mirror of
https://github.com/Sei-Lisa/LSL-PyOptimizer
synced 2025-07-01 07:38:21 +00:00
507 lines
21 KiB
Python
507 lines
21 KiB
Python
# (C) Copyright 2015 Sei Lisa. All rights reserved.
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#
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# This file is part of LSL PyOptimizer.
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#
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# LSL PyOptimizer is free software: you can redistribute it and/or
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# modify it under the terms of the GNU General Public License as
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# published by the Free Software Foundation, either version 3 of the
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# License, or (at your option) any later version.
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#
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# LSL PyOptimizer is distributed in the hope that it will be useful,
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# but WITHOUT ANY WARRANTY; without even the implied warranty of
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# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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# GNU General Public License for more details.
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#
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# You should have received a copy of the GNU General Public License
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# along with LSL PyOptimizer. If not, see <http://www.gnu.org/licenses/>.
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# Dead Code Removal optimization
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import lslfuncs
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class deadcode(object):
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# Functions that cause the rest of the current block to never be executed
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# e.g. default { state_entry() { llResetScript(); llSetPos(<3,3,3>); } }
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# in that example, llSetPos is dead code because llResetScript does not let
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# it execute. llRemoveInventory(llGetScriptName()), llDetachFromAvatar()
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# and llDie() come close, but evidence shows that it's not the case and the
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# script can execute some more lines before stopping.
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# llScriptState(..., FALSE) allows resuming after it, so whatever comes
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# next isn't really dead code.
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# TODO: check if there are any more than this one.
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TerminatorFuncs = ('llResetScript',)
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def MarkReferences(self, node):
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"""Marks each node it passes through as executed (X), and each variable
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as read (R) (with count) and/or written (W) (with node where it is, or
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False if written more than once) as appropriate. Traces execution to
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determine if any part of the code is never executed.
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"""
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# The 'X' key, when present, indicates whether a node is executed.
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# Its value means whether this instruction will proceed to the next
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# (True: it will; False: it won't).
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if 'X' in node:
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return node['X'] # branch already analyzed
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nt = node['nt']
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child = node['ch'] if 'ch' in node else None
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# Control flow statements
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if nt == 'STSW':
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node['X'] = False # Executed but path-breaking.
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sym = self.symtab[0][node['name']]
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if 'X' not in self.tree[sym['Loc']]:
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self.MarkReferences(self.tree[sym['Loc']])
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return False
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if nt == 'JUMP':
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node['X'] = False # Executed but path-breaking.
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sym = self.symtab[node['scope']][node['name']]
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if 'R' in sym:
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sym['R'] += 1
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else:
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sym['R'] = 1
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return False
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if nt == 'RETURN':
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node['X'] = False # Executed but path-breaking.
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if child:
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self.MarkReferences(child[0])
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return False
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if nt == 'IF':
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# "When you get to a fork in the road, take it."
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node['X'] = None # provisional value, refined later
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self.MarkReferences(child[0])
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condnode = child[0]
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if condnode['nt'] == 'CONST':
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if lslfuncs.cond(condnode['value']):
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# TRUE - 'then' branch always executed.
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node['X'] = self.MarkReferences(child[1])
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return node['X']
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elif len(child) == 3:
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# FALSE - 'else' branch always executed.
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node['X'] = self.MarkReferences(child[2])
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return node['X']
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# else fall through
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else:
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cont = self.MarkReferences(child[1])
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if len(child) == 3:
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if not cont:
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cont = self.MarkReferences(child[2])
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node['X'] = cont
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return cont
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self.MarkReferences(child[2])
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node['X'] = True
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return True
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if nt == 'WHILE':
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node['X'] = None # provisional value, refined later
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self.MarkReferences(child[0])
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if child[0]['nt'] == 'CONST':
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if lslfuncs.cond(child[0]['value']):
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# Infinite loop - unless it returns, it stops
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# execution. But it is executed itself.
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self.MarkReferences(child[1])
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node['X'] = False
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return node['X']
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# else the inside isn't executed at all, so don't mark it
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else:
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self.MarkReferences(child[1])
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node['X'] = True
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return True
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if nt == 'DO':
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node['X'] = None # provisional value, refined later
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if not self.MarkReferences(child[0]):
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node['X'] = False
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return False
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self.MarkReferences(child[1])
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# It proceeds to the next statement unless it's an infinite loop
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node['X'] = not (child[1]['nt'] == 'CONST' and lslfuncs.cond(child[1]['value']))
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return node['X']
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if nt == 'FOR':
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node['X'] = None # provisional value, refined later
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self.MarkReferences(child[0])
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self.MarkReferences(child[1])
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if child[1]['nt'] == 'CONST':
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if lslfuncs.cond(child[1]['value']):
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# Infinite loop - unless it returns, it stops
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# execution. But it is executed itself.
