#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace migraphx { inline namespace MIGRAPHX_INLINE_NS { namespace gpu { struct miopen_apply { module* mod = nullptr; const lowering* pass = nullptr; std::unordered_map> apply_map{}; instruction_ref last{}; std::unordered_map prog_output_names{}; bool offload_copy = false; bool int8_x4_format = true; context& get_context() const { assert(pass != nullptr); assert(pass->ctx != nullptr); return *pass->ctx; } void check_shape(shape x, instruction_ref i) { assert(x == i->get_shape()); (void)x; (void)i; } void create_output_names() { this->last = instruction::get_output_alias(std::prev(mod->end())); if(this->last->name() == "@return") { const auto& prog_outputs = last->inputs(); std::vector outputs_alias(prog_outputs.size()); std::transform(prog_outputs.begin(), prog_outputs.end(), outputs_alias.begin(), [](const auto& i) { return instruction::get_output_alias(i); }); std::size_t index = 0; for(auto ins : outputs_alias) { prog_output_names[ins] = mod->name() + ":#output_" + std::to_string(index++); } } } void init() { assert(mod != nullptr); assert(pass != nullptr); #if ROCBLAS_VERSION_MAJOR >= 2 && ROCBLAS_VERSION_MINOR >= 38 auto& ctx = get_context(); rocblas_gemm_flags flag; rocblas_query_int8_layout_flag(ctx.get_stream().get_rocblas(), &flag); int8_x4_format = (flag == rocblas_gemm_flags_pack_int8x4); #endif offload_copy = (mod->name() == "main") ? pass->offload_copy : false; create_output_names(); add_generic_op("acos"); add_generic_op("acosh"); add_generic_op("add"); add_generic_op("asin"); add_generic_op("asinh"); add_generic_op("atan"); add_generic_op("atanh"); add_generic_op("ceil"); add_generic_op("contiguous"); add_generic_op("cos"); add_generic_op("cosh"); add_generic_op("div"); add_generic_op("equal"); add_generic_op("erf"); add_generic_op("exp"); add_generic_op("floor"); add_generic_op("greater"); add_generic_op("less"); add_generic_op("log"); add_generic_op("logical_and"); add_generic_op("logical_or"); add_generic_op("logical_xor"); add_generic_op("max"); add_generic_op("min"); add_generic_op("mul"); add_generic_op("not"); add_generic_op("pow"); add_generic_op("prelu"); add_generic_op("recip"); add_generic_op("relu"); add_generic_op("round"); add_generic_op("rsqrt"); add_generic_op("sigmoid"); add_generic_op("sign"); add_generic_op("sin"); add_generic_op("sinh"); add_generic_op("sqdiff"); add_generic_op("sqrt"); add_generic_op("sub"); add_generic_op("tan"); add_generic_op("tanh"); add_generic_op("where"); add_extend_op("abs"); add_extend_op("argmax"); add_extend_op("argmin"); add_extend_op("clip"); add_extend_op("concat"); add_extend_op("convert"); add_extend_op("elu"); add_extend_op("gather"); add_extend_op("leaky_relu"); add_extend_op("logsoftmax"); add_extend_op("lrn"); add_extend_op("multinomial"); add_extend_op("nonzero"); add_extend_op("pad"); add_extend_op("pooling"); add_extend_op("prefix_scan_sum"); add_extend_op("reduce_max"); add_extend_op("reduce_mean"); add_extend_op("reduce_min"); add_extend_op("reduce_prod"); add_extend_op("reduce_sum"); add_extend_op("reverse"); add_extend_op("rnn_var_sl_last_output"); add_extend_op("rnn_var_sl_shift_output"); add_extend_op("rnn_var_sl_shift_sequence"); add_extend_op("scatter"); add_extend_op("softmax"); add_extend_op("topk"); add_precompile_op("pointwise"); add_batch_norm_inference_op(); add_convolution_op(); add_deconvolution_op(); add_gemm_op("dot"); add_gemm_op("quant_dot"); add_if_op(); add_loop_op(); add_neg_op(); add_nms_op(); add_quant_convolution_op(); add_roialign(); } void copy_params() { if(not offload_copy) return; for(auto ins : iterator_for(*mod)) { if(ins->name() != "@param") continue; // parameter no outputs, no need to insert copy to gpu if(ins->outputs().empty()) continue; auto pos = std::next(ins); auto a = insert_allocation(pos, ins->get_shape()); auto c = mod->insert_instruction(pos, make_op("hip::copy_to_gpu"), ins, a); mod->replace_instruction(ins, c); } // return instruction auto ret = std::prev(mod->end()); if(ret->name() == "@return") { const auto& inputs = ret->inputs(); // each input of ret need to be copied from gpu to host, and replace // output with copy output for(const auto& in : inputs) { auto p_output = mod->insert_instruction(ret, make_op("hip::copy_from_gpu"), in); instruction::replace_argument(ret, in, p_output); } } // else branch to handle legacy program without the return instruction else { mod->add_instruction(make_op("hip::copy_from_gpu"), ret); } } void apply() { init(); for(auto it = mod->begin(); it != mod->end(); it++) { auto s = it->get_shape(); if(apply_map.count(it->name()) > 0) { check_shape(s, apply_map.at(it->name())(it)); } } copy_params(); } instruction_ref insert_allocation(instruction_ref ins, const shape& s, std::string tag = "") { // Instruction's output is an input of the ret instruction if(offload_copy) { auto result = mod->insert_instruction( ins, make_op("hip::allocate", {{"shape", to_value(s)}, {"tag", std::move(tag)}})); return result; } auto ins_alias = instruction::get_output_alias(ins); if(last->name() == "@return" and tag.empty() and prog_output_names.count(ins_alias) > 0) { return mod->add_parameter(prog_output_names[ins_alias], s); } else if(ins == last and tag.empty()) { return mod->add_parameter("output", s); } return mod->insert_instruction( ins, make_op("hip::allocate", {{"shape", to_value(s)}, {"tag", std::move(tag)}})); } void add_convolution_op() { apply_map.emplace("convolution", [=](instruction_ref ins) { auto&& op = any_cast(ins->get_operator()); auto conv = miopen_convolution{op, make_conv(op)}; auto ws = conv.find(get_context(), ins->get_shape(), to_shapes(ins->inputs())); auto workspace = insert_allocation(ins, ws, "workspace"); auto output = insert_allocation(ins, ins->get_shape()); return mod->replace_instruction( ins, conv, ins->inputs().at(0), ins->inputs().at(1), workspace, output); }); } void add_deconvolution_op() { apply_map.emplace("deconvolution", [=](instruction_ref ins) { auto&& op = any_cast(ins->get_operator()); auto conv = miopen_deconvolution{op, make_deconv(op)}; auto ws = conv.compile(get_context(), ins->get_shape(), to_shapes(ins->inputs())); auto workspace = insert_allocation(ins, ws, "workspace"); auto output = insert_allocation(ins, ins->get_shape()); return mod->replace_instruction( ins, conv, ins->inputs().at(0), ins->inputs().at(1), workspace, output); }); } template void add_gemm_op(const std::string& name) { apply_map.emplace(name, [=](instruction_ref ins) { std::vector refs = ins->inputs(); if(refs.size() == 2) { auto output = insert_allocation(ins, ins->get_shape()); refs.push_back(output); } else { auto c_alias = instruction::get_output_alias(refs.back()); if(ins == last or refs.back()->outputs().size() > 1 or c_alias->inputs().empty()) { auto output = insert_allocation(ins, ins->get_shape()); auto copy_out = mod->insert_instruction(ins, make_op("hip::copy"), refs.back(), output); refs.back() = copy_out; refs.push_back(copy_out); } else { refs.push_back(refs.back()); } } return mod->replace_instruction( ins, rocblas_gemm{Op{}, 1, 0, int8_x4_format}, refs); }); } void add_quant_convolution_op() { apply_map.emplace("quant_convolution", [=](instruction_ref ins) { auto&& op = any_cast(ins->get_operator()); auto conv = miopen_quant_convolution{op, make_conv(op)}; auto ws = conv.compile(get_context(), ins->get_shape(), to_shapes(ins->inputs())); auto args = ins->inputs(); auto workspace = insert_allocation(ins, ws, "workspace"); auto output = insert_allocation(ins, ins->get_shape()); return mod->replace_instruction(ins, conv, args[0], args[1], workspace, output); }); } void add_generic_op(const std::string& name) { add_generic_op(name, "gpu::" + name); } void add_generic_op(const std::string& op_name, const std::string& gpu_name) { apply_map.emplace(op_name, [=](instruction_ref ins) { auto output = insert_allocation(ins, ins->get_shape()); std::vector refs = ins->inputs(); refs.push_back(output); return mod->replace_instruction(ins, make_op(gpu_name), refs); }); } void add_extend_op(const std::string& name) { add_extend_op(name, "gpu::" + name); } void add_extend_op(const std::string& op_name, const std::string& gpu_name) { apply_map.emplace(op_name, [=](instruction_ref ins) { auto&& op = ins->get_operator(); auto output = insert_allocation(ins, ins->get_shape()); std::vector refs = ins->inputs(); refs.push_back(output); return mod->replace_instruction(ins, make_op(gpu_name, op.to_value()), refs); }); } void add_precompile_op(const std::string& name) { apply_map.emplace(name, [=](instruction_ref ins) { auto output = insert_allocation(ins, ins->get_shape()); std::vector refs = ins->inputs(); refs.push_back(output); return mod->replace_instruction( ins, make_op("gpu::precompile_op", {{"op", to_value(ins->get_operator())}}), refs, ins->module_inputs()); }); } void add_batch_norm_inference_op() { apply_map.emplace("batch_norm_inference", [=](instruction_ref ins) { auto&& op = any_cast(ins->get_operator()); auto output = insert_allocation(ins, ins->get_shape()); shape old_shape = ins->inputs().at(1)->get_shape(); auto input = ins->inputs()[0]; auto input_lens = input->get_shape().lens(); std::vector rsp_lens(input_lens.size(), 1); // for per_activation case, also need to reshape input if(op.bn_mode == op::batch_norm_inference::per_activation) { std::copy(input_lens.begin() + 1, input_lens.end(), rsp_lens.begin() + 1); } else { rsp_lens[1] = static_cast(old_shape.elements()); } auto reshape_op = op::reshape{rsp_lens}; std::vector reshapes; std::transform(ins->inputs().begin() + 1, ins->inputs().end(), std::back_inserter(reshapes), [&](auto i) { return mod->insert_instruction(ins, reshape_op, i); }); return mod->replace_instruction(ins, miopen_batch_norm_inference{op}, input, reshapes[0], reshapes[1], reshapes[2], reshapes[3], output); }); } // use 0 - input to represent neg void add_neg_op() { apply_map.emplace("neg", [=](instruction_ref ins) { auto s = ins->get_shape(); std::vector zeros(s.elements(), 0.0f); auto l0 = mod->add_literal(literal(s, zeros)); auto output = insert_allocation(ins, s); return mod->replace_instruction( ins, make_op("gpu::sub"), l0, ins->inputs().front(), output); }); } // add input and output argument for the if operator void add_if_op() { apply_map.emplace("if", [=](instruction_ref ins) { std::vector inputs = ins->inputs(); auto cpu_cond = mod->insert_instruction(ins, make_op("hip::copy_from_gpu"), inputs.front()); auto sync_cond = mod->insert_instruction(ins, make_op("hip::sync_stream"), cpu_cond); inputs.front() = sync_cond; std::vector mod_args = ins->module_inputs(); std::map name_shapes; for(const auto& smod : mod_args) { auto ps = smod->get_parameter_shapes(); name_shapes.insert(ps.begin(), ps.end()); } bool ins_output_allocated = false; for(auto& pn : name_shapes) { const auto& s = pn.second; instruction_ref output{}; if(s == ins->get_shape() and not ins_output_allocated) { output = insert_allocation(ins, s); ins_output_allocated = true; } else { output = mod->insert_instruction( ins, make_op("hip::allocate", {{"shape", to_value(s)}})); } inputs.push_back(output); } return mod->replace_instruction(ins, ins->get_operator(), inputs, mod_args); }); } void add_roialign() { apply_map.emplace("roialign", [=](instruction_ref ins) { auto s = ins->get_shape(); auto op_val = ins->get_operator().to_value(); auto output = insert_allocation(ins, s); auto args = ins->inputs(); args.push_back(output); auto io_shapes = to_shapes(args); auto co = compile_roialign(get_context(), io_shapes, op_val); return mod->replace_instruction(ins, co, args); }); } // replace the loop operator with gpu_loop operator void add_loop_op() { apply_map.emplace("loop", [=](instruction_ref ins) { std::vector inputs = ins->inputs(); // copy max_iter from gpu to cpu auto cpu_max_iter = mod->insert_instruction(ins, make_op("hip::copy_from_gpu"), inputs.at(0)); auto cpu_cond = mod->insert_instruction(ins, make_op("hip::copy_from_gpu"), inputs.at(1)); auto synced_max_iter = mod->insert_instruction(ins, make_op("hip::sync_stream"), cpu_max_iter, cpu_cond); inputs.at(0) = synced_max_iter; inputs.at(1) = cpu_cond; auto copy_inputs = inputs; std::transform( copy_inputs.begin(), copy_inputs.end(), std::back_inserter(inputs), [&](auto in) { return mod->insert_instruction( ins, make_op("hip::allocate", {{"shape", to_value(in->get_shape())}})); }); auto mod_args = ins->module_inputs(); auto output = insert_allocation(ins, ins->get_shape()); const auto* sub_mod = mod_args.front(); auto cond_out = mod->insert_instruction( ins, make_op("hip::allocate", {{"shape", to_value(sub_mod->get_output_shapes().front())}})); // add cond and mod outputs to the argument list inputs.push_back(cond_out); inputs.push_back(output); return mod->replace_instruction( ins, make_op("gpu::loop", ins->get_operator().to_value()), inputs, mod_args); }); } void add_nms_op() { apply_map.emplace("nonmaxsuppression", [=](instruction_ref ins) { auto s = ins->get_shape(); auto output = insert_allocation(ins, s); std::vector cpu_inputs; auto inputs = ins->inputs(); std::transform( inputs.begin(), inputs.end(), std::back_inserter(cpu_inputs), [&](auto in) { return mod->insert_instruction(ins, make_op("hip::copy_from_gpu"), in); }); cpu_inputs.front() = mod->insert_instruction(ins, make_op("hip::sync_stream"), cpu_inputs); auto cpu_out = mod->insert_instruction(ins, ins->get_operator(), cpu_inputs); auto gpu_out = mod->insert_instruction(ins, make_op("hip::copy_to_gpu"), cpu_out, output); return mod->replace_instruction(ins, gpu_out); }); } }; void lowering::apply(module& m) const { miopen_apply{&m, this}.apply(); } } // namespace gpu } // namespace MIGRAPHX_INLINE_NS } // namespace migraphx