mirror of
https://github.com/ethereum/solidity
synced 2023-10-03 13:03:40 +00:00
364 lines
12 KiB
C++
364 lines
12 KiB
C++
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/*
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This file is part of solidity.
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solidity is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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solidity 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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You should have received a copy of the GNU General Public License
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along with solidity. If not, see <http://www.gnu.org/licenses/>.
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*/
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/**
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* @file ExpressionClasses.cpp
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* @author Christian <c@ethdev.com>
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* @date 2015
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* Container for equivalence classes of expressions for use in common subexpression elimination.
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*/
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#include <libevmasm/ExpressionClasses.h>
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#include <utility>
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#include <tuple>
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#include <functional>
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#include <boost/range/adaptor/reversed.hpp>
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#include <boost/noncopyable.hpp>
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#include <libevmasm/Assembly.h>
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#include <libevmasm/CommonSubexpressionEliminator.h>
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#include <libevmasm/SimplificationRules.h>
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using namespace std;
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using namespace dev;
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using namespace dev::eth;
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pair<Pattern, function<Pattern()> > const* Rules::findFirstMatch(
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Expression const& _expr,
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ExpressionClasses const& _classes
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)
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{
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resetMatchGroups();
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assertThrow(_expr.item, OptimizerException, "");
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for (auto const& rule: m_rules[byte(_expr.item->instruction())])
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{
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if (rule.first.matches(_expr, _classes))
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return &rule;
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}
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return nullptr;
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}
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void Rules::addRules(std::vector<std::pair<Pattern, std::function<Pattern ()> > > const& _rules)
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{
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for (auto const& r: _rules)
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addRule(r);
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}
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void Rules::addRule(std::pair<Pattern, std::function<Pattern()> > const& _rule)
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{
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m_rules[byte(_rule.first.instruction())].push_back(_rule);
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}
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template <class S> S divWorkaround(S const& _a, S const& _b)
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{
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return (S)(bigint(_a) / bigint(_b));
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}
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template <class S> S modWorkaround(S const& _a, S const& _b)
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{
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return (S)(bigint(_a) % bigint(_b));
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}
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Rules::Rules()
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{
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// Multiple occurences of one of these inside one rule must match the same equivalence class.
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// Constants.
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Pattern A(Push);
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Pattern B(Push);
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Pattern C(Push);
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// Anything.
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Pattern X;
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Pattern Y;
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Pattern Z;
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A.setMatchGroup(1, m_matchGroups);
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B.setMatchGroup(2, m_matchGroups);
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C.setMatchGroup(3, m_matchGroups);
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X.setMatchGroup(4, m_matchGroups);
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Y.setMatchGroup(5, m_matchGroups);
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Z.setMatchGroup(6, m_matchGroups);
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addRules(vector<pair<Pattern, function<Pattern()>>>{
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// arithmetics on constants
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{{Instruction::ADD, {A, B}}, [=]{ return A.d() + B.d(); }},
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{{Instruction::MUL, {A, B}}, [=]{ return A.d() * B.d(); }},
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{{Instruction::SUB, {A, B}}, [=]{ return A.d() - B.d(); }},
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{{Instruction::DIV, {A, B}}, [=]{ return B.d() == 0 ? 0 : divWorkaround(A.d(), B.d()); }},
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{{Instruction::SDIV, {A, B}}, [=]{ return B.d() == 0 ? 0 : s2u(divWorkaround(u2s(A.d()), u2s(B.d()))); }},
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{{Instruction::MOD, {A, B}}, [=]{ return B.d() == 0 ? 0 : modWorkaround(A.d(), B.d()); }},
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{{Instruction::SMOD, {A, B}}, [=]{ return B.d() == 0 ? 0 : s2u(modWorkaround(u2s(A.d()), u2s(B.d()))); }},