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node['X'] = False
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self.MarkReferences(child[3])
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self.MarkReferences(child[2]) # this can't stop execution
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return node['X']
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# else the body and the iterator aren't executed at all, so
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# don't mark them
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node['X'] = True
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else:
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node['X'] = True
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self.MarkReferences(child[3])
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self.MarkReferences(child[2])
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# Mark the EXPRLIST as always executed, but not the subexpressions.
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# That forces the EXPRLIST (which is a syntactic requirement) to be
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# kept, while still simplifying the contents properly.
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child[2]['X'] = True
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return True
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if nt == '{}':
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# Go through each statement in turn. If one stops execution,
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# continue reading until either we find a used label (and resume
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# execution) or reach the end (and return False). Otherwise return
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# True.
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continues = True
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node['X'] = None # provisional
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for stmt in child:
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if continues or stmt['nt'] == '@':
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continues = self.MarkReferences(stmt)
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node['X'] = continues
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return continues
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if nt == 'FNCALL':
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node['X'] = None # provisional
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sym = self.symtab[0][node['name']]
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fdef = self.tree[sym['Loc']] if 'Loc' in sym else None
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for idx in xrange(len(child)-1, -1, -1):
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# Each element is a "write" on the callee's parameter.
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# E.g. f(integer a, integer b) { f(2,3); } means 2, 3 are
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# writes to a and b.
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self.MarkReferences(child[idx])
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if fdef is not None:
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psym = self.symtab[fdef['pscope']][fdef['pnames'][idx]]
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if 'W' in psym:
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psym['W'] = False
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else:
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psym['W'] = child[idx]
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if 'Loc' in sym:
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if 'X' not in self.tree[sym['Loc']]:
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self.MarkReferences(self.tree[sym['Loc']])
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node['X'] = self.tree[sym['Loc']]['X']
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else:
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node['X'] = node['name'] not in self.TerminatorFuncs
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# Note that JUMP analysis is incomplete. To do it correctly, we
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# should follow the jump right to its destination, in order to know
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# if that branch leads to a RETURN or completely stops the event.
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# With our code structure, following the JUMP is unfeasible.
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# For that reason, we can't track whether a branch ends in RETURN
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# or in something more powerful like a script reset, in order to
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# propagate it through the function definition to the caller.
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#
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# In practice, this means that the caller can't distinguish this:
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# fn() { return; }
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# from this:
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# fn() { llResetScript(); }
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# and therefore, invocations of the function that are followed by
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# code can't know whether that code is dead or not.
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#
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# What does that have to do with jumps? Well, imagine this:
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# fn(integer x) { if (x) jump x1; else jump x2;
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# @x1; return; @x2; llResetScript(); }
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# What of the branches of if() is taken, depends on where the jumps
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# lead to. Assuming the last one always is wrong, because it would
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# mark in the caller code that may execute, as dead, e.g. here:
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# fn2() { fn(); x = 1; }
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return node['X']
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if nt == 'DECL':
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sym = self.symtab[node['scope']][node['name']]
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if child is not None:
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sym['W'] = child[0]
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else:
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sym['W'] = {'nt':'CONST', 't':node['t'],
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'value':self.DefaultValues[node['t']]}
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node['X'] = True
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if child is not None:
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if 'orig' in child[0]:
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self.MarkReferences(child[0]['orig'])
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child[0]['X'] = child[0]['orig']['X']
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else:
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self.MarkReferences(child[0])
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return True
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# ---- Starting here, all node types return through the bottom
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# (except '=').
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node['X'] = None # provisional
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if nt in self.assign_ops or nt in ('--V', '++V', 'V++', 'V--'):
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ident = node['ch'][0]
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if ident['nt'] == 'FLD':
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ident = ident['ch'][0]
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assert ident['nt'] == 'IDENT'
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sym = self.symtab[ident['scope']][ident['name']]
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if ident['scope'] == 0:
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# Mark the global first.
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self.MarkReferences(self.tree[sym['Loc']])
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# In any case, this is at least the second write, so mark it as such
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# (SSA would be a plus for this to be optimal)
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sym['W'] = False
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if nt == '=':
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# Prevent the first node from being mistaken as a read, by
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# recursing only on the RHS node.
