep..
if (!(name in locals) && !globalsInvalidated) {
invalidateGlobals();
globalsInvalidated = true;
}
// if we can track this name (that we assign into), and it has 0 uses and we want to remove its 'var'
// definition - then remove it right now, there is no later chance
if (allowTracking && (name in varsToRemove) && uses[name] == 0) {
track(name, node[3], node);
doEliminate(name, node);
}
} else {
// replace it in-place
node.length = value.length;
for (var i = 0; i < value.length; i++) {
node[i] = value[i];
}
varsToRemove[name] = 2;
}
} else {
if (allowTracking) track(name, node[3], node);
}
} else if (target[0] == 'sub') {
if (!isTempDoublePtrAccess(target) && !memoryInvalidated) {
invalidateMemory();
memoryInvalidated = true;
}
}
} else if (type == 'sub') {
traverseInOrder(node[1], false, !memSafe); // evaluate inner
traverseInOrder(node[2]); // evaluate outer
// ignoreSub means we are a write (happening later), not a read
if (!ignoreSub && !isTempDoublePtrAccess(node)) {
// do the memory access
if (!callsInvalidated) {
invalidateCalls();
callsInvalidated = true;
}
}
} else if (type == 'var') {
var vars = node[1];
for (var i = 0; i < vars.length; i++) {
var name = vars[i][0];
var value = vars[i][1];
if (value) {
traverseInOrder(value);
if (name in potentials && allowTracking) {
track(name, value, node);
} else {
invalidateByDep(name);
}
if (vars.length == 1 && name in varsToTryToRemove && value) {
// replace it in-place
value = ['stat', value];
node.length = value.length;
for (var i = 0; i < value.length; i++) {
node[i] = value[i];
}
varsToRemove[name] = 2;
}
}
}
} else if (type == 'binary') {
var flipped = false;
if (node[1] in ASSOCIATIVE_BINARIES && !(node[2][0] in NAME_OR_NUM) && node[3][0] in NAME_OR_NUM) { // TODO recurse here?
// associatives like + and * can be reordered in the simple case of one of the sides being a name, since we assume they are all just numbers
var temp = node[2];
node[2] = node[3];
node[3] = temp;
flipped = true;
}
traverseInOrder(node[2]);
traverseInOrder(node[3]);
if (flipped && node[2][0] in NAME_OR_NUM) { // dunno if we optimized, but safe to flip back - and keeps the code closer to the original and more readable
var temp = node[2];
node[2] = node[3];
node[3] = temp;
}
} else if (type == 'name') {
if (!ignoreName) { // ignoreName means we are the name of something like a call or a sub - irrelevant for us
var name = node[1];
if (name in tracked) {
doEliminate(name, node);
} else if (!(name in locals) && !callsInvalidated) {
invalidateCalls();
callsInvalidated = true;
}
}
} else if (type == 'unary-prefix' || type == 'unary-postfix') {
traverseInOrder(node[2]);
} else if (type in IGNORABLE_ELIMINATOR_SCAN_NODES) {
} else if (type == 'call') {
traverseInOrder(node[1], false, true);
var args = node[2];
for (var i = 0; i < args.length; i++) {
traverseInOrder(args[i]);
}
// these two invalidations will also invalidate calls
if (!globalsInvalidated) {
invalidateGlobals();
globalsInvalidated = true;
}
if (!memoryInvalidated) {
invalidateMemory();
memoryInvalidated = true;
}
} else if (type == 'if') {
if (allowTracking) {
traverseInOrder(node[1]); // can eliminate into condition, but nowhere else
if (!callsInvalidated) { // invalidate calls, since we cannot eliminate them into an if that may not execute!
invalidateCalls();
callsInvalidated = true;
}
allowTracking = false;
traverseInOrder(node[2]); // 2 and 3 could be 'parallel', really..
