r999: maintainers added to README_en.

[cinelerra_cv/mob.git] / cinelerra / audioidevice.C

#include "audiodevice.h"
#include "bcprogressbox.h"
#include "bcsignals.h"
#include "bctimer.h"
#include "condition.h"
#include "dcoffset.h"
#include "mutex.h"

#include <string.h>


#define GET_PEAK_MACRO \
                                        input_channel[j] = sample;                          \
                                        if(sample > max[i]) max[i] = sample;           \
                                        else if(-sample > max[i]) max[i] = -sample;


#define GET_8BIT_SAMPLE_MACRO1 \
sample = input_buffer[k];      \
k += input_channels;           \
if(sample >= max_sample[i]) { sample = max_sample[i]; if(over_count < 3) over_count++; } \
else                           \
if(sample <= min_sample[i]) { sample = min_sample[i]; if(over_count < 3) over_count++; } \
else                           \
if(over_count < 3) over_count = 0; 

#define GET_8BIT_SAMPLE_MACRO2 \
sample /= 0x7f;                  



#define GET_16BIT_SAMPLE_MACRO1                            \
sample = input_buffer_16[k];                               \
k += input_channels;                                       \
if(sample >= max_sample[i]) { sample = max_sample[i]; if(over_count < 3) over_count++; } \
else                                                       \
if(sample <= min_sample[i]) { sample = min_sample[i]; if(over_count < 3) over_count++; } \
else                                                       \
if(over_count < 3) over_count = 0;                         \

#define GET_16BIT_SAMPLE_MACRO2                            \
sample /= 0x7fff;                  



#define GET_24BIT_SAMPLE_MACRO1 \
sample = (unsigned char)input_buffer[k] | \
                        (((unsigned char)input_buffer[k + 1]) << 8) | \
                        (((int)input_buffer[k + 2]) << 16); \
k += input_channels * 3; \
if(sample >= max_sample[i]) { sample = max_sample[i]; if(over_count < 3) over_count++; } \
else                                                 \
if(sample <= min_sample[i]) { sample = min_sample[i]; if(over_count < 3) over_count++; } \
else                                                 \
if(over_count < 3) over_count = 0; 

#define GET_24BIT_SAMPLE_MACRO2       \
sample /= 0x7fffff;



#define GET_32BIT_SAMPLE_MACRO1 \
sample = (unsigned char)input_buffer[k] | \
                        (((unsigned char)input_buffer[k + 1]) << 8) | \
                        (((unsigned char)input_buffer[k + 2]) << 16) | \
                        (((int)input_buffer[k + 3]) << 24); \
k += input_channels * 4; \
if(sample >= max_sample[i]) { sample = max_sample[i]; if(over_count < 3) over_count++; } \
else \
if(sample <= min_sample[i]) { sample = min_sample[i]; if(over_count < 3) over_count++; } \
else \
if(over_count < 3) over_count = 0; 

#define GET_32BIT_SAMPLE_MACRO2       \
sample /= 0x7fffffff;

int AudioDevice::read_buffer(double **input, 
        int samples, 
        int *over, 
        double *max, 
        int input_offset)
{
        int i, j, k, frame, bits;
        double sample, denominator;
        double min_sample[MAXCHANNELS], max_sample[MAXCHANNELS];
        int sample_int;
        int over_count;
        int input_channels;
        int result = 0;
        double *input_channel;



        record_timer->update();

        bits = get_ibits();
        input_channels = get_ichannels();
        frame = input_channels * bits / 8;

        total_samples_read += samples;

        switch(bits)
        {
                case 8:       
                        denominator = 0x7f;          
                        break;
                case 16:      
                        denominator = 0x7fff;        
                        break;
                case 24:      
                        denominator = 0x7fffff;      
                        break;
                case 32:      
                        denominator = 0x7fffffff;      
                        break;
        }


        for(i = 0; i < get_ichannels(); i++)
        {
                min_sample[i] = -denominator; 
                max_sample[i] = denominator; 
                max[i] = 0; 
                over_count = 0;
        }



        int got_it = 0;
        int fragment_size = samples * frame;
        while(fragment_size > 0 && is_recording)
        {

// Get next buffer
                polling_lock->lock("AudioDevice::read_buffer");


                int output_buffer_num = thread_buffer_num - 1;
                if(output_buffer_num < 0) output_buffer_num = TOTAL_BUFFERS - 1;


// Test previously written buffer for data
                char *input_buffer = this->input_buffer[output_buffer_num];

                int *input_buffer_size = &this->buffer_size[output_buffer_num];


