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/*
* Copyright 2016 WebAssembly Community Group participants
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifndef WABT_DECOMPILER_AST_H_
#define WABT_DECOMPILER_AST_H_
#include "wabt/cast.h"
#include "wabt/generate-names.h"
#include "wabt/ir-util.h"
#include "wabt/ir.h"
#include <map>
namespace wabt {
enum class NodeType {
Uninitialized,
FlushToVars,
FlushedVar,
Statements,
EndReturn,
Decl,
DeclInit,
Expr
};
// The AST we're going to convert the standard IR into.
struct Node {
NodeType ntype;
ExprType etype; // Only if ntype == Expr.
const Expr* e;
std::vector<Node> children;
// Node specific annotations.
union {
struct {
Index var_start, var_count; // FlushedVar/FlushToVars
};
const Var* var; // Decl/DeclInit.
LabelType lt; // br/br_if target.
} u;
Node() : ntype(NodeType::Uninitialized), etype(ExprType::Nop), e(nullptr) {}
Node(NodeType ntype, ExprType etype, const Expr* e, const Var* v)
: ntype(ntype), etype(etype), e(e) {
u.var = v;
}
// This value should really never be copied, only moved.
Node(const Node& rhs) = delete;
Node& operator=(const Node& rhs) = delete;
Node(Node&& rhs) { *this = std::move(rhs); }
Node& operator=(Node&& rhs) {
ntype = rhs.ntype;
// Reset ntype to avoid moved from values still being used.
rhs.ntype = NodeType::Uninitialized;
etype = rhs.etype;
rhs.etype = ExprType::Nop;
e = rhs.e;
std::swap(children, rhs.children);
u = rhs.u;
return *this;
}
};
struct AST {
AST(ModuleContext& mc, const Func* f) : mc(mc), f(f) {
if (f) {
mc.BeginFunc(*f);
for (Index i = 0; i < f->GetNumParams(); i++) {
auto name = "$" + IndexToAlphaName(i);
vars_defined.insert({name, {0, false}});
}
}
}
~AST() {
if (f) {
mc.EndFunc();
}
}
// Create a new node, take nargs existing nodes on the exp stack as children.
Node& InsertNode(NodeType ntype, ExprType etype, const Expr* e, Index nargs) {
assert(exp_stack.size() >= nargs);
Node n{ntype, etype, e, nullptr};
n.children.reserve(nargs);
std::move(exp_stack.end() - nargs, exp_stack.end(),
std::back_inserter(n.children));
exp_stack.erase(exp_stack.end() - nargs, exp_stack.end());
exp_stack.push_back(std::move(n));
return exp_stack.back();
}
template <ExprType T>
void PreDecl(const VarExpr<T>& ve) {
// FIXME: this is slow, and would be better to avoid in callers.
// See https://github.com/WebAssembly/wabt/issues/1565
// And https://github.com/WebAssembly/wabt/issues/1665
for (auto& n : predecls) {
if (n.u.var->name() == ve.var.name()) {
return;
}
}
predecls.emplace_back(NodeType::Decl, ExprType::Nop, nullptr, &ve.var);
}
template <ExprType T>
void Get(const VarExpr<T>& ve, bool local) {
if (local) {
auto ret = vars_defined.insert({ve.var.name(), {cur_block_id, false}});
if (ret.second) {
// Use before def, may happen since locals are guaranteed 0.
PreDecl(ve);
} else if (blocks_closed[ret.first->second.block_id]) {
// This is a use of a variable that was defined in a block that has
// already ended. This happens rarely, but we should cater for this
// case by lifting it to the top scope.
PreDecl(ve);
}
}
InsertNode(NodeType::Expr, T, &ve, 0);
}
template <ExprType T>
void Set(const VarExpr<T>& ve, bool local) {
// Seen this var before?
if (local &&
vars_defined.insert({ve.var.name(), {cur_block_id, false}}).second) {
if (value_stack_depth == 1) {
// Top level, declare it here.
InsertNode(NodeType::DeclInit, ExprType::Nop, nullptr, 1).u.var =
&ve.var;
return;
} else {
// Inside exp, better leave it as assignment exp and lift the decl out.
