# Copyright (c) 1999-2008 Mark D. Hill and David A. Wood # Copyright (c) 2009 The Hewlett-Packard Development Company # All rights reserved. # # Redistribution and use in source and binary forms, with or without # modification, are permitted provided that the following conditions are # met: redistributions of source code must retain the above copyright # notice, this list of conditions and the following disclaimer; # redistributions in binary form must reproduce the above copyright # notice, this list of conditions and the following disclaimer in the # documentation and/or other materials provided with the distribution; # neither the name of the copyright holders nor the names of its # contributors may be used to endorse or promote products derived from # this software without specific prior written permission. # # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS # "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT # LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR # A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT # OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, # SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT # LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, # DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY # THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT # (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE # OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. from m5.util import orderdict from slicc.symbols.Symbol import Symbol from slicc.symbols.Var import Var import slicc.generate.html as html import re python_class_map = {"int": "Int", "std::string": "String", "bool": "Bool", "CacheMemory": "RubyCache", "WireBuffer": "RubyWireBuffer", "Sequencer": "RubySequencer", "DirectoryMemory": "RubyDirectoryMemory", "MemoryControl": "RubyMemoryControl", "DMASequencer": "DMASequencer" } class StateMachine(Symbol): def __init__(self, symtab, ident, location, pairs, config_parameters): super(StateMachine, self).__init__(symtab, ident, location, pairs) self.table = None self.config_parameters = config_parameters for param in config_parameters: if param.pointer: var = Var(symtab, param.name, location, param.type_ast.type, "(*m_%s_ptr)" % param.name, {}, self) else: var = Var(symtab, param.name, location, param.type_ast.type, "m_%s" % param.name, {}, self) self.symtab.registerSym(param.name, var) self.states = orderdict() self.events = orderdict() self.actions = orderdict() self.transitions = [] self.in_ports = [] self.functions = [] self.objects = [] self.TBEType = None self.EntryType = None self.message_buffer_names = [] def __repr__(self): return "[StateMachine: %s]" % self.ident def addState(self, state): assert self.table is None self.states[state.ident] = state def addEvent(self, event): assert self.table is None self.events[event.ident] = event def addAction(self, action): assert self.table is None # Check for duplicate action for other in self.actions.itervalues(): if action.ident == other.ident: action.warning("Duplicate action definition: %s" % action.ident) action.error("Duplicate action definition: %s" % action.ident) if action.short == other.short: other.warning("Duplicate action shorthand: %s" % other.ident) other.warning(" shorthand = %s" % other.short) action.warning("Duplicate action shorthand: %s" % action.ident) action.error(" shorthand = %s" % action.short) self.actions[action.ident] = action def addTransition(self, trans): assert self.table is None self.transitions.append(trans) def addInPort(self, var): self.in_ports.append(var) def addFunc(self, func): # register func in the symbol table self.symtab.registerSym(str(func), func) self.functions.append(func) def addObject(self, obj): self.objects.append(obj) def addType(self, type): type_ident = '%s' % type.c_ident if type_ident == "%s_TBE" %self.ident: if self.TBEType != None: self.error("Multiple Transaction Buffer types in a " \ "single machine."); self.TBEType = type elif "interface" in type and "AbstractCacheEntry" == type["interface"]: if self.EntryType != None: self.error("Multiple AbstractCacheEntry types in a " \ "single machine."); self.EntryType = type # Needs to be called before accessing the table def buildTable(self): assert self.table is None table = {} for trans in self.transitions: # Track which actions we touch so we know if we use them # all -- really this should be done for all symbols as # part of the symbol table, then only trigger it for # Actions, States, Events, etc. for action in trans.actions: action.used = True index = (trans.state, trans.event) if index in table: table[index].warning("Duplicate transition: %s" % table[index]) trans.error("Duplicate transition: %s" % trans) table[index] = trans # Look at all actions to make sure we used them all for action in self.actions.itervalues(): if not action.used: error_msg = "Unused action: %s" % action.ident if "desc" in action: error_msg += ", " + action.desc action.warning(error_msg) self.table = table