#include #include #include namespace migraphx { inline namespace MIGRAPHX_INLINE_NS { instruction::instruction(operation o, shape r, std::vector args) : op(std::move(o)), result(std::move(r)), arguments(std::move(args)) { } instruction::instruction(literal l) : op(builtin::literal{}), result(l.get_shape()), lit(std::move(l)) { } void instruction::replace(const shape& r) { if(r != result) { result = r; for(auto&& ins : output) { if(ins->name() == "@return") continue; assert(ins->name().front() != '@'); ins->recompute_shape(); } } } void instruction::replace(operation o) { op = std::move(o); recompute_shape(); } void instruction::recompute_shape() { replace(compute_shape(op, arguments)); } void instruction::clear_arguments() { for(auto&& arg : arguments) { arg->remove_output(*this); } arguments.clear(); } bool operator==(const instruction& i, instruction_ref ref) { return std::addressof(i) == std::addressof(*ref); } bool instruction::valid(instruction_ref start) const { return valid() && std::all_of(arguments.begin(), arguments.end(), [&](instruction_ref i) { auto self = std::find(i->outputs().begin(), i->outputs().end(), *this); return self != i->outputs().end() && std::distance(start, i) < std::distance(start, *self); }); } bool instruction::valid() const { shape computed; if(op.name() == "@literal") { computed = lit.get_shape(); } else if(op.name() == "@param") { computed = result; } else if(op.name() == "@return") { computed = {}; } else { try { computed = compute_shape(op, arguments); } catch(migraphx::exception&) { return false; } } return result == computed && std::all_of(output.begin(), output.end(), [&](instruction_ref i) { return std::find(i->inputs().begin(), i->inputs().end(), *this) != i->inputs().end(); }); } shape instruction::get_shape() const { return result; } const literal& instruction::get_literal() const { assert(op.name() == "@literal"); return lit; } const operation& instruction::get_operator() const { return op; } std::string instruction::name() const { return op.name(); } const std::vector& instruction::inputs() const { return arguments; } const std::vector& instruction::outputs() const { return output; } bool operator==(const instruction& x, const instruction& y) { if(std::tie(x.result, x.op, x.arguments) != std::tie(y.result, y.op, y.arguments)) return false; if(x.name() == "@literal") return x.lit == y.lit; return true; } bool operator!=(const instruction& x, const instruction& y) { return !(x == y); } bool operator==(instruction_ref ref, const instruction& i) { return i == ref; } bool operator!=(const instruction& i, instruction_ref ref) { return !(i == ref); } bool operator!=(instruction_ref ref, const instruction& i) { return !(i == ref); } void instruction::add_output(instruction_ref ins) { if(std::find(output.begin(), output.end(), ins) == output.end()) output.push_back(ins); } void instruction::backreference(instruction_ref ref) { for(auto&& arg : ref->inputs()) arg->add_output(ref); } void instruction::replace_argument(instruction_ref ins, instruction_ref old, instruction_ref new_ins) { ins->replace_argument(old, new_ins); backreference(ins); ins->recompute_shape(); } void instruction::replace(instruction_ref ins, operation o, const shape& r, std::vector args) { ins->replace(std::move(o), r, std::move(args)); backreference(ins); } void instruction::replace(operation o, const shape& r, std::vector args) { op = std::move(o); replace(r); replace(std::move(args)); } void instruction::replace(std::vector args) { clear_arguments(); arguments = std::move(args); } void instruction::replace_argument(instruction_ref old, instruction_ref new_ins) { assert(std::any_of(arguments.begin(), arguments.end(), [&](auto i) { return i == old; })); std::replace(arguments.begin(), arguments.end(), old, new_ins); old->remove_output(*this); } bool instruction::can_eval() const { if(op.name() == "@literal") { return true; } else if(is_context_free(op)) { return std::all_of( this->inputs().begin(), this->inputs().end(), [](auto arg) { return arg->can_eval(); }); } else { return false; } } argument instruction::eval(bool check_eval) const { if(op.name() == "@literal") { return this->get_literal().get_argument(); } if(is_context_free(op)) { if(check_eval and not this->can_eval()) return {}; std::vector args; std::transform(this->inputs().begin(), this->inputs().end(), std::back_inserter(args), [](auto arg) { return arg->eval(false); }); return op.compute(result, args); } return {}; } void instruction::finalize(context& ctx) { if(has_finalize(this->op)) this->op.finalize(ctx, this->get_shape(), to_shapes(this->inputs())); } static void debug_name(std::ostream& os, const instruction& ins) { if(ins.name() == "@literal") { os << "@literal"; if(ins.get_literal().get_shape().elements() > 10) os << "{ ... }"; else os << "{" << ins.get_literal() << "}"; } else { os << ins.get_operator(); } } void instruction::debug_print() const { debug_name(std::cout, *this); std::string delim = "("; for(auto arg : this->inputs()) { std::cout << delim; debug_name(std::cout, *arg); delim = ", "; } if(not this->inputs().empty()) std::cout << ")"; std::cout << " -> " << this->get_shape() << std::endl; } instruction_ref instruction::get_output_alias(instruction_ref ins, bool shallow) { auto i = ins->get_operator().output_alias(to_shapes(ins->inputs())); if(i < 0) return ins; if(shallow) return ins->inputs().at(i); return get_output_alias(ins->inputs().at(i)); } std::vector to_shapes(const std::vector& args) { std::vector shapes(args.size()); std::transform( args.begin(), args.end(), shapes.begin(), [](instruction_ref i) { return i->get_shape(); }); return shapes; } shape compute_shape(const operation& op, const std::vector& args) { return op.compute_shape(to_shapes(args)); } } // namespace MIGRAPHX_INLINE_NS } // namespace migraphx