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self.MarkReferences(child[1])
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node['X'] = True
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return True
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elif nt == 'FLD':
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# Mark this variable as referenced by a Field (recursing will mark
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# the ident as read later)
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self.symtab[child[0]['scope']][child[0]['name']]['Fld'] = True
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elif nt == 'IDENT':
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sym = self.symtab[node['scope']][node['name']]
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# Mark global if it's one.
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if 'W' not in sym and node['scope'] == 0:
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self.MarkReferences(self.tree[sym['Loc']])
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# Increase read counter
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if 'R' in sym:
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sym['R'] += 1
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else:
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sym['R'] = 1
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node['X'] = True
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if child is not None:
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for subnode in child:
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self.MarkReferences(subnode)
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return True
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def SymbolReplacedOrDeleted(self, curnode):
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"""If the given node's name must be simplified, that is, replaced or
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deleted (deleted if declaration, replaced if identifier), it returns
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the symbol table entry. Otherwise it returns False.
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"""
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# 'W':False means written more than once, i.e. not only in the
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# declaration. Variables written more than once can't be
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# simplified by this code.
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# If not written more than once:
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# For expressions:
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# - Remove expressions read only once, replacing the value, but only
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# if the readers are not fields of vectors or rotations, and if
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# they are side-effect free.
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# For constants:
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# - Remove lists, vectors and rotations read only once.
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# - Floats are removed if their value has no decimals or if
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# used no more than N times (for some N).
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# - Strings, keys and integers are just removed.
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sym = self.symtab[curnode['scope']][curnode['name']]
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if 'R' not in sym:
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return True # if not used, it can be removed
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# Event parameters do not have 'W' in sym.
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if 'W' not in sym:
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return False
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if sym['W'] is not False:
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node = sym['W']
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nt = node['nt']
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if nt == 'CONST':
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tcurnode = curnode['t']
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if tcurnode in ('integer', 'string', 'key'):
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return sym
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if tcurnode == 'float':
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if sym['R'] <= 3 or type(node['value']) == int:
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return sym
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elif tcurnode == 'vector' \
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or tcurnode == 'list' and len(node['value']) <= 3:
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if sym['R'] <= 1:
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return sym
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elif tcurnode == 'rotation' \
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or tcurnode == 'list' and len(node['value']) <= 4:
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if sym['R'] <= 1:
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return sym
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return False
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# To replace expressions, they MUST be side-effect free, or they
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# will be executed at a different time.
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# Also, we can't safely replace expressions unless shrinknames is
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# active. shrinknames assigns a different identifier to each
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# variable, which avoids conflicts. Consider this scenario:
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# integer i=2;
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# default{state_entry(){integer j=i+1; integer i=4; llSleep(i+j);}}
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# Replacing j with i+1 in llOwnerSay will produce wrong code because
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# the name i is redefined after j is assigned. shrinknames prevents
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# that.
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# FIXME: EMERGENCY FIX: shrinknames is not enough guarantee. See nposerlv.lsl.
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#if not self.shrinknames or 'SEF' not in node:
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if True or 'SEF' not in node:
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return False
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if nt not in ('VECTOR', 'ROTATION'):
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# If it's an expression and the reference is to a field, we
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# can't simplify. Consider e.g.:
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# vector v = llGetVel(); llOwnerSay((string)v.z);
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# However, if it's a field coming from a Vector or Rotation
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# expression, we can embed the corresponding component, e.g.
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# vector v = <i+1, i+2, i+3>; llOwnerSay((string)v.y);
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# can be replaced with: llOwnerSay((string)((float)(i+2)));
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if 'Fld' in sym:
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return False
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if sym['R'] == 1:
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return sym
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return False
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def CleanNode(self, curnode):
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"""Recursively checks if the children are used, deleting those that are
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not.
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"""
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if 'ch' not in curnode:
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return
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# NOTE: Should not depend on 'Loc', since the nodes that are the
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# destination of 'Loc' are renumbered as we delete stuff from globals.
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index = int(curnode['nt'] in self.assign_ops) # don't recurse into a lvalue
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while index < len(curnode['ch']):
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node = curnode['ch'][index]
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if 'X' not in node:
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del curnode['ch'][index]
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continue
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nt = node['nt']
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if nt == 'DECL':
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if self.SymbolReplacedOrDeleted(node):
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if 'ch' not in node or 'SEF' in node['ch'][0]:
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del curnode['ch'][index]
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continue
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node = curnode['ch'][index] = {'nt':'EXPR', 't':node['t'],
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'ch':[self.Cast(node['ch'][0], node['t'])]}
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elif nt == 'FLD':
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sym = self.SymbolReplacedOrDeleted(node['ch'][0])
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if sym:
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value = sym['W']
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# Mark as executed, so it isn't optimized out.