def writeCodeFiles(self, path): self.printControllerPython(path) self.printControllerHH(path) self.printControllerCC(path) self.printCSwitch(path) self.printCWakeup(path) self.printProfilerCC(path) self.printProfilerHH(path) self.printProfileDumperCC(path) self.printProfileDumperHH(path) def printControllerPython(self, path): code = self.symtab.codeFormatter() ident = self.ident py_ident = "%s_Controller" % ident c_ident = "%s_Controller" % self.ident code(''' from m5.params import * from m5.SimObject import SimObject from Controller import RubyController class $py_ident(RubyController): type = '$py_ident' ''') code.indent() for param in self.config_parameters: dflt_str = '' if param.default is not None: dflt_str = str(param.default) + ', ' if python_class_map.has_key(param.type_ast.type.c_ident): python_type = python_class_map[param.type_ast.type.c_ident] code('${{param.name}} = Param.${{python_type}}(${dflt_str}"")') else: self.error("Unknown c++ to python class conversion for c++ " \ "type: '%s'. Please update the python_class_map " \ "in StateMachine.py", param.type_ast.type.c_ident) code.dedent() code.write(path, '%s.py' % py_ident) def printControllerHH(self, path): '''Output the method declarations for the class declaration''' code = self.symtab.codeFormatter() ident = self.ident c_ident = "%s_Controller" % self.ident self.message_buffer_names = [] code(''' /** \\file $c_ident.hh * * Auto generated C++ code started by $__file__:$__line__ * Created by slicc definition of Module "${{self.short}}" */ #ifndef __${ident}_CONTROLLER_HH__ #define __${ident}_CONTROLLER_HH__ #include #include #include #include "mem/protocol/${ident}_ProfileDumper.hh" #include "mem/protocol/${ident}_Profiler.hh" #include "mem/protocol/TransitionResult.hh" #include "mem/protocol/Types.hh" #include "mem/ruby/common/Consumer.hh" #include "mem/ruby/common/Global.hh" #include "mem/ruby/slicc_interface/AbstractController.hh" #include "params/$c_ident.hh" ''') seen_types = set() for var in self.objects: if var.type.ident not in seen_types and not var.type.isPrimitive: code('#include "mem/protocol/${{var.type.c_ident}}.hh"') seen_types.add(var.type.ident) # for adding information to the protocol debug trace code(''' extern std::stringstream ${ident}_transitionComment; class $c_ident : public AbstractController { // the coherence checker needs to call isBlockExclusive() and isBlockShared() // making the Chip a friend class is an easy way to do this for now public: typedef ${c_ident}Params Params; $c_ident(const Params *p); static int getNumControllers(); void init(); MessageBuffer* getMandatoryQueue() const; const int & getVersion() const; const std::string toString() const; const std::string getName() const; const MachineType getMachineType() const; void stallBuffer(MessageBuffer* buf, Address addr); void wakeUpBuffers(Address addr); void wakeUpAllBuffers(); void initNetworkPtr(Network* net_ptr) { m_net_ptr = net_ptr; } void print(std::ostream& out) const; void printConfig(std::ostream& out) const; void wakeup(); void printStats(std::ostream& out) const; void clearStats(); void blockOnQueue(Address addr, MessageBuffer* port); void unblock(Address addr); private: ''') code.indent() # added by SS for param in self.config_parameters: if param.pointer: code('${{param.type_ast.type}}* m_${{param.ident}}_ptr;') else: code('${{param.type_ast.type}} m_${{param.ident}};') code(''' int m_number_of_TBEs; TransitionResult doTransition(${ident}_Event event, ''') if self.EntryType != None: code(''' ${{self.EntryType.c_ident}}* m_cache_entry_ptr, ''') if self.TBEType != None: code(''' ${{self.TBEType.c_ident}}* m_tbe_ptr, ''') code(''' const Address& addr); TransitionResult doTransitionWorker(${ident}_Event event, ${ident}_State state, ${ident}_State& next_state, ''') if self.TBEType != None: code(''' ${{self.TBEType.c_ident}}*& m_tbe_ptr, ''') if self.EntryType != None: code(''' ${{self.EntryType.c_ident}}*& m_cache_entry_ptr, ''') code(''' const Address& addr); std::string m_name; int m_transitions_per_cycle; int m_buffer_size; int m_recycle_latency; std::map m_cfg; NodeID m_version; Network* m_net_ptr; MachineID m_machineID; bool m_is_blocking; std::map m_block_map; typedef std::vector MsgVecType; typedef m5::hash_map< Address, MsgVecType* > WaitingBufType; WaitingBufType m_waiting_buffers; int m_max_in_port_rank; int m_cur_in_port_rank; static ${ident}_ProfileDumper s_profileDumper; ${ident}_Profiler m_profiler; static int m_num_controllers; // Internal functions ''') for func in self.functions: proto = func.prototype if proto: code('$proto') if self.EntryType != None: code(''' // Set and Reset for cache_entry variable void set_cache_entry(${{self.EntryType.c_ident}}*& m_cache_entry_ptr, AbstractCacheEntry* m_new_cache_entry); void unset_cache_entry(${{self.EntryType.c_ident}}*& m_cache_entry_ptr); ''') if self.TBEType != None: code(''' // Set and Reset for tbe variable void set_tbe(${{self.TBEType.c_ident}}*& m_tbe_ptr, ${ident}_TBE* m_new_tbe); void