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/* Asynchronous SDM NoC (C)2011 Wei Song Advanced Processor Technologies Group Computer Science, the Univ. of Manchester, UK Authors: Wei Song wsong83@gmail.com License: LGPL 3.0 or later The SystemC module of network node including the processing element and the network interface. Currently the transmission FIFO is 500 frame deep. History: 26/02/2011 Initial version. <wsong83@gmail.com> 30/05/2011 Clean up for opensource. <wsong83@gmail.com> */ #ifndef NETNODE_H_ #define NETNODE_H_ #include "define.h" #include <systemc.h> #include "ni.h" #include "procelem.h" #include "rtdriver.h" class NetNode : public sc_module { public: RTDriver * LIOD [SubChN]; /* driving and convert I/O to/from router local port */ Network_Adapter * NI; /* network interface */ ProcElem * PE; /* processor element */ #ifdef ENABLE_CHANNEL_CLISING sc_signal<sc_lv<ChBW*4> > rtia [SubChN]; /* input ack to router */ sc_signal<sc_lv<ChBW*4> > rtod4 [SubChN]; /* output eof to router */ sc_signal<sc_lv<ChBW*4> > rtoa [SubChN]; /* output ack from router */ sc_signal<sc_lv<ChBW*4> > rtid4 [SubChN]; /* input data from router */ sc_in<sc_lv<SubChN*ChBW*4> > dia; /* input ack, undivided */ sc_in<sc_lv<SubChN*ChBW*4> > do4; /* output eof, undivided */ sc_out<sc_lv<SubChN*ChBW*4> > doa; /* output ack, undivided */ sc_out<sc_lv<SubChN*ChBW*4> > di4; /* input eof, undivided */ #else sc_signal<sc_logic > rtia [SubChN]; /* input ack to router */ sc_signal<sc_logic > rtod4 [SubChN]; /* output data to router */ sc_signal<sc_logic > rtoa [SubChN]; /* output ack from router */ sc_signal<sc_logic > rtid4 [SubChN]; /* input eof from router */ sc_in<sc_lv<SubChN> > dia; /* input ack, undivided */ sc_in<sc_lv<SubChN> > do4; /* output eof, undivided */ sc_out<sc_lv<SubChN> > doa; /* output ack, undivided */ sc_out<sc_lv<SubChN> > di4; /* input eof, undivided */ #endif sc_signal<sc_lv<ChBW*4 > > rtod [SubChN][4]; /* output data to router */ sc_signal<sc_lv<ChBW*4 > > rtid [SubChN][4]; /* input data from router */ sc_in<sc_lv<SubChN*ChBW*4 > > do0; /* output d0, undivided */ sc_in<sc_lv<SubChN*ChBW*4 > > do1; sc_in<sc_lv<SubChN*ChBW*4 > > do2; sc_in<sc_lv<SubChN*ChBW*4 > > do3; sc_out<sc_lv<SubChN*ChBW*4 > > di0; /* input data, undivided */ sc_out<sc_lv<SubChN*ChBW*4 > > di1; sc_out<sc_lv<SubChN*ChBW*4 > > di2; sc_out<sc_lv<SubChN*ChBW*4 > > di3; sc_in<sc_logic > rst_n; /* global reste, from the verilog top level */ // signals between IOD and NI sc_fifo<pdu_flit<ChBW> > * NI2P [SubChN]; /* flit fifo, from NI to IO driver */ sc_fifo<pdu_flit<ChBW> > * P2NI [SubChN]; /* flit fifo, from IO driver to NI */ // signals between NI and FG/FS sc_fifo<pdu_frame<ChBW> > * FIQ; /* the frame fifo, from PE to NI */ sc_fifo<pdu_frame<ChBW> > * FOQ; /* the frame fifo, from NI to PE */ sc_signal<bool> brst_n; /* the reset in the SystemC modules */ int x, y; /* private local address */ SC_CTOR(NetNode) : dia("dia"), do4("do4"), doa("doa"), di4("di4"), do0("do0"), do1("do1"), do2("do2"), do3("do3"), di0("di0"), di1("di1"), di2("di2"), di3("di3"), rst_n("rst_n") { // dynamically get the parameters from Verilog test bench ncsc_get_param("x", x); ncsc_get_param("y", y); // initialization NI = new Network_Adapter("NI", x, y); PE = new ProcElem("PE", x, y); FIQ = new