static void napi_disable_rx(struct net_device *dev) { struct fs_enet_private *fep = netdev_priv(dev); fcc_t __iomem *fccp = fep->fcc.fccp; C16(fccp, fcc_fccm, FCC_NAPI_RX_EVENT_MSK); }
static void set_multicast_finish(struct net_device *dev) { struct fs_enet_private *fep = netdev_priv(dev); scc_t __iomem *sccp = fep->scc.sccp; scc_enet_t __iomem *ep = fep->scc.ep; /* clear promiscuous always */ C16(sccp, scc_psmr, SCC_PSMR_PRO); /* if all multi or too many multicasts; just enable all */ if ((dev->flags & IFF_ALLMULTI) != 0 || dev->mc_count > SCC_MAX_MULTICAST_ADDRS) { W16(ep, sen_gaddr1, 0xffff); W16(ep, sen_gaddr2, 0xffff); W16(ep, sen_gaddr3, 0xffff); W16(ep, sen_gaddr4, 0xffff); } }
void sirius_v500(std::vector<Element>& the_ring) { int harmonic_number = 864; //double energy = 3e9; // AC10_5 double qaf_strength = 2.536876; double qad_strength = -2.730416; double qbd2_strength = -3.961194; double qbf_strength = 3.902838; double qbd1_strength = -2.966239; double qf1_strength = 2.367821; double qf2_strength = 3.354286; double qf3_strength = 3.080632; double qf4_strength = 2.707639; double sa1_strength = -115.7829759411277/2; double sa2_strength = 49.50386128829739/2; double sb1_strength = -214.5386552515188/2; double sb2_strength = 133.1252391065637/2; double sd1_strength = -302.6188062085843/2; double sf1_strength = 369.5045185071228/2; double sd2_strength = -164.3042864671946/2; double sd3_strength = -289.9270429064217/2; double sf2_strength = 333.7039740852999/2; //""" --- drift spaces --- """ double id_length = 2.0; // [m] Element dia1 = Element::drift("dia", id_length/2); Element dia2 = Element::drift("dia", 3.26920 + 3.65e-3 - id_length/2); Element dib1 = Element::drift("dib", id_length/2); Element dib2 = Element::drift("dib", 2.909200 + 3.65e-3 - id_length/2); Element d10 = Element::drift("d10", 0.100000); Element d11 = Element::drift("d11", 0.110000); Element d12 = Element::drift("d12", 0.120000); Element d13 = Element::drift("d13", 0.130000); Element d15 = Element::drift("d15", 0.150000); Element d17 = Element::drift("d17", 0.170000); Element d18 = Element::drift("d18", 0.180000); Element d20 = Element::drift("d20", 0.200000); Element d22 = Element::drift("d22", 0.220000); Element d23 = Element::drift("d23", 0.230000); Element d26 = Element::drift("d26", 0.260000); Element d32 = Element::drift("d32", 0.320000); Element d44 = Element::drift("d44", 0.440000); //""" --- markers --- """ Element mc = Element::marker("mc"); Element mia = Element::marker("mia"); Element mib = Element::marker("mib"); Element mb1 = Element::marker("mb1"); Element mb2 = Element::marker("mb2"); Element mb3 = Element::marker("mb3"); Element inicio = Element::marker("inicio"); Element fim = Element::marker("fim"); Element mida = Element::marker("id_enda"); Element midb = Element::marker("id_endb"); //""" --- beam position monitors --- """ Element mon = Element::marker("BPM"); //""" --- quadrupoles --- """ Element qaf = Element::quadrupole("qaf", 0.340000, qaf_strength); Element qad = Element::quadrupole("qad", 0.140000, qad_strength); Element qbd2 = Element::quadrupole("qbd2", 0.140000, qbd2_strength); Element qbf = Element::quadrupole("qbf", 0.340000, qbf_strength); Element qbd1 = Element::quadrupole("qbd1", 0.140000, qbd1_strength); Element qf1 = Element::quadrupole("qf1", 0.250000, qf1_strength); Element qf2 = Element::quadrupole("qf2", 0.250000, qf2_strength); Element qf3 = Element::quadrupole("qf3", 0.250000, qf3_strength); Element qf4 = Element::quadrupole("qf4", 0.250000, qf4_strength); //""" --- bending magnets --- """ double deg_2_rad = (M_PI/180.0); std::string dip_nam; double dip_len, dip_ang, dip_K, dip_S; Element h1, h2; //""" -- b1 -- """ dip_nam = "b1"; dip_len = 0.828080; dip_ang = 2.766540 * deg_2_rad; dip_K = -0.78; dip_S = 0; h1 = Element::rbend(dip_nam, dip_len/2, dip_ang/2, 1*dip_ang/2, 0*dip_ang/2, dip_K, dip_S); h2 = Element::rbend(dip_nam, dip_len/2, dip_ang/2, 0*dip_ang/2, 1*dip_ang/2, dip_K, dip_S); std::vector<Element> B1 = {h1, mb1, h2}; //""" -- b2 -- """ dip_nam = "b2"; dip_len = 1.228262; dip_ang = 4.103510 * deg_2_rad; dip_K = -0.78; dip_S = 0.00; h1 = Element::rbend(dip_nam, dip_len/2, dip_ang/2, 1*dip_ang/2, 0*dip_ang/2, dip_K, dip_S); h2 = Element::rbend(dip_nam, dip_len/2, dip_ang/2, 0*dip_ang/2, 1*dip_ang/2, dip_K, dip_S); std::vector<Element> B2 = {h1, mb2, h2}; //""" -- b3 -- """ dip_nam = "b3"; dip_len = 0.428011; dip_ang = 1.429950 * deg_2_rad; dip_K = -0.78; dip_S = 0.00; h1 = Element::rbend(dip_nam, dip_len/2, dip_ang/2, 1*dip_ang/2, 0*dip_ang/2, dip_K, dip_S); h2 = Element::rbend(dip_nam, dip_len/2, dip_ang/2, 0*dip_ang/2, 1*dip_ang/2, dip_K, dip_S); std::vector<Element> B3 = {h1, mb3, h2}; //""" -- bc -- """ dip_nam = "bc"; dip_len = 0.125394; dip_ang = 1.4 * deg_2_rad; dip_K = 0.00; dip_S = -18.93; Element bce = Element::rbend(dip_nam, dip_len/2, dip_ang/2, 1*dip_ang/2, 0*dip_ang/2, dip_K, dip_S); Element bcs = Element::rbend(dip_nam, dip_len/2, dip_ang/2, 0*dip_ang/2, 1*dip_ang/2, dip_K, dip_S); std::vector<Element> BC = {bce, mc, bcs}; //""" --- correctors --- """ Element ch = Element::hcorrector("hcm", 0, 0); Element cv = Element::vcorrector("vcm", 0, 0); Element crhv = Element::corrector ("crhv", 0, 0, 0); //""" --- sextupoles --- """ Element sa1 = Element::sextupole("sa1", 0.150000, sa1_strength); Element sa2 = Element::sextupole("sa2", 0.150000, sa2_strength); Element sb1 = Element::sextupole("sb1", 0.150000, sb1_strength); Element sb2 = Element::sextupole("sb2", 0.150000, sb2_strength); Element sd1 = Element::sextupole("sd1", 0.150000, sd1_strength); Element sf1 = Element::sextupole("sf1", 0.150000, sf1_strength); Element sd2 = Element::sextupole("sd2", 0.150000, sd2_strength); Element sd3 = Element::sextupole("sd3", 0.150000, sd3_strength); Element sf2 = Element::sextupole("sf2", 0.150000, sf2_strength); //""" --- rf cavity --- """ Element cav = Element::rfcavity("cav", 0, 500e6, 2.5e6); //""" lines """ std::vector<Element> insa = { dia1, mida, dia2, crhv, cv, d12, ch, d12, sa2, d12, mon, d12, qaf, d23, qad, d17, sa1, d17}; std::vector<Element> insb = { dib1, midb, dib2, d10, crhv, qbd2, d12, cv, d12, ch, d12, sb2, d12, mon, d12, qbf, d23, qbd1, d17, sb1, d17}; std::vector<Element> cline1 = { d32, cv, d12, ch, d15, sd1, d17, qf1, d12, mon, d11, sf1, d20, qf2, d17, sd2, d12, ch, d10, mon, d10}; std::vector<Element> cline2 = { d18, cv, d26, sd3, d17, qf3, d12, mon, d11, sf2, d20, qf4, d15, ch, crhv, d12, mon, d44}; std::vector<Element> cline3 = { d44, mon, d12, ch, d15, qf4, d20, sf2, d11, mon, d12, qf3, d17, sd3, d26, cv, crhv, d18}; std::vector<Element> cline4 = { d20, ch, d12, sd2, d17, qf2, d20, sf1, d11, mon, d12, qf1, d17, sd1, d15, ch, d12, cv, d22, mon, d10}; //""" Injection Section """ Element dmiainj = Element::drift("dmiainj", 0.3); Element dinjk3 = Element::drift("dinjk3" , 0.3); Element dk3k4 = Element::drift("dk3k4" , 0.6); Element dk4pmm = Element::drift("dk4pmm" , 0.2); Element dpmmcv = Element::drift("dpmmcv" , (3.2692 + 3.65e-3 - 0.3 - 0.3 - 0.6 - 0.2 - 3*0.6)); Element dcvk1 = Element::drift("dcvk1" , (3.2692 + 3.65e-3 - 0.6 - 1.4 - 