/* * scene.c * * Created on: 2025年7月18日 * Author: 86189 */ #include #include #include #include "tg_scene.h" #include "../protocol_internal.h" #include "../ModuleExport.h" tgScene::tgScene(hw_adapter_t* adapter):Scene(adapter) { s8 inport_str[16],outport_str[16]; s8 ana_input_num, ana_output_num, loc_input_num, loc_output_num, dante_input_num, dante_output_num ; s8 usb_input_num, usb_output_num; s16 input_num, output_num ; s32 n, new_idx = 300; //ID of the USB channel starts from 300. s16 dual_dsp = adapter->get_system_is_dual_dsp(); s16 dsp_index = adapter->get_dsp_index(); adapter->get_channel_num(&loc_input_num, &loc_output_num, &dante_input_num, &dante_output_num, &usb_input_num, &usb_output_num); ana_input_num = loc_input_num - usb_input_num; ana_output_num = loc_output_num - usb_output_num; //物理输入共16+16+2 input_num = ana_input_num + dante_input_num + usb_input_num; //2 USB output_num = ana_output_num + dante_output_num + usb_output_num; tgScene_param_default(¶meters); sprintf(inport_str, "1-%d", input_num); __MADD(299,PROC_INPUT,inport_str,inport_str,0, 1 ,¶meters.input, 0, ModuleInterfaceType::PHY_INPUT); sprintf(inport_str, "1-%d", input_num); __MADD(298,PROC_METER,inport_str,"",0,1 ,NULL,0, ModuleInterfaceType::SOFT_MODULE); //tag:0-peak,1-rms //The number of DSPs is 1, but the number of input and output channels is greater than 16. //It only processes analog input and output. //However, for the channels that do not need to be processed, the level offset needs to be calculated. // if(!dual_dsp && input_num >16) { // n = ana_input_num; // } // else { // n= input_num; // } //expander for(s32 i =0 ;i < input_num ; i++) { sprintf(inport_str, "%d|", i+1); if(i < input_num - usb_input_num) __MADD(1+i,PROC_EXPANDER, inport_str, inport_str, 0, 0, ¶meters.in1[i], 0, ModuleInterfaceType::SOFT_MODULE); else __MADD(new_idx++,PROC_EXPANDER, inport_str, inport_str, 0, 0, ¶meters.in1[i], 0, ModuleInterfaceType::SOFT_MODULE); } //compresser for(s32 i =0 ;i < input_num ; i++) { sprintf(inport_str, "%d|", i+1); if(i < input_num - usb_input_num) __MADD(33+i,PROC_COMPRESS, inport_str, inport_str, 0, 0, ¶meters.in2[i], 0, ModuleInterfaceType::SOFT_MODULE); else __MADD(new_idx++,PROC_COMPRESS, inport_str, inport_str, 0, 0, ¶meters.in2[i], 0, ModuleInterfaceType::SOFT_MODULE); } //agc for(s32 i =0 ;i < input_num ; i++) { sprintf(inport_str, "%d|", i+1); if(i < input_num - usb_input_num) __MADD(65+i,PROC_AGC, inport_str, inport_str, 0, 0, ¶meters.in3[i], 0, ModuleInterfaceType::SOFT_MODULE); else __MADD(new_idx++,PROC_AGC, inport_str, inport_str, 0, 0, ¶meters.in3[i], 0, ModuleInterfaceType::SOFT_MODULE); } //eq for(s32 i =0 ;i < input_num ; i++) { sprintf(inport_str, "%d|", i+1); if(i < input_num - usb_input_num) __MADD(97+i,PROC_EQ, inport_str, inport_str, 0, 0, ¶meters.in4[i], 8, ModuleInterfaceType::SOFT_MODULE); else __MADD(new_idx++,PROC_EQ, inport_str, inport_str, 0, 0, ¶meters.in4[i], 8, ModuleInterfaceType::SOFT_MODULE); } //nhs