unset_tbe(${{self.TBEType.c_ident}}*& m_tbe_ptr); ''') code(''' // Actions ''') if self.TBEType != None and self.EntryType != None: for action in self.actions.itervalues(): code('/** \\brief ${{action.desc}} */') code('void ${{action.ident}}(${{self.TBEType.c_ident}}*& m_tbe_ptr, ${{self.EntryType.c_ident}}*& m_cache_entry_ptr, const Address& addr);') elif self.TBEType != None: for action in self.actions.itervalues(): code('/** \\brief ${{action.desc}} */') code('void ${{action.ident}}(${{self.TBEType.c_ident}}*& m_tbe_ptr, const Address& addr);') elif self.EntryType != None: for action in self.actions.itervalues(): code('/** \\brief ${{action.desc}} */') code('void ${{action.ident}}(${{self.EntryType.c_ident}}*& m_cache_entry_ptr, const Address& addr);') else: for action in self.actions.itervalues(): code('/** \\brief ${{action.desc}} */') code('void ${{action.ident}}(const Address& addr);') # the controller internal variables code(''' // Objects ''') for var in self.objects: th = var.get("template_hack", "") code('${{var.type.c_ident}}$th* m_${{var.c_ident}}_ptr;') if var.type.ident == "MessageBuffer": self.message_buffer_names.append("m_%s_ptr" % var.c_ident) code.dedent() code('};') code('#endif // __${ident}_CONTROLLER_H__') code.write(path, '%s.hh' % c_ident) def printControllerCC(self, path): '''Output the actions for performing the actions''' code = self.symtab.codeFormatter() ident = self.ident c_ident = "%s_Controller" % self.ident code(''' /** \\file $c_ident.cc * * Auto generated C++ code started by $__file__:$__line__ * Created by slicc definition of Module "${{self.short}}" */ #include #include #include #include "base/cprintf.hh" #include "debug/RubyGenerated.hh" #include "debug/RubySlicc.hh" #include "mem/protocol/${ident}_Controller.hh" #include "mem/protocol/${ident}_Event.hh" #include "mem/protocol/${ident}_State.hh" #include "mem/protocol/Types.hh" #include "mem/ruby/common/Global.hh" #include "mem/ruby/slicc_interface/RubySlicc_includes.hh" #include "mem/ruby/system/System.hh" using namespace std; ''') # include object classes seen_types = set() for var in self.objects: if var.type.ident not in seen_types and not var.type.isPrimitive: code('#include "mem/protocol/${{var.type.c_ident}}.hh"') seen_types.add(var.type.ident) code(''' $c_ident * ${c_ident}Params::create() { return new $c_ident(this); } int $c_ident::m_num_controllers = 0; ${ident}_ProfileDumper $c_ident::s_profileDumper; // for adding information to the protocol debug trace stringstream ${ident}_transitionComment; #define APPEND_TRANSITION_COMMENT(str) (${ident}_transitionComment << str) /** \\brief constructor */ $c_ident::$c_ident(const Params *p) : AbstractController(p) { m_version = p->version; m_transitions_per_cycle = p->transitions_per_cycle; m_buffer_size = p->buffer_size; m_recycle_latency = p->recycle_latency; m_number_of_TBEs = p->number_of_TBEs; m_is_blocking = false; ''') # # max_port_rank is used to size vectors and thus should be one plus the # largest port rank # max_port_rank = self.in_ports[0].pairs["max_port_rank"] + 1 code(' m_max_in_port_rank = $max_port_rank;') code.indent() # # After initializing the universal machine parameters, initialize the # this machines config parameters. Also detemine if these configuration # params include a sequencer. This information will be used later for # contecting the sequencer back to the L1 cache controller. # contains_dma_sequencer = False sequencers = [] for param in self.config_parameters: if param.name == "dma_sequencer": contains_dma_sequencer = True elif re.compile("sequencer").search(param.name): sequencers.append(param.name) if param.pointer: code('m_${{param.name}}_ptr = p->${{param.name}};') else: code('m_${{param.name}} = p->${{param.name}};') # # For the l1 cache controller, add the special atomic support which # includes passing the sequencer a pointer to the controller. # if self.ident == "L1Cache": if not sequencers: self.error("The L1Cache controller must include the sequencer " \ "configuration parameter") for seq in sequencers: code(''' m_${{seq}}_ptr->setController(this); ''') # # For the DMA controller, pass the sequencer a pointer to the # controller. # if self.ident == "DMA": if not contains_dma_sequencer: self.error("The DMA controller must include the sequencer " \ "configuration parameter") code(''' m_dma_sequencer_ptr->setController(this); ''') code('m_num_controllers++;') for var in self.objects: if var.ident.find("mandatoryQueue") >= 0: code('m_${{var.c_ident}}_ptr = new ${{var.type.c_ident}}();') code.dedent() code(''' } void $c_ident::init() { MachineType machine_type; int base; m_machineID.type = MachineType_${ident}; m_machineID.num = m_version; // initialize objects m_profiler.setVersion(m_version); s_profileDumper.registerProfiler(&m_profiler); ''') code.indent() for var in self.objects: vtype = var.type vid = "m_%s_ptr" % var.c_ident if "network" not in var: # Not a network port object if "primitive" in vtype: code('$vid = new ${{vtype.c_ident}};') if "default" in var: code('(*$vid) = ${{var["default"]}};') else: # Normal Object # added by SS if "factory" in var: code('$vid = ${{var["factory"]}};') elif var.ident.find("mandatoryQueue") < 0: th = var.get("template_hack", "") expr = "%s = new %s%s" % (vid, vtype.c_ident, th) args = "" if "non_obj" not in vtype and not vtype.isEnumeration: if expr.find("TBETable") >= 0: args = "m_number_of_TBEs" else: args = var.get("constructor_hack", "") code('$expr($args);') code('assert($vid != NULL);') if "default" in var: code('*$vid = ${{var["default"]}}; // Object default') elif "default" in vtype: comment = "Type %s default" % vtype.ident code('*$vid = ${{vtype["default"]}}; // $comment') # Set ordering if "ordered" in var and "trigger_queue" not in var: # A buffer code('$vid->setOrdering(${{var["ordered"]}});') # Set randomization if "random" in var: # A buffer code('$vid->setRandomization(${{var["random"]}});') # Set Priority if vtype.isBuffer and \ "rank" in var and "trigger_queue" not in var: code('$vid->setPriority(${{var["rank"]}});') else: # Network port object network = var["network"] ordered = var["ordered"] vnet = var["virtual_network"] vnet_type = var["vnet_type"] assert var.machine is not None code(''' machine_type = string_to_MachineType("${{var.machine.ident}}"); base = MachineType_base_number(machine_type); $vid = m_net_ptr->get${network}NetQueue(m_version + base, $ordered, $vnet, "$vnet_type"); ''') code('assert($vid != NULL);') # Set ordering if "ordered" in var: # A buffer code('$vid->setOrdering(${{var["ordered"]}});') # Set randomization if "random" in var: # A buffer code('$vid->setRandomization(${{var["random"]}});') # Set Priority if "rank" in var: code('$vid->setPriority(${{var["rank"]}})') # Set buffer size if vtype.isBuffer: code(''' if (m_buffer_size > 0) { $vid->resize(m_buffer_size); } ''') # set description (may be overriden later by port def) code(''' $vid->setDescription("[Version " + to_string(m_version) + ", ${ident}, name=${{var.c_ident}}]"); ''') if vtype.isBuffer: if "recycle_latency" in var: code('$vid->setRecycleLatency(${{var["recycle_latency"]}});') else: code('$vid->setRecycleLatency(m_recycle_latency);') # Set the queue consumers code() for port in self.in_ports: code('${{port.code}}.setConsumer(this);') # Set the queue descriptions code() for port in self.in_ports: code('${{port.code}}.setDescription("[Version " + to_string(m_version) + ", $ident, $port]");') # Initialize the transition profiling code() for trans in self.transitions: # Figure out if we stall stall = False for action in trans.actions: if action.ident == "z_stall": stall = True # Only possible if it is not a 'z' case if not stall: state = "%s_State_%s" % (self.ident, trans.state.ident) event = "%s_Event_%s" % (self.ident, trans.event.ident) code('m_profiler.possibleTransition($state, $event);') code.dedent() code('}') has_mandatory_q = False for port in self.in_ports: if port.code.find("mandatoryQueue_ptr") >= 0: has_mandatory_q = True if has_mandatory_q: mq_ident = "m_%s_mandatoryQueue_ptr" % self.ident else: mq_ident = "NULL" code(''' int $c_ident::getNumControllers() { return m_num_controllers; } MessageBuffer* $c_ident::getMandatoryQueue() const { return $mq_ident; } const int & $c_ident::getVersion() const { return m_version; } const string $c_ident::toString() const { return "$c_ident"; } const string $c_ident::getName() const { return m_name; } const MachineType $c_ident::getMachineType() const { return MachineType_${ident}; } void $c_ident::stallBuffer(MessageBuffer* buf, Address addr) { if (m_waiting_buffers.count(addr) == 0) { MsgVecType* msgVec = new MsgVecType; msgVec->resize(m_max_in_port_rank, NULL); m_waiting_buffers[addr] = msgVec; } (*(m_waiting_buffers[addr]))[m_cur_in_port_rank] = buf; } void $c_ident::wakeUpBuffers(Address addr) { if (m_waiting_buffers.count(addr) > 0) { // // Wake up all possible lower rank (i.e. lower priority) buffers that could // be waiting on this message. // for (int in_port_rank = m_cur_in_port_rank - 1; in_port_rank >= 0; in_port_rank--) { if ((*(m_waiting_buffers[addr]))[in_port_rank] != NULL) { (*(m_waiting_buffers[addr]))[in_port_rank]->reanalyzeMessages(addr); } } delete m_waiting_buffers[addr]; m_waiting_buffers.erase(addr); } } void $c_ident::wakeUpAllBuffers() { // // Wake up all possible buffers that could be waiting on any message. // std::vector wokeUpMsgVecs; if(m_waiting_buffers.size() > 0) { for (WaitingBufType::iterator buf_iter = m_waiting_buffers.begin(); buf_iter != m_waiting_buffers.end(); ++buf_iter) { for (MsgVecType::iterator vec_iter = buf_iter->second->begin(); vec_iter != buf_iter->second->end(); ++vec_iter) { if (*vec_iter != NULL) { (*vec_iter)->reanalyzeAllMessages(); } } wokeUpMsgVecs.push_back(buf_iter->second); } for (std::vector::iterator wb_iter = wokeUpMsgVecs.begin(); wb_iter != wokeUpMsgVecs.end(); ++wb_iter) { delete (*wb_iter); } m_waiting_buffers.clear(); } } void $c_ident::blockOnQueue(Address