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{{Instruction::EXP, {A, B}}, [=]{ return u256(boost::multiprecision::powm(bigint(A.d()), bigint(B.d()), bigint(1) << 256)); }},
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{{Instruction::NOT, {A}}, [=]{ return ~A.d(); }},
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{{Instruction::LT, {A, B}}, [=]() { return A.d() < B.d() ? u256(1) : 0; }},
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{{Instruction::GT, {A, B}}, [=]() -> u256 { return A.d() > B.d() ? 1 : 0; }},
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{{Instruction::SLT, {A, B}}, [=]() -> u256 { return u2s(A.d()) < u2s(B.d()) ? 1 : 0; }},
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{{Instruction::SGT, {A, B}}, [=]() -> u256 { return u2s(A.d()) > u2s(B.d()) ? 1 : 0; }},
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{{Instruction::EQ, {A, B}}, [=]() -> u256 { return A.d() == B.d() ? 1 : 0; }},
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{{Instruction::ISZERO, {A}}, [=]() -> u256 { return A.d() == 0 ? 1 : 0; }},
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{{Instruction::AND, {A, B}}, [=]{ return A.d() & B.d(); }},
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{{Instruction::OR, {A, B}}, [=]{ return A.d() | B.d(); }},
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{{Instruction::XOR, {A, B}}, [=]{ return A.d() ^ B.d(); }},
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{{Instruction::BYTE, {A, B}}, [=]{ return A.d() >= 32 ? 0 : (B.d() >> unsigned(8 * (31 - A.d()))) & 0xff; }},
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{{Instruction::ADDMOD, {A, B, C}}, [=]{ return C.d() == 0 ? 0 : u256((bigint(A.d()) + bigint(B.d())) % C.d()); }},
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{{Instruction::MULMOD, {A, B, C}}, [=]{ return C.d() == 0 ? 0 : u256((bigint(A.d()) * bigint(B.d())) % C.d()); }},
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{{Instruction::MULMOD, {A, B, C}}, [=]{ return A.d() * B.d(); }},
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{{Instruction::SIGNEXTEND, {A, B}}, [=]() -> u256 {
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if (A.d() >= 31)
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return B.d();
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unsigned testBit = unsigned(A.d()) * 8 + 7;
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u256 mask = (u256(1) << testBit) - 1;
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return u256(boost::multiprecision::bit_test(B.d(), testBit) ? B.d() | ~mask : B.d() & mask);
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}},
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// invariants involving known constants
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{{Instruction::ADD, {X, 0}}, [=]{ return X; }},
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{{Instruction::SUB, {X, 0}}, [=]{ return X; }},
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{{Instruction::MUL, {X, 1}}, [=]{ return X; }},
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{{Instruction::DIV, {X, 1}}, [=]{ return X; }},
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{{Instruction::SDIV, {X, 1}}, [=]{ return X; }},
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{{Instruction::OR, {X, 0}}, [=]{ return X; }},
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{{Instruction::XOR, {X, 0}}, [=]{ return X; }},
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{{Instruction::AND, {X, ~u256(0)}}, [=]{ return X; }},
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{{Instruction::AND, {X, 0}}, [=]{ return u256(0); }},
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{{Instruction::MUL, {X, 0}}, [=]{ return u256(0); }},
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{{Instruction::DIV, {X, 0}}, [=]{ return u256(0); }},
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{{Instruction::DIV, {0, X}}, [=]{ return u256(0); }},
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{{Instruction::MOD, {X, 0}}, [=]{ return u256(0); }},
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{{Instruction::MOD, {0, X}}, [=]{ return u256(0); }},
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{{Instruction::OR, {X, ~u256(0)}}, [=]{ return ~u256(0); }},
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{{Instruction::EQ, {X, 0}}, [=]() -> Pattern { return {Instruction::ISZERO, {X}}; } },
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// operations involving an expression and itself
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{{Instruction::AND, {X, X}}, [=]{ return X; }},
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{{Instruction::OR, {X, X}}, [=]{ return X; }},
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{{Instruction::XOR, {X, X}}, [=]{ return u256(0); }},
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{{Instruction::SUB, {X, X}}, [=]{ return u256(0); }},
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{{Instruction::EQ, {X, X}}, [=]{ return u256(1); }},
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{{Instruction::LT, {X, X}}, [=]{ return u256(0); }},
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{{Instruction::SLT, {X, X}}, [=]{ return u256(0); }},
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{{Instruction::GT, {X, X}}, [=]{ return u256(0); }},
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{{Instruction::SGT, {X, X}}, [=]{ return u256(0); }},
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{{Instruction::MOD, {X, X}}, [=]{ return u256(0); }},
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{{Instruction::NOT, {{Instruction::NOT, {X}}}}, [=]{ return X; }},
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{{Instruction::XOR, {{{X}, {Instruction::XOR, {X, Y}}}}}, [=]{ return Y; }},
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{{Instruction::OR, {{{X}, {Instruction::AND, {X, Y}}}}}, [=]{ return X; }},
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{{Instruction::AND, {{{X}, {Instruction::OR, {X, Y}}}}}, [=]{ return X; }},
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{{Instruction::AND, {{{X}, {Instruction::NOT, {X}}}}}, [=]{ return u256(0); }},
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{{Instruction::OR, {{{X}, {Instruction::NOT, {X}}}}}, [=]{ return ~u256(0); }},
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});
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// Double negation of opcodes with binary result
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for (auto const& op: vector<Instruction>{
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Instruction::EQ,
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Instruction::LT,
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Instruction::SLT,
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Instruction::GT,
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Instruction::SGT
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})
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addRule({
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{Instruction::ISZERO, {{Instruction::ISZERO, {{op, {X, Y}}}}}},
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[=]() -> Pattern { return {op, {X, Y}}; }
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});