2*0.6)); Element dk1k2 = Element::drift("dk1k2" , 0.6); Element sef = Element::sextupole("sef", 0.6, 0.0, 5); Element dk2sef = Element::drift("dk2mia" , 0.8); Element kick = Element::corrector("kick", 0.6, 0, 0); Element pmm = Element::sextupole("pmm", 0.6, 0.0, 5); Element inj = Element::marker("inj"); std::vector<Element> insaend = {cv, d12, ch, d12, sa2, d12, mon, d12, qaf, d23, qad, d17, sa1, d17}; std::vector<Element> insainj = latt_join({{dmiainj, inj, dinjk3, kick, dk3k4, kick, dk4pmm, pmm, dpmmcv}, insaend}); std::vector<Element> injinsa = latt_join({latt_reverse(insaend), {dcvk1, kick, dk1k2, kick, dk2sef, sef}}); std::vector<Element> B3BCB3 = latt_join({B3,{d13},BC,{d13},B3}); std::vector<Element> R01 = latt_join({injinsa, {fim, inicio, mia}, insainj}); //#% injection sector, marker of the lattice model starting element std::vector<Element> R03 = latt_join({latt_reverse(insa), {mia, cav}, insa}); //#% sector with cavities std::vector<Element> R05 = latt_join({latt_reverse(insa), {mia}, insa}); std::vector<Element> R07(R05); std::vector<Element> R09(R05); std::vector<Element> R11(R05); std::vector<Element> R13(R05); std::vector<Element> R15(R05); std::vector<Element> R17(R05); std::vector<Element> R19(R05); std::vector<Element> R02 = latt_join({latt_reverse(insb), {mib}, insb}); std::vector<Element> R04(R02); std::vector<Element> R06(R02); std::vector<Element> R08(R02); std::vector<Element> R10(R02); std::vector<Element> R12(R02); std::vector<Element> R14(R02); std::vector<Element> R16(R02); std::vector<Element> R18(R02); std::vector<Element> R20(R02); std::vector<Element> C01 = latt_join({B1, cline1, B2, cline2, B3BCB3, cline3, B2, cline4, B1}); std::vector<Element> C02(C01); std::vector<Element> C03(C01); std::vector<Element> C04(C01); std::vector<Element> C05(C01); std::vector<Element> C06(C01); std::vector<Element> C07(C01); std::vector<Element> C08(C01); std::vector<Element> C09(C01); std::vector<Element> C10(C01); std::vector<Element> C11(C01); std::vector<Element> C12(C01); std::vector<Element> C13(C01); std::vector<Element> C14(C01); std::vector<Element> C15(C01); std::vector<Element> C16(C01); std::vector<Element> C17(C01); std::vector<Element> C18(C01); std::vector<Element> C19(C01); std::vector<Element> C20(C01); the_ring = latt_join({ R01, C01, R02, C02, R03, C03, R04, C04, R05, C05, R06, C06, R07, C07, R08, C08, R09, C09, R10, C10, R11, C11, R12, C12, R13, C13, R14, C14, R15, C15, R16, C16, R17, C17, R18, C18, R19, C19, R20, C20, }); //""" shift lattice to start at the marker "inicio" """ std::vector<int> idx = latt_findcells_fam_name(the_ring, "inicio"); if (idx.size() > 0) { std::vector<Element>::iterator it = the_ring.begin() + idx[0]; std::rotate(the_ring.begin(), it, the_ring.end()); }; //""" check if there are elements with negative lengths """ std::vector<double> lens = latt_getcellstruct<double>(the_ring, "length", latt_range(the_ring)); for(unsigned int i=0; i<lens.size(); ++i) { if (lens[i] < 0) { std::cerr << "negative drift in lattice!" << std::endl; } } //""" sets cavity frequency according to lattice length """ double C = latt_findspos(the_ring, 1+the_ring.size()); double rev_freq = light_speed / C; std::vector<int> rf_idx = latt_findcells_fam_name(the_ring, "cav"); for(unsigned int idx = 0; idx<rf_idx.size(); ++idx) { the_ring[rf_idx[idx]].frequency = rev_freq * harmonic_number; } latt_setcavity(the_ring, "on"); //latt_setradiation(the_ring, "on", 3e9); //""" adjusts number of integraton steps for each element family """ the_ring = latt_set_num_integ_steps(the_ring); }