addr, MessageBuffer* port) { m_is_blocking = true; m_block_map[addr] = port; } void $c_ident::unblock(Address addr) { m_block_map.erase(addr); if (m_block_map.size() == 0) { m_is_blocking = false; } } void $c_ident::print(ostream& out) const { out << "[$c_ident " << m_version << "]"; } void $c_ident::printConfig(ostream& out) const { out << "$c_ident config: " << m_name << endl; out << " version: " << m_version << endl; map::const_iterator it; for (it = m_cfg.begin(); it != m_cfg.end(); it++) out << " " << it->first << ": " << it->second << endl; } void $c_ident::printStats(ostream& out) const { ''') # # Cache and Memory Controllers have specific profilers associated with # them. Print out these stats before dumping state transition stats. # for param in self.config_parameters: if param.type_ast.type.ident == "CacheMemory" or \ param.type_ast.type.ident == "DirectoryMemory" or \ param.type_ast.type.ident == "MemoryControl": assert(param.pointer) code(' m_${{param.ident}}_ptr->printStats(out);') code(''' if (m_version == 0) { s_profileDumper.dumpStats(out); } } void $c_ident::clearStats() { ''') # # Cache and Memory Controllers have specific profilers associated with # them. These stats must be cleared too. # for param in self.config_parameters: if param.type_ast.type.ident == "CacheMemory" or \ param.type_ast.type.ident == "MemoryControl": assert(param.pointer) code(' m_${{param.ident}}_ptr->clearStats();') code(''' m_profiler.clearStats(); } ''') if self.EntryType != None: code(''' // Set and Reset for cache_entry variable void $c_ident::set_cache_entry(${{self.EntryType.c_ident}}*& m_cache_entry_ptr, AbstractCacheEntry* m_new_cache_entry) { m_cache_entry_ptr = (${{self.EntryType.c_ident}}*)m_new_cache_entry; } void $c_ident::unset_cache_entry(${{self.EntryType.c_ident}}*& m_cache_entry_ptr) { m_cache_entry_ptr = 0; } ''') if self.TBEType != None: code(''' // Set and Reset for tbe variable void $c_ident::set_tbe(${{self.TBEType.c_ident}}*& m_tbe_ptr, ${{self.TBEType.c_ident}}* m_new_tbe) { m_tbe_ptr = m_new_tbe; } void $c_ident::unset_tbe(${{self.TBEType.c_ident}}*& m_tbe_ptr) { m_tbe_ptr = NULL; } ''') code(''' // Actions ''') if self.TBEType != None and self.EntryType != None: for action in self.actions.itervalues(): if "c_code" not in action: continue code(''' /** \\brief ${{action.desc}} */ void $c_ident::${{action.ident}}(${{self.TBEType.c_ident}}*& m_tbe_ptr, ${{self.EntryType.c_ident}}*& m_cache_entry_ptr, const Address& addr) { DPRINTF(RubyGenerated, "executing ${{action.ident}}\\n"); ${{action["c_code"]}} } ''') elif self.TBEType != None: for action in self.actions.itervalues(): if "c_code" not in action: continue code(''' /** \\brief ${{action.desc}} */ void $c_ident::${{action.ident}}(${{self.TBEType.c_ident}}*& m_tbe_ptr, const Address& addr) { DPRINTF(RubyGenerated, "executing ${{action.ident}}\\n"); ${{action["c_code"]}} } ''') elif self.EntryType != None: for action in self.actions.itervalues(): if "c_code" not in action: continue code(''' /** \\brief ${{action.desc}} */ void $c_ident::${{action.ident}}(${{self.EntryType.c_ident}}*& m_cache_entry_ptr, const Address& addr) { DPRINTF(RubyGenerated, "executing ${{action.ident}}\\n"); ${{action["c_code"]}} } ''') else: for action in self.actions.itervalues(): if "c_code" not in action: continue code(''' /** \\brief ${{action.desc}} */ void $c_ident::${{action.ident}}(const Address& addr) { DPRINTF(RubyGenerated, "executing ${{action.ident}}\\n"); ${{action["c_code"]}} } ''') for func in self.functions: code(func.generateCode()) code.write(path, "%s.cc" % c_ident) def printCWakeup(self, path): '''Output the wakeup loop for the events''' code = self.symtab.codeFormatter() ident = self.ident code(''' // Auto generated C++ code started by $__file__:$__line__ // ${ident}: ${{self.short}} #include #include "base/misc.hh" #include "debug/RubySlicc.hh" #include "mem/protocol/${ident}_Controller.hh" #include "mem/protocol/${ident}_Event.hh" #include "mem/protocol/${ident}_State.hh" #include "mem/protocol/Types.hh" #include "mem/ruby/common/Global.hh" #include "mem/ruby/slicc_interface/RubySlicc_includes.hh" #include "mem/ruby/system/System.hh" using namespace std; void ${ident}_Controller::wakeup() { int counter = 0; while (true) { // Some cases will put us into an infinite loop without this limit assert(counter <= m_transitions_per_cycle); if (counter == m_transitions_per_cycle) { // Count how often we are fully utilized g_system_ptr->getProfiler()->controllerBusy(m_machineID); // Wakeup in another cycle and try again g_eventQueue_ptr->scheduleEvent(this, 1); break; } ''') code.indent() code.indent() # InPorts # for port in self.in_ports: code.indent() code('// ${ident}InPort $port') if port.pairs.has_key("rank"): code('m_cur_in_port_rank = ${{port.pairs["rank"]}};') else: code('m_cur_in_port_rank = 0;') code('${{port["c_code_in_port"]}}') code.dedent() code('') code.dedent() code.dedent() code(''' break; // If we got this far, we have nothing left todo } // g_eventQueue_ptr->scheduleEvent(this, 1); } ''') code.write(path, "%s_Wakeup.cc" % self.ident) def printCSwitch(self, path): '''Output switch statement for transition table''' code = self.symtab.codeFormatter() ident = self.ident code(''' // Auto generated C++ code started by $__file__:$__line__ // ${ident}: ${{self.short}} #include #include "base/misc.hh" #include "base/trace.hh" #include "debug/ProtocolTrace.hh" #include "debug/RubyGenerated.hh" #include "mem/protocol/${ident}_Controller.hh" #include "mem/protocol/${ident}_Event.hh" #include "mem/protocol/${ident}_State.hh" #include "mem/protocol/Types.hh" #include "mem/ruby/common/Global.hh" #include "mem/ruby/system/System.hh" #define HASH_FUN(state, event) ((int(state)*${ident}_Event_NUM)+int(event)) #define GET_TRANSITION_COMMENT() (${ident}_transitionComment.str()) #define CLEAR_TRANSITION_COMMENT() (${ident}_transitionComment.str("")) TransitionResult ${ident}_Controller::doTransition(${ident}_Event event, ''') if self.EntryType != None: code(''' ${{self.EntryType.c_ident}}* m_cache_entry_ptr, ''') if self.TBEType != None: code(''' ${{self.TBEType.c_ident}}* m_tbe_ptr, ''') code(''' const Address &addr) { ''') if self.TBEType != None and self.EntryType != None: code('${ident}_State state = getState(m_tbe_ptr, m_cache_entry_ptr, addr);') elif self.TBEType != None: code('${ident}_State state = getState(m_tbe_ptr, addr);') elif self.EntryType != None: code('${ident}_State state = getState(m_cache_entry_ptr, addr);') else: code('${ident}_State state = getState(addr);') code(''' ${ident}_State next_state = state; DPRINTF(RubyGenerated, "%s, Time: %lld, state: %s, event: %s, addr: %s\\n", *this, g_eventQueue_ptr->getTime(), ${ident}_State_to_string(state), ${ident}_Event_to_string(event), addr); TransitionResult result = ''') if self.TBEType != None and self.EntryType != None: code('doTransitionWorker(event, state, next_state, m_tbe_ptr, m_cache_entry_ptr, addr);') elif self.TBEType != None: code('doTransitionWorker(event, state, next_state, m_tbe_ptr, addr);') elif self.EntryType != None: code('doTransitionWorker(event, state, next_state, m_cache_entry_ptr, addr);') else: code('doTransitionWorker(event, state, next_state, addr);') code(''' if (result == TransitionResult_Valid) { DPRINTF(RubyGenerated, "next_state: %s\\n", ${ident}_State_to_string(next_state)); m_profiler.countTransition(state, event); DPRINTFR(ProtocolTrace, "%15d %3s %10s%20s %6s>%-6s %s %s\\n", curTick(), m_version, "${ident}", ${ident}_Event_to_string(event), ${ident}_State_to_string(state), ${ident}_State_to_string(next_state), addr, GET_TRANSITION_COMMENT()); CLEAR_TRANSITION_COMMENT(); ''') if self.TBEType != None and self.EntryType != None: code('setState(m_tbe_ptr, m_cache_entry_ptr, addr, next_state);') code('setAccessPermission(m_cache_entry_ptr, addr, next_state);') elif self.TBEType != None: code('setState(m_tbe_ptr, addr, next_state);') code('setAccessPermission(addr, next_state);') elif self.EntryType != None: code('setState(m_cache_entry_ptr, addr, next_state);') code('setAccessPermission(m_cache_entry_ptr, addr, next_state);') else: code('setState(addr, next_state);') code('setAccessPermission(addr, next_state);') code(''' } else if (result == TransitionResult_ResourceStall) { DPRINTFR(ProtocolTrace, "%15s %3s %10s%20s %6s>%-6s %s %s\\n", curTick(), m_version, "${ident}", ${ident}_Event_to_string(event), ${ident}_State_to_string(state), ${ident}_State_to_string(next_state), addr, "Resource Stall"); } else if (result == TransitionResult_ProtocolStall) { DPRINTF(RubyGenerated, "stalling\\n"); DPRINTFR(ProtocolTrace, "%15s %3s %10s%20s %6s>%-6s %s %s\\n", curTick(), m_version, "${ident}", ${ident}_Event_to_string(event), ${ident}_State_to_string(state), ${ident}_State_to_string(next_state), addr, "Protocol Stall"); } return result; } TransitionResult ${ident}_Controller::doTransitionWorker(${ident}_Event event, ${ident}_State state, ${ident}_State& next_state, ''') if self.TBEType != None: code(''' ${{self.TBEType.c_ident}}*& m_tbe_ptr, ''') if self.EntryType != None: code(''' ${{self.EntryType.c_ident}}*& m_cache_entry_ptr, ''') code(''' const Address& addr) { switch(HASH_FUN(state, event)) { ''') # This map will allow suppress generating duplicate code cases = orderdict() for trans in self.transitions: case_string = "%s_State_%s, %s_Event_%s" % \ (self.ident, trans.state.ident, self.ident, trans.event.ident) case = self.symtab.codeFormatter() # Only set next_state if it changes if trans.state != trans.nextState: ns_ident = trans.nextState.ident case('next_state = ${ident}_State_${ns_ident};') actions = trans.actions # Check for resources case_sorter = [] res = trans.resources for key,val in res.iteritems(): if key.type.ident != "DNUCAStopTable": val = ''' if (!