PreDecl(ve);
}
}
InsertNode(NodeType::Expr, T, &ve, 1);
}
template <ExprType T>
void Block(const BlockExprBase<T>& be, LabelType label) {
mc.BeginBlock(label, be.block);
Construct(be.block.exprs, be.block.decl.GetNumResults(),
be.block.decl.GetNumParams(), false);
mc.EndBlock();
InsertNode(NodeType::Expr, T, &be, 1);
}
void Construct(const Expr& e) {
auto arity = mc.GetExprArity(e);
switch (e.type()) {
case ExprType::LocalGet: {
Get(*cast<LocalGetExpr>(&e), true);
return;
}
case ExprType::GlobalGet: {
Get(*cast<GlobalGetExpr>(&e), false);
return;
}
case ExprType::LocalSet: {
Set(*cast<LocalSetExpr>(&e), true);
return;
}
case ExprType::GlobalSet: {
Set(*cast<GlobalSetExpr>(&e), false);
return;
}
case ExprType::LocalTee: {
auto& lt = *cast<LocalTeeExpr>(&e);
Set(lt, true);
if (value_stack_depth == 1) { // Tee is the only thing on there.
Get(lt, true); // Now Set + Get instead.
} else {
// Things are above us on the stack so the Tee can't be eliminated.
// The Set makes this work as a Tee when consumed by a parent.
}
return;
}
case ExprType::If: {
auto ife = cast<IfExpr>(&e);
value_stack_depth--; // Condition.
mc.BeginBlock(LabelType::Block, ife->true_);
Construct(ife->true_.exprs, ife->true_.decl.GetNumResults(),
ife->true_.decl.GetNumParams(), false);
if (!ife->false_.empty()) {
Construct(ife->false_, ife->true_.decl.GetNumResults(),
ife->true_.decl.GetNumParams(), false);
}
mc.EndBlock();
value_stack_depth++; // Put Condition back.
InsertNode(NodeType::Expr, ExprType::If, &e,
ife->false_.empty() ? 2 : 3);
return;
}
case ExprType::Block: {
Block(*cast<BlockExpr>(&e), LabelType::Block);
return;
}
case ExprType::Loop: {
Block(*cast<LoopExpr>(&e), LabelType::Loop);
return;
}
case ExprType::Br: {
InsertNode(NodeType::Expr, ExprType::Br, &e, 0).u.lt =
mc.GetLabel(cast<BrExpr>(&e)->var)->label_type;
return;
}
case ExprType::BrIf: {
InsertNode(NodeType::Expr, ExprType::BrIf, &e, 1).u.lt =
mc.GetLabel(cast<BrIfExpr>(&e)->var)->label_type;
return;
}
case ExprType::BrTable: {
InsertNode(NodeType::Expr, ExprType::BrTable, &e, 1).u.lt =
mc.GetLabel(cast<BrTableExpr>(&e)->default_target)->label_type;
return;
}
default: {
InsertNode(NodeType::Expr, e.type(), &e, arity.nargs);
return;
}
}
}
void Construct(const ExprList& es,
Index nresults,
Index nparams,
bool is_function_body) {
block_stack.push_back(cur_block_id);
cur_block_id = blocks_closed.size();
blocks_closed.push_back(false);
auto start = exp_stack.size();
int value_stack_depth_start = value_stack_depth - nparams;
auto value_stack_in_variables = value_stack_depth;
bool unreachable = false;
for (auto& e : es) {
Construct(e);
auto arity = mc.GetExprArity(e);
value_stack_depth -= arity.nargs;
value_stack_in_variables =
std::min(value_stack_in_variables, value_stack_depth);
unreachable = unreachable || arity.unreachable;
assert(unreachable || value_stack_depth >= value_stack_depth_start);
value_stack_depth += arity.nreturns;
// We maintain the invariant that a value_stack_depth of N is represented
// by the last N exp_stack items (each of which returning exactly 1
// value), all exp_stack items before it return void ("statements").
// In particular for the wasm stack:
// - The values between 0 and value_stack_depth_start are part of the
// parent block, and not touched here.
// - The values from there up to value_stack_in_variables are variables
// to be used, representing previous statements that flushed the
// stack into variables.
// - Values on top of that up to value_stack_depth are exps returning
// a single value.