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addRule({
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{Instruction::ISZERO, {{Instruction::ISZERO, {{Instruction::ISZERO, {X}}}}}},
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[=]() -> Pattern { return {Instruction::ISZERO, {X}}; }
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});
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addRule({
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{Instruction::ISZERO, {{Instruction::XOR, {X, Y}}}},
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[=]() -> Pattern { return { Instruction::EQ, {X, Y} }; }
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});
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// Associative operations
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for (auto const& opFun: vector<pair<Instruction,function<u256(u256 const&,u256 const&)>>>{
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{Instruction::ADD, plus<u256>()},
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{Instruction::MUL, multiplies<u256>()},
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{Instruction::AND, bit_and<u256>()},
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{Instruction::OR, bit_or<u256>()},
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{Instruction::XOR, bit_xor<u256>()}
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})
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{
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auto op = opFun.first;
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auto fun = opFun.second;
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// Moving constants to the outside, order matters here!
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// we need actions that return expressions (or patterns?) here, and we need also reversed rules
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// (X+A)+B -> X+(A+B)
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addRules(vector<pair<Pattern, function<Pattern()>>>{{
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{op, {{op, {X, A}}, B}},
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[=]() -> Pattern { return {op, {X, fun(A.d(), B.d())}}; }
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}, {
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// X+(Y+A) -> (X+Y)+A
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{op, {{op, {X, A}}, Y}},
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[=]() -> Pattern { return {op, {{op, {X, Y}}, A}}; }
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}, {
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// For now, we still need explicit commutativity for the inner pattern
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{op, {{op, {A, X}}, B}},
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[=]() -> Pattern { return {op, {X, fun(A.d(), B.d())}}; }
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}, {
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{op, {{op, {A, X}}, Y}},
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[=]() -> Pattern { return {op, {{op, {X, Y}}, A}}; }
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}});
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}
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// move constants across subtractions
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addRules(vector<pair<Pattern, function<Pattern()>>>{
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{
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// X - A -> X + (-A)
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{Instruction::SUB, {X, A}},
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[=]() -> Pattern { return {Instruction::ADD, {X, 0 - A.d()}}; }
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}, {
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// (X + A) - Y -> (X - Y) + A
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{Instruction::SUB, {{Instruction::ADD, {X, A}}, Y}},
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[=]() -> Pattern { return {Instruction::ADD, {{Instruction::SUB, {X, Y}}, A}}; }
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}, {
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// (A + X) - Y -> (X - Y) + A
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{Instruction::SUB, {{Instruction::ADD, {A, X}}, Y}},
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[=]() -> Pattern { return {Instruction::ADD, {{Instruction::SUB, {X, Y}}, A}}; }
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}, {
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// X - (Y + A) -> (X - Y) + (-A)
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{Instruction::SUB, {X, {Instruction::ADD, {Y, A}}}},
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[=]() -> Pattern { return {Instruction::ADD, {{Instruction::SUB, {X, Y}}, 0 - A.d()}}; }
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}, {
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// X - (A + Y) -> (X - Y) + (-A)
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{Instruction::SUB, {X, {Instruction::ADD, {A, Y}}}},
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[=]() -> Pattern { return {Instruction::ADD, {{Instruction::SUB, {X, Y}}, 0 - A.d()}}; }
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}
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});
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}
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Pattern::Pattern(Instruction _instruction, std::vector<Pattern> const& _arguments):
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m_type(Operation),
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m_instruction(_instruction),
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m_arguments(_arguments)
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{
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}
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void Pattern::setMatchGroup(unsigned _group, map<unsigned, Expression const*>& _matchGroups)
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{
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m_matchGroup = _group;
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m_matchGroups = &_matchGroups;
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}
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bool Pattern::matches(Expression const& _expr, ExpressionClasses const& _classes) const
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{
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if (!matchesBaseItem(_expr.item))
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return false;
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if (m_matchGroup)
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{
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if (!m_matchGroups->count(m_matchGroup))
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(*m_matchGroups)[m_matchGroup] = &_expr;
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else if ((*m_matchGroups)[m_matchGroup]->id != _expr.id)
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return false;