if (node[3]) traverseInOrder(node[3]);
allowTracking = true;
} else {
tracked = {};
}
} else if (type == 'block') {
var stats = node[1];
if (stats) {
for (var i = 0; i < stats.length; i++) {
traverseInOrder(stats[i]);
}
}
} else if (type == 'stat') {
traverseInOrder(node[1]);
} else if (type == 'label') {
traverseInOrder(node[2]);
} else if (type == 'seq') {
traverseInOrder(node[1]);
traverseInOrder(node[2]);
} else if (type == 'do') {
if (node[1][0] == 'num' && node[1][1] == 0) { // one-time loop
traverseInOrder(node[2]);
} else {
tracked = {};
}
} else if (type == 'return') {
if (node[1]) traverseInOrder(node[1]);
} else if (type == 'conditional') {
traverseInOrder(node[1]);
traverseInOrder(node[2]);
traverseInOrder(node[3]);
} else if (type == 'switch') {
traverseInOrder(node[1]);
var cases = node[2];
for (var i = 0; i < cases.length; i++) {
var c = cases[i];
assert(c[0] === null || c[0][0] == 'num' || (c[0][0] == 'unary-prefix' && c[0][2][0] == 'num'));
var stats = c[1];
for (var j = 0; j < stats.length; j++) {
traverseInOrder(stats[j]);
}
}
} else {
if (!(type in ABORTING_ELIMINATOR_SCAN_NODES)) {
printErr('unfamiliar eliminator scan node: ' + JSON.stringify(node));
}
tracked = {};
abort = true;
}
//nesting--; // printErr-related
}
traverseInOrder(node);
}
function doEliminate(name, node) {
//printErr('elim!!!!! ' + name);
// yes, eliminate!
varsToRemove[name] = 2; // both assign and var definitions can have other vars we must clean up
var info = tracked[name];
delete tracked[name];
var defNode = info.defNode;
if (!sideEffectFree[name]) {
if (defNode[0] == 'var') {
defNode[1].forEach(function(pair) {
if (pair[0] == name) {
value = pair[1];
}
});
assert(value);
} else { // assign
value = defNode[3];
// wipe out the assign
defNode[0] = 'toplevel';
defNode[1] = [];
defNode.length = 2;
}
// replace this node in-place
node.length = 0;
for (var i = 0; i < value.length; i++) {
node[i] = value[i];
}
} else {
// empty it out in-place
node.length = 0;
node[0] = 'toplevel';
node[1] = [];
}
}
traverse(func, function(block) {
// Look for statements, including while-switch pattern
var stats = getStatements(block) || (block[0] == 'while' && block[2][0] == 'switch' ? [block[2]] : stats);
if (!stats) return;
//printErr('Stats: ' + JSON.stringify(stats).substr(0,100));
tracked = {};
//printErr('new StatBlock');
for (var i = 0; i < stats.length; i++) {
var node = stats[i];
//printErr('StatBlock[' + i + '] => ' + JSON.stringify(node).substr(0,100));
var type = node[0];
if (type == 'stat') {
node = node[1];
type = node[0];
}
// Check for things that affect elimination
if (type in ELIMINATION_SAFE_NODES) {
scan(node);
} else {
tracked = {}; // not a var or assign, break all potential elimination so far
}
}
//printErr('delete StatBlock');
});
var seenUses = {}, helperReplacements = {}; // for looper-helper optimization
// clean up vars, and loop variable elimination
traverse(func, function(node, type) {
// pre
if (type === 'var') {
node[1] = node[1].filter(function(pair) { return !varsToRemove[pair[0]] });
if (node[1].length == 0) {
// wipe out an empty |var;|
node[0] = 'toplevel';
node[1] = [];
}
}
}, function(node, type) {
// post
if (type == 'name') {
var name = node[1];
if (name in helperReplacements) {
node[1] = helperReplacements[name];
return; // no need to track this anymore, we can't loop-optimize more than once
}
// track how many uses we saw. we need to know when a variable is no longer used (hence we run this in the post)
if (!(name in seenUses)) {
seenUses[name] = 1;
} else {
seenUses[name]++;
}
} else if (type == 'while') {
// try to remove loop helper variables specifically
var stats = node[2][1];
var last = stats[stats.length-1];
if (last && last[0] == 'if' && last[2][0] == 'block' && last[3] && last[3][0] == 'block') {
var ifTrue = last[2];
var ifFalse = last[3];