// The code below maintains the above invariants. With this in place
// code "falls into place" the way you expect it.
if (arity.nreturns != 1) {
auto num_vars = value_stack_in_variables - value_stack_depth_start;
auto num_vals = value_stack_depth - value_stack_in_variables;
auto GenFlushVars = [&](int nargs) {
auto& ftv =
InsertNode(NodeType::FlushToVars, ExprType::Nop, nullptr, nargs);
ftv.u.var_start = flushed_vars;
ftv.u.var_count = num_vals;
};
auto MoveStatementsBelowVars = [&](size_t amount) {
std::rotate(exp_stack.end() - num_vars - amount,
exp_stack.end() - amount, exp_stack.end());
};
auto GenFlushedVars = [&]() {
// Re-generate these values as vars.
for (int i = 0; i < num_vals; i++) {
auto& fv =
InsertNode(NodeType::FlushedVar, ExprType::Nop, nullptr, 0);
fv.u.var_start = flushed_vars++;
fv.u.var_count = 1;
}
};
if (arity.nreturns == 0 &&
value_stack_depth > value_stack_depth_start) {
// We have a void item on top of the exp_stack, so we must "lift" the
// previous values around it.
// We track what part of the stack is in variables to avoid doing
// this unnecessarily.
if (num_vals > 0) {
// We have actual new values that need lifting.
// This puts the part of the stack that wasn't already a variable
// (before the current void exp) into a FlushToVars.
auto void_exp = std::move(exp_stack.back());
exp_stack.pop_back();
GenFlushVars(num_vals);
exp_stack.push_back(std::move(void_exp));
// Put this flush statement + void statement before any
// existing variables.
MoveStatementsBelowVars(2);
// Now re-generate these values after the void exp as vars.
GenFlushedVars();
} else {
// We have existing variables that need lifting, but no need to
// create them anew.
std::rotate(exp_stack.end() - num_vars - 1, exp_stack.end() - 1,
exp_stack.end());
}
value_stack_in_variables = value_stack_depth;
} else if (arity.nreturns > 1) {
// Multivalue: we flush the stack also.
// Number of other non-variable values that may be present:
assert(num_vals >= static_cast<int>(arity.nreturns));
// Flush multi-value exp + others.
GenFlushVars(num_vals - arity.nreturns + 1);
// Put this flush statement before any existing variables.
MoveStatementsBelowVars(1);
GenFlushedVars();
value_stack_in_variables = value_stack_depth;
}
} else {
// Special optimisation: for constant instructions, we can mark these
// as if they were variables, so they can be re-ordered for free with
// the above code, without needing new variables!
// TODO: this would be nice to also do for local.get and maybe others,
// though that needs a way to ensure there's no local.set in between
// when they get lifted, so complicates matters a bit.
if (e.type() == ExprType::Const &&
value_stack_in_variables == value_stack_depth - 1) {
value_stack_in_variables++;
}
}
}
assert(unreachable || value_stack_depth - value_stack_depth_start ==
static_cast<int>(nresults));
// Undo any changes to value_stack_depth, since parent takes care of arity
// changes.
value_stack_depth = value_stack_depth_start;
auto end = exp_stack.size();
assert(end >= start);
if (is_function_body) {
if (!exp_stack.empty()) {
if (exp_stack.back().etype == ExprType::Return) {
if (exp_stack.back().children.empty()) {
// Return statement at the end of a void function.
exp_stack.pop_back();
}
} else if (nresults) {
// Combine nresults into a return statement, for when this is used as
// a function body.
// TODO: if this is some other kind of block and >1 value is being
// returned, probably need some kind of syntax to make that clearer.
InsertNode(NodeType::EndReturn, ExprType::Nop, nullptr, nresults);
}
}
// TODO: these predecls are always at top level, but in the case of
// use inside an exp, it be nice to do it in the current block. Can't
// do that for predecls that are "out if scope" however.
std::move(predecls.begin(), predecls.end(),
std::back_inserter(exp_stack));
std::rotate(exp_stack.begin(), exp_stack.end() - predecls.size(),
exp_stack.end());
predecls.clear();
}
end = exp_stack.size();
assert(end >= start);
auto size = end - start;
if (size != 1) {
InsertNode(NodeType::Statements, ExprType::Nop, nullptr, size);
}
blocks_closed[cur_block_id] = true;
cur_block_id = block_stack.back();
block_stack.pop_back();
}
ModuleContext& mc;
std::vector<Node> exp_stack;
std::vector<Node> predecls;
const Func* f;
int value_stack_depth = 0;
struct Variable {
size_t block_id;
bool defined;
};
std::map<std::string, Variable> vars_defined;
Index flushed_vars = 0;
size_t cur_block_id = 0;
std::vector<size_t> block_stack;
std::vector<bool> blocks_closed;
};
} // namespace wabt
#endif // WABT_DECOMPILER_AST_H_
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