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value['X'] = True
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fieldidx = 'xyzs'.index(node['fld'])
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if value['nt'] == 'CONST':
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value = value['value'][fieldidx]
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value = {'nt':'CONST', 'X':True, 'SEF':True,
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't':self.PythonType2LSL[type(value)], 'value':value}
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value = self.Cast(value, 'float')
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SEF = True
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else: # assumed VECTOR or ROTATION per SymbolReplacedOrDeleted
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SEF = 'SEF' in value
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value = self.Cast(value['ch'][fieldidx], 'float')
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# Replace it
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node = curnode['ch'][index] = value
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if SEF:
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node['SEF'] = True
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elif nt == 'IDENT':
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sym = self.SymbolReplacedOrDeleted(node)
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if sym:
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# Mark as executed, so it isn't optimized out.
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new = sym['W']
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new['X'] = True
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SEF = 'SEF' in sym['W']
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if SEF:
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new['SEF'] = True
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if new['t'] != node['t']:
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new = self.Cast(new, node['t'])
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curnode['ch'][index] = node = new
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# Delete orig if present, as we've eliminated the original
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#if 'orig' in sym['W']:
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# del sym['W']['orig']
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elif nt in self.assign_ops:
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ident = node['ch'][0]
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if ident['nt'] == 'FLD':
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ident = ident['ch'][0]
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sym = self.SymbolReplacedOrDeleted(ident)
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if sym:
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node = curnode['ch'][index] = self.Cast(node['ch'][1], node['t'])
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elif nt in ('IF', 'WHILE', 'DO', 'FOR'):
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# If the mandatory statement is to be removed, replace it
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# with a ; to prevent leaving the statement empty.
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child = node['ch']
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idx = 3 if nt == 'FOR' else 0 if nt == 'DO' else 1
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if 'X' not in child[idx]:
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child[idx] = {'nt':';', 't':None, 'X':True, 'SEF':True}
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if nt == 'DO' and 'X' not in child[1]:
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# Mandatory condition but not executed - replace
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child[1] = {'nt':'CONST','X':True,'SEF':True,'t':'integer',
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'value':0}
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self.CleanNode(node)
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index += 1
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def RemoveDeadCode(self):
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"""Simple reference-based dead code removal. It also performs a
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simplified form of constant propagation, taking advantage of the fact
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that it analyzes the code flow.
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"""
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# TODO: Converting to SSA first would facilitate DCR.
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# The SSA should be followed by constant and expression propagation,
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# then constant folding and then dead code removal.
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# Start at state default and mark everything referenced from there.
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# At the end, unreferenced globals and states will be removed.
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# We assume all events in a state are executed.
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#
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# This may not be the case, e.g. a target()/no_target() without
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# llTarget, sensor()/no_sensor() without llSensor(), listen() without
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# llListen, timer without llSetTimerEvent, etc. but we're not that
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# sophisticated (yet).
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# TODO: Inlining of functions that are a single 'return' line.
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statedef = self.tree[self.symtab[0]['default']['Loc']]
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assert statedef['nt'] == 'STDEF' and statedef['name'] == 'default'
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self.MarkReferences(statedef)
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# Track removal of global lines, to reasign locations later.
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LocMap = range(len(self.tree))
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# Perform the removal
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idx = 0
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while idx < len(self.tree):
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# Globals are special.
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# We need to track the locations too.
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node = self.tree[idx]
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delete = False
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if 'X' not in node:
|
|
delete = True
|
|
elif node['nt'] == 'DECL':
|
|
delete = self.SymbolReplacedOrDeleted(node)
|
|
|
|
if delete:
|
|
del self.tree[idx]
|
|
del LocMap[idx]
|
|
else:
|
|
idx += 1
|
|
self.CleanNode(node)
|
|
|
|
# Reassign locations
|
|
for name in self.symtab[0]:
|
|
if name != -1:
|
|
sym = self.symtab[0][name]
|
|
if 'Loc' in sym:
|
|
try:
|
|
sym['Loc'] = LocMap.index(sym['Loc'])
|
|
except ValueError:
|
|
# Subtree deleted - delete the Loc
|
|
del sym['Loc']
|