/*
Copyright (C) 2018 Evariste COURJAUD F5OEO
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see .
*/
#include "stdio.h"
#include "amdmasync.h"
#include "gpio.h"
#include
#include
#include
#include
#include
amdmasync::amdmasync(uint64_t TuneFrequency,uint32_t SR,int Channel,uint32_t FifoSize):bufferdma(Channel,FifoSize,3,2)
{
SampleRate=SR;
tunefreq=TuneFrequency;
clkgpio::SetAdvancedPllMode(true);
clkgpio::SetCenterFrequency(TuneFrequency,SampleRate);
clkgpio::SetFrequency(0);
clkgpio::enableclk(4); // GPIO 4 CLK by default
syncwithpwm=false;
if(syncwithpwm)
{
pwmgpio::SetPllNumber(clk_plld,1);
pwmgpio::SetFrequency(SampleRate);
}
else
{
pcmgpio::SetPllNumber(clk_plld,1);
pcmgpio::SetFrequency(SampleRate);
}
padgpio pad;
Originfsel=pad.gpioreg[PADS_GPIO_0];
SetDmaAlgo();
}
amdmasync::~amdmasync()
{
clkgpio::disableclk(4);
padgpio pad;
pad.gpioreg[PADS_GPIO_0]=Originfsel;
}
void amdmasync::SetDmaAlgo()
{
dma_cb_t *cbp = cbarray;
for (uint32_t samplecnt = 0; samplecnt < buffersize; samplecnt++)
{
//@0
//Set Amplitude by writing to PADS
SetEasyCB(cbp,samplecnt*registerbysample,dma_pad,1);
cbp++;
//@1
//Set Amplitude to FSEL for amplitude=0
SetEasyCB(cbp,samplecnt*registerbysample+1,dma_fsel,1);
cbp++;
// Delay
SetEasyCB(cbp,samplecnt*registerbysample,syncwithpwm?dma_pwm:dma_pcm,1);
cbp++;
}
cbp--;
cbp->next = mem_virt_to_phys(cbarray); // We loop to the first CB
//dbg_printf(1,"Last cbp : src %x dest %x next %x\n",cbp->src,cbp->dst,cbp->next);
}
void amdmasync::SetAmSample(uint32_t Index,float Amplitude) //-1;1
{
Index=Index%buffersize;
int IntAmplitude=round(abs(Amplitude)*8.0)-1;
int IntAmplitudePAD=IntAmplitude;
if(IntAmplitudePAD>7) IntAmplitudePAD=7;
if(IntAmplitudePAD<0) IntAmplitudePAD=0;
//dbg_printf(1,"Amplitude=%f PAD %d\n",Amplitude,IntAmplitudePAD);
sampletab[Index*registerbysample]=(0x5A<<24) + (IntAmplitudePAD&0x7) + (1<<4) + (0<<3); // Amplitude PAD
//sampletab[Index*registerbysample+2]=(Originfsel & ~(7 << 12)) | (4 << 12); //Alternate is CLK
if(IntAmplitude==-1)
{
sampletab[Index*registerbysample+1]=(Originfsel & ~(7 << 12)) | (0 << 12); //Pin is in -> Amplitude 0
}
else
{
sampletab[Index*registerbysample+1]=(Originfsel & ~(7 << 12)) | (4 << 12); //Alternate is CLK
}
PushSample(Index);
}
void amdmasync::SetAmSamples(float *sample,size_t Size)
{
size_t NbWritten=0;
int OSGranularity=100;
long int start_time;
long time_difference=0;
struct timespec gettime_now;
while(NbWritten0)
{
//dbg_printf(1,"buffer size %d Available %d SampleRate %d Sleep %d\n",buffersize,Available,SampleRate,TimeToSleep);
usleep(TimeToSleep);
}
else
{
//dbg_printf(1,"No Sleep %d\n",TimeToSleep);
sched_yield();
}
clock_gettime(CLOCK_REALTIME, &gettime_now);
time_difference = gettime_now.tv_nsec - start_time;
if(time_difference<0) time_difference+=1E9;
//dbg_printf(1,"Measure samplerate=%d\n",(int)((GetBufferAvailable()-Available)*1e9/time_difference));
Available=GetBufferAvailable();
int Index=GetUserMemIndex();
int ToWrite=((int)Size-(int)NbWritten)