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}
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assertThrow(m_arguments.size() == 0 || _expr.arguments.size() == m_arguments.size(), OptimizerException, "");
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for (size_t i = 0; i < m_arguments.size(); ++i)
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if (!m_arguments[i].matches(_classes.representative(_expr.arguments[i]), _classes))
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return false;
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return true;
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}
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AssemblyItem Pattern::toAssemblyItem(SourceLocation const& _location) const
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{
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if (m_type == Operation)
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return AssemblyItem(m_instruction, _location);
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else
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return AssemblyItem(m_type, data(), _location);
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}
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string Pattern::toString() const
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{
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stringstream s;
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switch (m_type)
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{
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case Operation:
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s << instructionInfo(m_instruction).name;
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break;
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case Push:
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s << "PUSH " << hex << data();
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break;
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case UndefinedItem:
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s << "ANY";
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break;
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default:
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s << "t=" << dec << m_type << " d=" << hex << data();
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break;
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}
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if (!m_requireDataMatch)
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s << " ~";
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if (m_matchGroup)
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s << "[" << dec << m_matchGroup << "]";
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s << "(";
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for (Pattern const& p: m_arguments)
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s << p.toString() << ", ";
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s << ")";
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return s.str();
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}
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bool Pattern::matchesBaseItem(AssemblyItem const* _item) const
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{
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if (m_type == UndefinedItem)
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return true;
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if (!_item)
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return false;
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if (m_type != _item->type())
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return false;
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else if (m_type == Operation)
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return m_instruction == _item->instruction();
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else if (m_requireDataMatch)
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return data() == _item->data();
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return true;
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}
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Pattern::Expression const& Pattern::matchGroupValue() const
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{
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assertThrow(m_matchGroup > 0, OptimizerException, "");
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assertThrow(!!m_matchGroups, OptimizerException, "");
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assertThrow((*m_matchGroups)[m_matchGroup], OptimizerException, "");
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return *(*m_matchGroups)[m_matchGroup];
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}
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u256 const& Pattern::data() const
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{
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assertThrow(m_data, OptimizerException, "");
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return *m_data;
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}
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ExpressionTemplate::ExpressionTemplate(Pattern const& _pattern, SourceLocation const& _location)
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{
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if (_pattern.matchGroup())
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{
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hasId = true;
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id = _pattern.id();
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}
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else
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{
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hasId = false;
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item = _pattern.toAssemblyItem(_location);
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}
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for (auto const& arg: _pattern.arguments())
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arguments.push_back(ExpressionTemplate(arg, _location));
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}
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string ExpressionTemplate::toString() const
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{
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stringstream s;
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if (hasId)
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s << id;
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else
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s << item;
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s << "(";
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for (auto const& arg: arguments)
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s << arg.toString();
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s << ")";
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return s.str();
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}
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