sc_fifo<pdu_frame<ChBW> >(500); /* currently the fifo from PE is 500 frame deep */ FOQ = new sc_fifo<pdu_frame<ChBW> >(1); for(unsigned int j=0; j<SubChN; j++) { LIOD[j] = new RTDriver("LIOD"); NI2P[j] = new sc_fifo<pdu_flit<ChBW> >(1); P2NI[j] = new sc_fifo<pdu_flit<ChBW> >(1); } // connections for(unsigned int j=0; j<SubChN; j++) { LIOD[j]->NI2P(*NI2P[j]); LIOD[j]->P2NI(*P2NI[j]); for(unsigned int k=0; k<4; k++) { LIOD[j]->rtid[k](rtid[j][k]); LIOD[j]->rtod[k](rtod[j][k]); } LIOD[j]->rtia(rtia[j]); LIOD[j]->rtid4(rtid4[j]); LIOD[j]->rtoa(rtoa[j]); LIOD[j]->rtod4(rtod4[j]); } NI->frame_in(*FIQ); NI->frame_out(*FOQ); for(unsigned int j=0; j<SubChN; j++) { NI->IP[j](*P2NI[j]); NI->OP[j](*NI2P[j]); } PE->rst_n(brst_n); PE->Fout(*FIQ); PE->Fin(*FOQ); brst_n.write(false); SC_METHOD(rst_proc); sensitive << rst_n; sc_spawn_options opt_inp; opt_inp.spawn_method(); for(unsigned int j=0; j<SubChN; j++) { opt_inp.set_sensitivity(&rtid[j][0]); opt_inp.set_sensitivity(&rtid[j][1]); opt_inp.set_sensitivity(&rtid[j][2]); opt_inp.set_sensitivity(&rtid[j][3]); opt_inp.set_sensitivity(&rtid4[j]); } opt_inp.set_sensitivity(&dia); sc_spawn(sc_bind(&NetNode::VC_inp, this), NULL, &opt_inp); sc_spawn_options opt_outp; opt_outp.spawn_method(); for(unsigned int j=0; j<SubChN; j++) { opt_outp.set_sensitivity(&rtoa[j]); } opt_outp.set_sensitivity(&do0); opt_outp.set_sensitivity(&do1); opt_outp.set_sensitivity(&do2); opt_outp.set_sensitivity(&do3); opt_outp.set_sensitivity(&do4); sc_spawn(sc_bind(&NetNode::VC_outp, this), NULL, &opt_outp); } // thread to divide the input buses according to virtual circuits void VC_inp() { sc_lv<SubChN*ChBW*4> md[4]; #ifdef ENABLE_CHANNEL_CLISING sc_lv<SubChN*ChBW*4> md4; sc_lv<SubChN*ChBW*4> mda; #else sc_lv<SubChN> md4; sc_lv<SubChN> mda; #endif mda = dia.read(); for(unsigned int i=0; i<SubChN; i++) { #ifdef ENABLE_CHANNEL_CLISING rtia[i].write(mda(ChBW*4*(i+1)-1, ChBW*4*i)); md4(ChBW*4*(i+1)-1, ChBW*4*i) = rtid4[i].read(); #else rtia[i].write(mda[i]); md4[i] = rtid4[i].read(); #endif md[0](ChBW*4*(i+1)-1, ChBW*4*i) = rtid[i][0].read(); md[1](ChBW*4*(i+1)-1, ChBW*4*i) = rtid[i][1].read(); md[2](ChBW*4*(i+1)-1, ChBW*4*i) = rtid[i][2].read(); md[3](ChBW*4*(i+1)-1, ChBW*4*i) = rtid[i][3].read(); } di0.write(md[0]); di1.write(md[1]); di2.write(md[2]); di3.write(md[3]); di4.write(md4); } // thread to combine the buses according to virtual circuits void VC_outp() { sc_lv<SubChN*ChBW*4> md[4]; #ifdef ENABLE_CHANNEL_CLISING sc_lv<SubChN*ChBW*4> md4; sc_lv<SubChN*ChBW*4> mda; #else sc_lv<SubChN> md4; sc_lv<SubChN> mda; #endif md[0] = do0.read(); md[1] = do1.read(); md[2] = do2.read(); md[3] = do3.read(); md4 = do4.read(); for(unsigned int i=0; i<SubChN; i++) { #ifdef ENABLE_CHANNEL_CLISING mda(ChBW*4*(i+1)-1, ChBW*4*i) = rtoa[i].read(); rtod4[i].write(md4(ChBW*4*(i+1)-1, ChBW*4*i)); #else mda[i] = rtoa[i].read(); rtod4[i].write(md4[i]); #endif rtod[i][0].write(md[0](ChBW*4*(i+1)-1, ChBW*4*i)); rtod[i][1].write(md[1](ChBW*4*(i+1)-1, ChBW*4*i)); rtod[i][2].write(md[2](ChBW*4*(i+1)-1, ChBW*4*i)); rtod[i][3].write(md[3](ChBW*4*(i+1)-1, ChBW*4*i)); } doa.write(mda); } // generate the reset for SystemC modules void rst_proc() { bool mrst_n; mrst_n = rst_n.read().is_01() ? rst_n.read().to_bool() : false; brst_n.write(mrst_n); } }; #endif
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