// No data.  Test current buffer for data
                if(!*input_buffer_size)
                {
                        read_waiting = 1;
                        buffer_lock->lock("AudioDevice::read_buffer 1");
                        read_waiting = 0;
                        input_buffer = this->input_buffer[thread_buffer_num];

                        input_buffer_size = &this->buffer_size[thread_buffer_num];


// Data in current buffer.  Advance thread buffer.
                        if(*input_buffer_size >= fragment_size)
                        {
                                thread_buffer_num++;
                                if(thread_buffer_num >= TOTAL_BUFFERS)
                                        thread_buffer_num = 0;
                        }
                        else
// Not enough data.
                        {
                                input_buffer = 0;
                                input_buffer_size = 0;
                        }

                        buffer_lock->unlock();

                }


// Transfer data
                if(input_buffer_size && *input_buffer_size)
                {
                        int subfragment_size = fragment_size;
                        if(subfragment_size > *input_buffer_size)
                                subfragment_size = *input_buffer_size;
                        int subfragment_samples = subfragment_size / frame;


                        for(i = 0; i < get_ichannels(); i++)
                        {
                                input_channel = &input[i][input_offset];

// device is set to little endian
                                switch(bits)
                                {
                                        case 8:
                                                for(j = 0, k = i; j < subfragment_samples; j++)
                                                {
                                                        GET_8BIT_SAMPLE_MACRO1
                                                        GET_8BIT_SAMPLE_MACRO2
                                                        GET_PEAK_MACRO
                                                }
                                                break;

                                        case 16:
                                                {
                                                        int16_t *input_buffer_16;
                                                        input_buffer_16 = (int16_t *)input_buffer;

                                                        {
                                                                for(j = 0, k = i; j < subfragment_samples; j++)
                                                                {
                                                                        GET_16BIT_SAMPLE_MACRO1
                                                                        GET_16BIT_SAMPLE_MACRO2
                                                                        GET_PEAK_MACRO
                                                                }
                                                        }
                                                }
                                                break;

                                        case 24:
                                                for(j = 0, k = i * 3; j < subfragment_samples; j++)
                                                {
                                                        GET_24BIT_SAMPLE_MACRO1
                                                        GET_24BIT_SAMPLE_MACRO2
                                                        GET_PEAK_MACRO
                                                }

                                        case 32:
                                                for(j = 0, k = i * 4; j < subfragment_samples; j++)
                                                {
                                                        GET_32BIT_SAMPLE_MACRO1
                                                        GET_32BIT_SAMPLE_MACRO2
                                                        GET_PEAK_MACRO
                                                }
                                                break;
                                }

                                if(over_count >= 3) 
                                        over[i] = 1; 
                                else 
                                        over[i] = 0;
                        }




                        input_offset += subfragment_size / frame;

// Shift input buffer
                        if(*input_buffer_size > subfragment_size)
                        {
                                memcpy(input_buffer, 
                                        input_buffer + subfragment_size, 
                                        *input_buffer_size - subfragment_size);
                        }

                        fragment_size -= subfragment_size;
                        *input_buffer_size -= subfragment_size;
                }
        }







        return result < 0;
}


void AudioDevice::run_input()
{
        int frame = get_ichannels() * get_ibits() / 8;
        int fragment_size = in_samples * frame;

        while(is_recording)
        {
                if(read_waiting) usleep(1);
                buffer_lock->lock("AudioDevice::run_input 1");

// Get available input buffer
                char *input_buffer = this->input_buffer[thread_buffer_num];
                int *input_buffer_size = &this->buffer_size[thread_buffer_num];

                if(*input_buffer_size + fragment_size > INPUT_BUFFER_BYTES)
                {
                        *input_buffer_size = INPUT_BUFFER_BYTES - fragment_size;
                        *input_buffer_size -= *input_buffer_size % fragment_size;
                        printf("AudioDevice::run_input: buffer overflow\n");
                }

                int result = get_lowlevel_in()->read_buffer(
                        input_buffer + *input_buffer_size, 
                        fragment_size);

                if(result < 0)
                {
                        perror("AudioDevice::run_input");
                        sleep(1);
                }
                else
                {
                        *input_buffer_size += fragment_size;

                }
                buffer_lock->unlock();
                polling_lock->unlock();
        }
}

void AudioDevice::start_recording()
{
        is_recording = 1;
        interrupt = 0;
        thread_buffer_num = 0;

        for(int i = 0; i < TOTAL_BUFFERS; i++)
        {
                input_buffer[i] = new char[INPUT_BUFFER_BYTES];
        }
        record_timer->update();

        Thread::set_realtime(get_irealtime());
        Thread::start();
}