for(s32 i =0 ;i < input_num ; i++) { sprintf(inport_str, "%d|", i+1); if(i < input_num - usb_input_num) __MADD(129+i,PROC_FEEDBACK, inport_str, inport_str, 0, 0, ¶meters.in5[i], 8, ModuleInterfaceType::SOFT_MODULE); else __MADD(new_idx++,PROC_FEEDBACK, inport_str, inport_str, 0, 0, ¶meters.in5[i], 8, ModuleInterfaceType::SOFT_MODULE); } //am sprintf(inport_str, "1-%d", input_num); sprintf(outport_str, "1-%d", input_num+1); __MADD(161,PROC_AUTOMIXER,inport_str, outport_str, 0, 0, ¶meters.automixer, 0, ModuleInterfaceType::SOFT_MODULE); //¿ÉÌæ»» //aec selector sprintf(inport_str, "1-%d", input_num+ 1); sprintf(outport_str, "%d|%d|", input_num+ 2, input_num+ 3); __MADD(162,PROC_SELECTOR, inport_str,outport_str, 0, 1, ¶meters.aec_selector, 0, ModuleInterfaceType::SOFT_MODULE); //add usb //aec sprintf(inport_str, "%d|%d", input_num+ 2, input_num+ 3); sprintf(outport_str, "%d|", input_num+ 2); __MADD(163,PROC_AEC,inport_str, outport_str ,0, 1, ¶meters.aec, 256, ModuleInterfaceType::SOFT_MODULE); //ans selector sprintf(inport_str, "1-%d", input_num+ 2); sprintf(outport_str, "%d|", input_num+ 3); __MADD(164,PROC_SELECTOR,inport_str,outport_str, 1, 1 ,¶meters.ans_selector, 0, ModuleInterfaceType::SOFT_MODULE); //ans sprintf(inport_str, "%d|", input_num+ 3); sprintf(outport_str, "%d|", input_num+ 3); __MADD(165,PROC_ANS,inport_str,outport_str, 1, 0 ,¶meters.afc_ns,0, ModuleInterfaceType::SOFT_MODULE); //mixer sprintf(inport_str, "1-%d", input_num+ 3); sprintf(outport_str, "%d-%d",input_num+4, input_num+output_num+4); __MADD(166,PROC_MIXER,inport_str,outport_str,1, 1 ,¶meters.mixer, 0, ModuleInterfaceType::SOFT_MODULE); // .begin()+48 //crossover for(s32 i =0 ;i < output_num ; i++) { sprintf(inport_str, "%d|", i+input_num+4); sprintf(outport_str, "%d|", i+1); if(i < output_num - usb_output_num) __MADD(167+i,PROC_CROSSOVER,inport_str,outport_str,1, 0, ¶meters.out1[i],2, ModuleInterfaceType::SOFT_MODULE); else __MADD(new_idx++,PROC_CROSSOVER,inport_str,outport_str,1, 0, ¶meters.out1[i],2, ModuleInterfaceType::SOFT_MODULE); } //eq for(s32 i =0 ;i < output_num ; i++) { sprintf(outport_str, "%d|", i+1); if(i < output_num - usb_output_num) __MADD(199+i,PROC_EQ,outport_str, outport_str,1, 0, ¶meters.out2[i], 8, ModuleInterfaceType::SOFT_MODULE); else __MADD(new_idx++,PROC_EQ,outport_str, outport_str,1, 0, ¶meters.out2[i], 8, ModuleInterfaceType::SOFT_MODULE); } //delay for(s32 i =0 ;i < output_num ; i++) { sprintf(outport_str, "%d|", i+1); if(i < output_num - usb_output_num) __MADD(231+i,PROC_DELAY,outport_str, outport_str,1, 0, ¶meters.out3[i], 1200, ModuleInterfaceType::SOFT_MODULE); else __MADD(new_idx++,PROC_DELAY,outport_str, outport_str,1, 0, ¶meters.out3[i], 1200, ModuleInterfaceType::SOFT_MODULE); } //limit for(s32 i =0 ;i < output_num ; i++) { sprintf(outport_str, "%d|", i+1); if(i < output_num - usb_output_num) __MADD(263+i,PROC_LIMIT,outport_str, outport_str,1, 0, ¶meters.out4[i],0, ModuleInterfaceType::SOFT_MODULE); else __MADD(new_idx++,PROC_LIMIT,outport_str, outport_str,1, 0, ¶meters.out4[i],0, ModuleInterfaceType::SOFT_MODULE); } //output sprintf(outport_str, "1-%d", output_num); __MADD(295,PROC_OUTPUT,outport_str,outport_str,1, 1, ¶meters.output,0, ModuleInterfaceType::SOFT_MODULE); //sysctrl __MADD(296,PROC_SYSCTL,outport_str,outport_str,1, 1, ¶meters.sysctl,0, ModuleInterfaceType::SOFT_MODULE); //meter __MADD(297,PROC_METER,outport_str,outport_str,1, 1, NULL, 0, ModuleInterfaceType::PHY_OUTPUT); }; void tgScene::module_def(s32 proc_type, void* param_ptr) { int j; int allbypass = 1; switch(proc_type) { case PROC_INPUT: ptag_input pInput = (ptag_input)param_ptr; pInput->input_num = MAX_INPUT_NUM; for(j=0; jinput_num; j++){ pInput->input[j].freq = 1000; pInput->input[j].level = -4800; pInput->input[j].phant = 0; pInput->input[j].sensitivity = 0; pInput->input[j].channelID = j; pInput->input[j].gain =0; pInput->input[j].mute = 0; pInput->input[j].type=0; pInput->input[j].phase =0; pInput->input[j].mingain = -8000; pInput->input[j].maxgain = 1200; } break; case PROC_METER: ptag_Meter pMeter = (ptag_Meter)param_ptr; pMeter->input_num = 8; break; case PROC_SHELF: ptag_shelf pshelf = (ptag_shelf)param_ptr; pshelf->highshelf.bypass = allbypass; pshelf->highshelf.freq = 500; pshelf->highshelf.gain = -4500; pshelf->highshelf.q = 71; pshelf->lowshelf.bypass = 1; pshelf->lowshelf.freq = 500; pshelf->lowshelf.gain =-4500; pshelf->lowshelf.q = 71; break; case PROC_GEQ: int j; ptag_geq pGEQ = (ptag_geq)param_ptr; pGEQ->bypass = allbypass; pGEQ->q_index = 2; pGEQ->nsections = 31; for(j=0;j<31;j++){ pGEQ->eq_attr[j].gain = 0; } break; case PROC_EQ: ptag_eq pEQ = (ptag_eq)param_ptr; u16 freq[]={40,80,200,500,1000,2000,4000,8000,10000,12500,16000,20000}; pEQ->bypass = allbypass; pEQ->nsection = MAX_EQ_SECTION; for(j=0;jnsection;j++){ pEQ->eq_attr[j].bypass = allbypass; pEQ->eq_attr[j].freq = freq[j]; pEQ->eq_attr[j].gain = 0; pEQ->eq_attr[j].q = 250; //pEQ->eq_attr[j].type = } break; case PROC_EXPANDER: ptag_expander pExpander = (ptag_expander)param_ptr; pExpander->bypass = allbypass; pExpander->threshold = -6000; pExpander->ratio = 100; pExpander->attack = 1; pExpander->release = 1; break; case PROC_COMPRESS: ptag_compress pcompress = (ptag_compress)param_ptr; pcompress->bypass = allbypass; pcompress->threshold = -4800; pcompress->ratio = 100; pcompress->attack = 1; pcompress->release = 1; pcompress->gain = 0; pcompress->soft = 0; break; case PROC_LIMIT: ptag_compress limiter = (ptag_compress)param_ptr; limiter->bypass = allbypass; limiter->threshold = 0; limiter->ratio = 10000; limiter->attack = 1; limiter->release = 1; limiter->gain = 0; limiter->soft = 0; break; case PROC_MIXER: int m; ptag_mixer pMixer = (ptag_mixer)param_ptr; pMixer->input_num = MAX_MIXER_INPUT; pMixer->output_num = MAX_MIXER_OUTPUT; memset(pMixer->input_mask,0,sizeof(pMixer->input_mask)); for (m=0;moutput_num ;m ++){ for(j=0;jinput_num;j++){ pMixer->input_gain[m][j]=0; pMixer->delay[m][j] =0; } pMixer->input_mask[m][m/16]=1<<(m&15); } break; case PROC_DELAY: ptag_delay pDelay = (ptag_delay)param_ptr; pDelay->bypass = allbypass; pDelay->ms = 1; break; case PROC_CROSSOVER: ptag_crossover pCross = (ptag_crossover)param_ptr; pCross->highpass.bypass = allbypass; pCross->highpass.freq = 500;//454; pCross->highpass.taps = 18;//48; pCross->highpass.type = 0; pCross->highpass.gain =0 ; pCross->lowpass.bypass = allbypass; pCross->lowpass.freq = 500; pCross->lowpass.taps = 18; pCross->lowpass.type = 0; pCross->lowpass.gain =0; break; case PROC_OUTPUT: ptag_output pOutput= (ptag_output)param_ptr; pOutput->output_num = MAX_OUTPUT_NUM; for(j=0;joutput_num;j++){ pOutput->output[j].gain = 0; pOutput->output[j].mute = 0; pOutput->output[j].channelID = j; pOutput->output[j].phase = 0; pOutput->output[j].mingain = -8000; pOutput->output[j].maxgain = 1200; } break; case PROC_GAIN: ptag_gain pgain = (ptag_gain)param_ptr; pgain->gain = 0; pgain->mute = 0; break; case PROC_AUTOMIXER: ptag_gainsharing_mixer pautomixer = (ptag_gainsharing_mixer)param_ptr; pautomixer->bypass = allbypass; pautomixer->master_mute =0; pautomixer->master_gain =0; pautomixer->response = 5; pautomixer->slope = 200; for(j=0;jchannels[j].automatic = 0; pautomixer->channels[j].mute = 0; pautomixer->channels[j].gain = 0; pautomixer->channels[j].priority = 5; } break; case PROC_FEEDBACK: ptag_feedback pfb = (ptag_feedback)param_ptr; pfb->bypass = allbypass; pfb->panic_threshold = 0; pfb->flt_depth = 1800; break; case PROC_SYSCTL: ptag_sysctl psysctl = (ptag_sysctl)param_ptr; psysctl->gain = 0; psysctl->mute = 0; break; case PROC_AEC: ptag_aec paec = (ptag_aec)param_ptr; paec->bypass = allbypass; paec->mode = 0; break; case PROC_ANS: ptag_ans pans = (ptag_ans)param_ptr; pans->bypass = allbypass; pans->mode = 0; break; case PROC_SELECTOR: ptag_selector pselector = (ptag_selector)param_ptr; pselector->input_num = MAX_MIXER_INPUT; pselector->output_num = MAX_MIXER_OUTPUT; memset(pselector->input_mask,0,sizeof(pselector->input_mask)); break; case PROC_AGC: ptag_agc pAGC = (ptag_agc)param_ptr; pAGC->bypass = allbypass; pAGC->attacktime = 1; pAGC->releasetime = 500; pAGC->ratio = 100; pAGC->tar_threshold = 0; pAGC->threshold =-4800; break; case PROC_GATING_AUTOMIXER: ptag_gating_mixer pgautomixer = (ptag_gating_mixer)param_ptr; pgautomixer->bypass = allbypass; pgautomixer->master_mute =0; pgautomixer->master_gain =0; pgautomixer->holdtime = 500; pgautomixer->offgain = -4000; pgautomixer->sensitivity = 600; pgautomixer->nom_atten = 300; pgautomixer->nom_num = 4; for(j=0;jchannels[j].automatic = 0; pgautomixer->channels[j].mute = 0; pgautomixer->channels[j].gain = 0; pgautomixer->channels[j].priority = 5; } break; case PROC_CONTINUNOUS_SPL: ptag_spl pspl = (ptag_spl)param_ptr; pspl->maxgain = 2000; pspl->mingain = -2000; pspl->sense_ratio = 75; pspl->speed = 5; pspl->trim =0; pspl->bypass = allbypass; memset((void*)pspl->mask,0,sizeof(pspl->mask)); break; case PROC_GATING: ptag_gate pgate = (ptag_gate)param_ptr; pgate->bypass = allbypass; pgate->threshold = -3000; pgate->depth = -6000; pgate->attacktime = 2; pgate->holdtime = 5; pgate->releasetime = 1000; break; case PROC_DUCKER: ptag_ducker pducker = (ptag_ducker)param_ptr; pducker->bypass = allbypass; pducker->threshold = -4500; pducker->depth = -2000; pducker->attacktime = 20; pducker->holdtime = 1000; pducker->releasetime = 1000; memset((void*)pducker->mask,0,sizeof(pducker->mask)); break; case PROC_REVERB: break; case PROC_ECHO: break; case PROC_FIR: ptag_fir pfir = (ptag_fir)param_ptr; pfir->bypass = allbypass; pfir->taps = 1024; memset((void*)pfir->coeffs, 0, sizeof(pfir->coeffs)); pfir->coeffs[0] = 1; break; default: break; } } void tgScene::tgScene_param_default(ptag_parameters p) { int i,j,module_cnt=0; module_def(PROC_INPUT, &p->input); for (i=0; iin1[i]); module_def(PROC_COMPRESS, &p->in2[i]); module_def(PROC_AGC, &p->in3[i]); module_def(PROC_EQ, &p->in4[i]); module_def(PROC_FEEDBACK, &p->in5[i]); } module_def(PROC_AUTOMIXER, &p->automixer); module_def(PROC_SELECTOR, &p->aec_selector); module_def(PROC_AEC, &p->aec); module_def(PROC_SELECTOR, &p->ans_selector); module_def(PROC_ANS, &p->ans_selector); module_def(PROC_MIXER, &p->mixer); for (i=0; iout1[i]); module_def(PROC_EQ, &p->out2[i]); module_def(PROC_DELAY, &p->out3[i]); module_def(PROC_LIMIT, &p->out4[i]); } module_def(PROC_OUTPUT, &p->output); module_def(PROC_SYSCTL, &p->sysctl); } s32 tgScene::set_parameters_content(uvoid* param, s32 size) { tag_parameters* pp = (tag_parameters*)param; int L[24] = {0}; if(pp->magic != 0xbcba || size != sizeof(tag_parameters)) { printf("preset param error!\n"); /*printf("tag_head:%d,%d,%d,%d,%d\n", L[0]=sizeof(parameters.magic), L[1]=sizeof(parameters.nmds)+L[0], L[2]=sizeof(parameters.pad1)+L[1], L[3]=sizeof(parameters.pad2)+L[2], L[4]=sizeof(parameters.crc)+L[3]); printf("tag_input:%d, %d\n", sizeof(tag_input), L[5]=sizeof(tag_input)+L[4]); printf("tag_module_in:%d, %d\n", sizeof(tag_module), L[6]=sizeof(tag_module) * MAX_INPUT_NUM * 5 + L[5]); printf("tag_automixer:%d, %d\n", sizeof(tag_automixer), L[7]=sizeof(tag_automixer)+L[6]); printf("tag_select1:%d, %d\n", sizeof(tag_selector), L[8]=sizeof(tag_selector)+L[7]); printf("tag_aec:%d, %d\n", sizeof(tag_aec), L[9]=sizeof(tag_aec)+L[8]); printf("tag_selector:%d, %d\n", sizeof(tag_selector), L[10]=sizeof(tag_selector) + L[9]); printf("tag_3a:%d, %d, %d\n", sizeof(tag_3a), L[11]=sizeof(tag_3a)+L[10]); printf("tag_mixer:%d, %d\n", sizeof(tag_mixer), L[12]=sizeof(tag_mixer)+L[11]); printf("tag_module_o1:%d, %d\n", sizeof(tag_module), L[13]=sizeof(tag_module) * MAX_INPUT_NUM + L[12]); printf("tag_module_fir:%d\n", sizeof(tag_module_fir), L[14]=sizeof(tag_module_fir) * MAX_OUTPUT_NUM + L[13]); printf("tag_module_out:%d\n", sizeof(tag_module), L[15]=sizeof(tag_module) * MAX_OUTPUT_NUM * 2 + L[14]); printf("tag_output:%d, %d\n", sizeof(tag_output), L[16]=sizeof(tag_output)+L[15]); printf("tag_sysctl:%d, %d\n", sizeof(tag_sysctl), L[17]=sizeof(tag_sysctl)+L[16]); printf("tag_group:%d, %d\n", sizeof(tag_group), L[18]=sizeof(tag_group)+L[17]);*/ dbg_printf("Len parameters:%d, Len recv:%d\n", L[19]=sizeof(tag_parameters), size); return -1; } memcpy(¶meters, param, sizeof(tag_parameters)); return 0; } s32 tgScene::update_dynmodule_tag(s32 proc_type, struct proc_field* proc) { switch(proc_type) { case ModuleType::PROC_GEQ:{ ptag_module pmodule = (ptag_module)proc->parameters; ptag_geq geq = (ptag_geq)pmodule->proc_ins; proc->tag = geq->nsections; } break; case ModuleType::PROC_EQ:{ ptag_module pmodule = (ptag_module)proc->parameters; ptag_eq eq = (ptag_eq)pmodule->proc_ins; proc->tag = eq->nsection; } break; case ModuleType::PROC_GATING: case ModuleType::PROC_EXPANDER: proc->tag =0; break; case ModuleType::PROC_COMPRESS: case ModuleType::PROC_LIMIT: proc->tag =0; break; case ModuleType::PROC_DELAY: proc->tag =1200; break; case ModuleType::PROC_CROSSOVER: proc->tag =1; break; case ModuleType::PROC_FEEDBACK:{ ptag_module pmodule = (ptag_module)proc->parameters; ptag_feedback nhs = (ptag_feedback)pmodule->proc_ins; proc->tag = nhs->fbc_num; } break; case ModuleType::PROC_AGC: proc->tag =0; break; case ModuleType::PROC_CONTINUNOUS_SPL: proc->tag =0; break; case ModuleType::PROC_DUCKER: proc->tag =0; break; case ModuleType::PROC_FIR: proc->tag = 1024; break; default: proc->tag =0 ; break; } proc->proc_type = proc_type; return 0; } s32 tgScene::update_module() { s8 ana_input_num, ana_output_num,dante_input_num,dante_output_num, usb_input_num, usb_output_num ; s16 input_num, output_num ; s16 dual_dsp = hw_adapter->get_system_is_dual_dsp(); s16 dsp_index = hw_adapter->get_dsp_index(); hw_adapter->get_channel_num(&ana_input_num, &ana_output_num, &dante_input_num, &dante_output_num, &usb_input_num, &usb_output_num); input_num = ana_input_num + dante_input_num; output_num = ana_output_num + dante_output_num; for(auto& iter: proc_list){ //update dynamic module info. if(iter.fixed == 0) { ptag_module pmodule = (ptag_module)iter.parameters; if(pmodule->proc_type >= ModuleType::PROC_COUNT || pmodule->proc_type < ModuleType::PROC_NONE) { pmodule->proc_type = ModuleType::PROC_NONE; } update_dynmodule_tag(pmodule->proc_type, &iter); } } return 0; } uvoid* tgScene::get_module_param_ptr(s32 mType, uvoid *param, s32 fixed) { uvoid *ptr = param; if(fixed == 0){ if (PROC_FIR == mType) { ptag_module_fir pmod = (ptag_module_fir)param; ptr = (void*)pmod->proc_ins; } else { ptag_module pmod = (ptag_module)param; ptr = (void*)pmod->proc_ins; } } return ptr; } //u32 tgScene::get_module_id(u32 mid, s32 mtype , u32 pid) //{ // if(mtype == PROC_INPUT && (pid == INPUT_TYPE || pid == INPUT_FREQ || pid == INPUT_LEVEL)){ // mid = 300; // } // else if(mtype == PROC_DUCKER && pid == DUCKER_MIX){ // mid = mid + 320; // } // // return mid; //}