var flip = false;
if (ifFalse[1][0][0] == 'break') { // canonicalize break in the if
var temp = ifFalse;
ifFalse = ifTrue;
ifTrue = temp;
flip = true;
}
if (ifTrue[1][0][0] == 'break') {
var assigns = ifFalse[1];
var loopers = [], helpers = [];
for (var i = 0; i < assigns.length; i++) {
if (assigns[i][0] == 'stat' && assigns[i][1][0] == 'assign') {
var assign = assigns[i][1];
if (assign[1] === true && assign[2][0] == 'name' && assign[3][0] == 'name') {
var looper = assign[2][1];
var helper = assign[3][1];
if (definitions[helper] == 1 && seenUses[looper] == namings[looper] &&
!helperReplacements[helper] && !helperReplacements[looper]) {
loopers.push(looper);
helpers.push(helper);
}
}
}
}
if (loopers.length < assigns.length) return; // TODO: handle the case where can can just eliminate one. (we can't optimize the break, but we can remove the var at least)
for (var l = 0; l < loopers.length; l++) {
var looper = loopers[l];
var helper = helpers[l];
// the remaining issue is whether loopers are used after the assignment to helper and before the last line (where we assign to it)
var found = -1;
for (var i = stats.length-2; i >= 0; i--) {
var curr = stats[i];
if (curr[0] == 'stat' && curr[1][0] == 'assign') {
var currAssign = curr[1];
if (currAssign[1] === true && currAssign[2][0] == 'name') {
var to = currAssign[2][1];
if (to == helper) {
found = i;
break;
}
}
}
}
if (found < 0) return;
var looperUsed = false;
for (var i = found+1; i < stats.length && !looperUsed; i++) {
var curr = i < stats.length-1 ? stats[i] : last[1]; // on the last line, just look in the condition
traverse(curr, function(node, type) {
if (type == 'name' && node[1] == looper) {
looperUsed = true;
return true;
}
});
}
if (looperUsed) return;
}
// hurrah! this is safe to do
for (var l = 0; l < loopers.length; l++) {
var looper = loopers[l];
var helper = helpers[l];
varsToRemove[helper] = 2;
traverse(node, function(node, type) { // replace all appearances of helper with looper
if (type == 'name' && node[1] == helper) node[1] = looper;
});
helperReplacements[helper] = looper; // replace all future appearances of helper with looper
helperReplacements[looper] = looper; // avoid any further attempts to optimize looper in this manner (seenUses is wrong anyhow, too)
}
// simplify the if. we remove the if branch, leaving only the else
if (flip) {
last[1] = simplifyNotCompsDirect(['unary-prefix', '!', last[1]]);
last[2] = last[3];
}
last.pop();
}
}
}
});
if (asm) {
for (var v in varsToRemove) {
if (varsToRemove[v] == 2) delete asmData.vars[v];
}
denormalizeAsm(func, asmData);
}
});
// A class for optimizing expressions. We know that it is legitimate to collapse
// 5+7 in the generated code, as it will always be numerical, for example. XXX do we need this? here?
function ExpressionOptimizer(node) {
this.node = node;
this.run = function() {
traverse(this.node, function(node, type) {
if (type === 'binary' && node[1] == '+') {
var names = [];
var num = 0;
var has_num = false;
var fail = false;
traverse(node, function(subNode, subType) {
if (subType === 'binary') {
if (subNode[1] != '+') {
fail = true;
return false;
}
} else if (subType === 'name') {
names.push(subNode[1]);
return;
} else if (subType === 'num') {
num += subNode[1];
has_num = true;
return;
} else {
fail = true;
return false;
}
});
if (!fail && has_num) {
var ret = ['num', num];
for (var i = 0; i < names.length; i++) {
ret = ['binary', '+', ['name', names[i]], ret];
}
return ret;
}
}
});
};
}
new ExpressionOptimizer(ast).run();
}
function eliminateMemSafe(ast) {
eliminate(ast, true);
}
function minifyGlobals(ast) {
var minified = {};
var next = 0;
var first = true; // do not minify initial 'var asm ='
// find the globals
traverse(ast, function(node, type) {
if (type == 'var') {
if (first) {
first = false;
return;
}
var vars = node[1];