%s.areNSlotsAvailable(%s)) return TransitionResult_ResourceStall; ''' % (key.code, val) case_sorter.append(val) # Emit the code sequences in a sorted order. This makes the # output deterministic (without this the output order can vary # since Map's keys() on a vector of pointers is not deterministic for c in sorted(case_sorter): case("$c") # Figure out if we stall stall = False for action in actions: if action.ident == "z_stall": stall = True break if stall: case('return TransitionResult_ProtocolStall;') else: if self.TBEType != None and self.EntryType != None: for action in actions: case('${{action.ident}}(m_tbe_ptr, m_cache_entry_ptr, addr);') elif self.TBEType != None: for action in actions: case('${{action.ident}}(m_tbe_ptr, addr);') elif self.EntryType != None: for action in actions: case('${{action.ident}}(m_cache_entry_ptr, addr);') else: for action in actions: case('${{action.ident}}(addr);') case('return TransitionResult_Valid;') case = str(case) # Look to see if this transition code is unique. if case not in cases: cases[case] = [] cases[case].append(case_string) # Walk through all of the unique code blocks and spit out the # corresponding case statement elements for case,transitions in cases.iteritems(): # Iterative over all the multiple transitions that share # the same code for trans in transitions: code(' case HASH_FUN($trans):') code(' $case') code(''' default: fatal("Invalid transition\\n" "%s time: %d addr: %s event: %s state: %s\\n", name(), g_eventQueue_ptr->getTime(), addr, event, state); } return TransitionResult_Valid; } ''') code.write(path, "%s_Transitions.cc" % self.ident) def printProfileDumperHH(self, path): code = self.symtab.codeFormatter() ident = self.ident code(''' // Auto generated C++ code started by $__file__:$__line__ // ${ident}: ${{self.short}} #ifndef __${ident}_PROFILE_DUMPER_HH__ #define __${ident}_PROFILE_DUMPER_HH__ #include #include #include #include "${ident}_Event.hh" #include "${ident}_Profiler.hh" typedef std::vector<${ident}_Profiler *> ${ident}_profilers; class ${ident}_ProfileDumper { public: ${ident}_ProfileDumper(); void registerProfiler(${ident}_Profiler* profiler); void dumpStats(std::ostream& out) const; private: ${ident}_profilers m_profilers; }; #endif // __${ident}_PROFILE_DUMPER_HH__ ''') code.write(path, "%s_ProfileDumper.hh" % self.ident) def printProfileDumperCC(self, path): code = self.symtab.codeFormatter() ident = self.ident code(''' // Auto generated C++ code started by $__file__:$__line__ // ${ident}: ${{self.short}} #include "mem/protocol/${ident}_ProfileDumper.hh" ${ident}_ProfileDumper::${ident}_ProfileDumper() { } void ${ident}_ProfileDumper::registerProfiler(${ident}_Profiler* profiler) { m_profilers.push_back(profiler); } void ${ident}_ProfileDumper::dumpStats(std::ostream& out) const { out << " --- ${ident} ---\\n"; out << " - Event Counts -\\n"; for (${ident}_Event event = ${ident}_Event_FIRST; event < ${ident}_Event_NUM; ++event) { out << (${ident}_Event) event << " ["; uint64 total = 0; for (int i = 0; i < m_profilers.size(); i++) { out << m_profilers[i]->getEventCount(event) << " "; total += m_profilers[i]->getEventCount(event); } out << "] " << total << "\\n"; } out << "\\n"; out << " - Transitions -\\n"; for (${ident}_State state = ${ident}_State_FIRST; state < ${ident}_State_NUM; ++state) { for (${ident}_Event event = ${ident}_Event_FIRST; event < ${ident}_Event_NUM; ++event) { if (m_profilers[0]->isPossible(state, event)) { out << (${ident}_State) state << " " << (${ident}_Event) event << " ["; uint64 total = 0; for (int i = 0; i < m_profilers.size(); i++) { out << m_profilers[i]->getTransitionCount(state, event) << " "; total += m_profilers[i]->getTransitionCount(state, event); } out << "] " << total << "\\n"; } } out << "\\n"; } } ''') code.write(path, "%s_ProfileDumper.cc" % self.ident) def printProfilerHH(self, path): code = self.symtab.codeFormatter() ident = self.ident code(''' // Auto generated C++ code started by $__file__:$__line__ // ${ident}: ${{self.short}} #ifndef __${ident}_PROFILER_HH__ #define __${ident}_PROFILER_HH__ #include #include #include "mem/protocol/${ident}_Event.hh" #include "mem/protocol/${ident}_State.hh" #include "mem/ruby/common/Global.hh" class ${ident}_Profiler { public: ${ident}_Profiler(); void setVersion(int version); void countTransition(${ident}_State state, ${ident}_Event event); void possibleTransition(${ident}_State state, ${ident}_Event event); uint64 getEventCount(${ident}_Event event); bool isPossible(${ident}_State state, ${ident}_Event event); uint64 getTransitionCount(${ident}_State state, ${ident}_Event event); void clearStats(); private: int m_counters[${ident}_State_NUM][${ident}_Event_NUM]; int m_event_counters[${ident}_Event_NUM]; bool m_possible[${ident}_State_NUM][${ident}_Event_NUM]; int m_version; }; #endif // __${ident}_PROFILER_HH__ ''') code.write(path, "%s_Profiler.hh" % self.ident) def printProfilerCC(self, path): code = self.symtab.codeFormatter() ident = self.ident code(''' // Auto generated C++ code started by $__file__:$__line__ // ${ident}: ${{self.short}} #include #include "mem/protocol/${ident}_Profiler.hh" ${ident}_Profiler::${ident}_Profiler() { for (int state = 0; state < ${ident}_State_NUM; state++) { for (int event = 0; event < ${ident}_Event_NUM; event++) { m_possible[state][event] = false; m_counters[state][event] = 0; } } for (int event = 0; event < ${ident}_Event_NUM; event++) { m_event_counters[event] = 0; } } void ${ident}_Profiler::setVersion(int version) { m_version = version; } void ${ident}_Profiler::clearStats() { for (int state = 0; state < ${ident}_State_NUM; state++) { for (int event = 0; event < ${ident}_Event_NUM; event++) { m_counters[state][event] = 0; } } for (int event = 0; event < ${ident}_Event_NUM; event++) { m_event_counters[event] = 0; } } void ${ident}_Profiler::countTransition(${ident}_State state, ${ident}_Event event) { assert(m_possible[state][event]); m_counters[state][event]++; m_event_counters[event]++; } void ${ident}_Profiler::possibleTransition(${ident}_State state, ${ident}_Event event) { m_possible[state][event] = true; } uint64 ${ident}_Profiler::getEventCount(${ident}_Event event) { return m_event_counters[event]; } bool ${ident}_Profiler::isPossible(${ident}_State state, ${ident}_Event event) { return m_possible[state][event]; } uint64 ${ident}_Profiler::getTransitionCount(${ident}_State state, ${ident}_Event event) { return m_counters[state][event]; } ''') code.write(path, "%s_Profiler.cc" % self.ident) # ************************** # ******* HTML Files ******* # ************************** def frameRef(self, click_href, click_target, over_href, over_num, text): code = self.symtab.codeFormatter(fix_newlines=False) code(""" ${{html.formatShorthand(text)}} """) return str(code) def writeHTMLFiles(self, path): # Create table with no row hilighted self.printHTMLTransitions(path, None) # Generate transition tables for state in self.states.itervalues(): self.printHTMLTransitions(path, state) # Generate action descriptions for action in self.actions.itervalues(): name = "%s_action_%s.html" % (self.ident, action.ident) code = html.createSymbol(action, "Action") code.write(path, name) # Generate state descriptions for state in self.states.itervalues(): name = "%s_State_%s.html" % (self.ident, state.ident) code = html.createSymbol(state, "State") code.write(path, name) # Generate event descriptions for event in self.events.itervalues(): name = "%s_Event_%s.html" % (self.ident, event.ident) code = html.createSymbol(event, "Event") code.write(path, name) def printHTMLTransitions(self, path, active_state): code = self.symtab.codeFormatter() code('''

${{html.formatShorthand(self.short)}}: ''') code.indent() for i,machine in enumerate(self.symtab.getAllType(StateMachine)): mid = machine.ident if i != 0: extra = " - " else: extra = "" if machine == self: code('$extra$mid') else: code('$extra$mid') code.dedent() code("""

""") for event in self.events.itervalues(): href = "%s_Event_%s.html" % (self.ident, event.ident) ref = self.frameRef(href, "Status", href, "1", event.short) code('') code('') # -- Body of table for state in self.states.itervalues(): # -- Each row if state == active_state: color = "yellow" else: color = "white" click = "%s_table_%s.html" % (self.ident, state.ident) over = "%s_State_%s.html" % (self.ident, state.ident) text = html.formatShorthand(state.short) ref = self.frameRef(click, "Table", over, "1", state.short) code(''' ''') # -- One column for each event for event in self.events.itervalues(): trans = self.table.get((state,event), None) if trans is None: # This is the no transition case if state == active_state: color = "#C0C000" else: color = "lightgrey" code('') continue next = trans.nextState stall_action = False # -- Get the actions for action in trans.actions: if action.ident == "z_stall" or \ action.ident == "zz_recycleMandatoryQueue": stall_action = True # -- Print out "actions/next-state" if stall_action: if state == active_state: color = "#C0C000" else: color = "lightgrey" elif active_state and next.ident == active_state.ident: color = "aqua" elif state == active_state: color = "yellow" else: color = "white" code('") # -- Each row if state == active_state: color = "yellow" else: color = "white" click = "%s_table_%s.html" % (self.ident, state.ident) over = "%s_State_%s.html" % (self.ident, state.ident) ref = self.frameRef(click, "Table", over, "1", state.short) code(''' ''') code(''' ''') for event in self.events.itervalues(): href = "%s_Event_%s.html" % (self.ident, event.ident) ref = self.frameRef(href, "Status", href, "1", event.short) code('') code('''
$ref
$ref ') for action in trans.actions: href = "%s_action_%s.html" % (self.ident, action.ident) ref = self.frameRef(href, "Status", href, "1", action.short) code(' $ref') if next != state: if trans.actions: code('/') click = "%s_table_%s.html" % (self.ident, next.ident) over = "%s_State_%s.html" % (self.ident, next.ident) ref = self.frameRef(click, "Table", over, "1", next.short) code("$ref") code("$ref
$ref
''') if active_state: name = "%s_table_%s.html" % (self.ident, active_state.ident) else: name = "%s_table.html" % self.ident code.write(path, name) __all__ = [ "StateMachine" ]