for (var i = 0; i < vars.length; i++) {
var name = vars[i][0];
assert(next < minifierInfo.names.length);
vars[i][0] = minified[name] = minifierInfo.names[next++];
}
}
});
// add all globals in function chunks, i.e. not here but passed to us
for (var i = 0; i < minifierInfo.globals.length; i++) {
name = minifierInfo.globals[i];
assert(next < minifierInfo.names.length);
minified[name] = minifierInfo.names[next++];
}
// apply minification
traverse(ast, function(node, type) {
if (type == 'name') {
var name = node[1];
if (name in minified) {
node[1] = minified[name];
}
}
});
suffix = '// MINIFY_INFO:' + JSON.stringify(minified);
}
// Change +5 to DOT$ZERO(5). We then textually change 5 to 5.0 (uglify's ast cannot differentiate between 5 and 5.0 directly)
function prepDotZero(ast) {
traverse(ast, function(node, type) {
if (type == 'unary-prefix' && node[1] == '+') {
if (node[2][0] == 'num' ||
(node[2][0] == 'unary-prefix' && node[2][1] == '-' && node[2][2][0] == 'num')) {
return ['call', ['name', 'DOT$ZERO'], [node[2]]];
}
}
});
}
function fixDotZero(js) {
return js.replace(/DOT\$ZERO\(([-+]?(0x)?[0-9a-f]*\.?[0-9]+([eE][-+]?[0-9]+)?)\)/g, function(m, num) {
if (num.substr(0, 2) == '0x' || num.substr(0, 3) == '-0x') {
return eval(num) + '.0';
}
if (num.indexOf('.') >= 0) return num;
var e = num.indexOf('e');
if (e < 0) return num + '.0';
return num.substr(0, e) + '.0' + num.substr(e);
});
}
function asmLoopOptimizer(ast) {
traverseGeneratedFunctions(ast, function(fun) {
// This is at the end of the pipeline, we can assume all other optimizations are done, and we modify loops
// into shapes that might confuse other passes
traverse(fun, function(node, type) {
if (type == 'while' && node[1][0] == 'num' && node[1][1] == 1 && node[2][0] == 'block') {
// while (1) { .. if (..) { break } } ==> do { .. } while(..)
var stats = node[2][1];
var last = stats[stats.length-1];
if (last && last[0] == 'if' && !last[3] && last[2][0] == 'block' && last[2][1][0][0] == 'break' && !last[2][1][0][1]) {
var conditionToBreak = last[1];
stats.pop();
node[0] = 'do';
node[1] = simplifyNotCompsDirect(['unary-prefix', '!', conditionToBreak]);
return node;
}
}
});
});
}
// Passes table
var compress = false, printMetadata = true, asm = false, last = false;
var passes = {
dumpAst: dumpAst,
dumpSrc: dumpSrc,
unGlobalize: unGlobalize,
removeAssignsToUndefined: removeAssignsToUndefined,
//removeUnneededLabelSettings: removeUnneededLabelSettings,
simplifyExpressionsPre: simplifyExpressionsPre,
optimizeShiftsConservative: optimizeShiftsConservative,
optimizeShiftsAggressive: optimizeShiftsAggressive,
simplifyExpressionsPost: simplifyExpressionsPost,
hoistMultiples: hoistMultiples,
loopOptimizer: loopOptimizer,
registerize: registerize,
eliminate: eliminate,
eliminateMemSafe: eliminateMemSafe,
minifyGlobals: minifyGlobals,
compress: function() { compress = true },
noPrintMetadata: function() { printMetadata = false },
asm: function() { asm = true },
last: function() { last = true },
closure: function(){} // handled in python
};
// Main
var suffix = '';
var src = read(arguments_[0]);
var ast = srcToAst(src);
//printErr(JSON.stringify(ast)); throw 1;
generatedFunctions = src.indexOf(GENERATED_FUNCTIONS_MARKER) >= 0;
var minifierInfoStart = src.indexOf('// MINIFY_INFO:')
if (minifierInfoStart > 0) minifierInfo = JSON.parse(src.substr(minifierInfoStart + 15));
//printErr(JSON.stringify(minifierInfo));
arguments_.slice(1).forEach(function(arg) {
passes[arg](ast);
});
if (asm && last) {
asmLoopOptimizer(ast);
prepDotZero(ast);
}
var js = astToSrc(ast, compress), old;
if (asm && last) {
js = fixDotZero(js);
}
// remove unneeded newlines+spaces, and print
do {
old = js;
js = js.replace(/\n *\n/g, '\n');
} while (js != old);
print(js);
print('\n');
print(suffix);
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