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#ifndef _SSC_H
#define _SSC_H
#include "queue.h"
#include "iso14443_layer3a.h"
extern void ssc_rx_start(void);
extern void ssc_rx_stop(void);
/* Rx/Tx initialization separate, since Tx disables PWM output ! */
extern void ssc_tx_init(void);
extern void ssc_rx_init(void);
extern void ssc_fini(void);
extern void ssc_rx_stop(void);
extern void ssc_rx_unthrottle(void);
extern void __ramfunc ssc_rx_stop_frame_ended(void);
enum ssc_mode {
SSC_MODE_NONE,
SSC_MODE_14443A_SHORT,
SSC_MODE_14443A_STANDARD,
SSC_MODE_14443B,
SSC_MODE_EDGE_ONE_SHOT,
SSC_MODE_CONTINUOUS,
};
extern void ssc_rx_mode_set(enum ssc_mode ssc_mode);
typedef void (*ssc_irq_ext_t)(u_int32_t ssc_sr, enum ssc_mode ssc_mode, u_int8_t* samples);
/* A fast method to extend the IRQ handler from the higher level code, e.g. to prepare
* an ATQA answer to REQA or WUPA in iso14443_layer3a. Normally I'd use the FreeRTOS
* primitives to wake the task and then do everything in task context, but the delay
* from SSC IRQ to the task returning from xQueueReceive is around 165us. Additionally to the
* delay from end of communication to SSC IRQ which is around 50us. This results in way more delay
* than acceptable for the synchronous responses (around 87us).*/
extern ssc_irq_ext_t ssc_set_irq_extension(ssc_irq_ext_t ext_handler);
extern portBASE_TYPE ssc_get_overflows(void);
extern int ssc_count_free(void);
#define SSC_DMA_BUFFER_SIZE 2048
#define SSC_DMA_BUFFER_COUNT 4
typedef enum {
FREE=0, /* Buffer is free */
PENDING, /* Buffer has been given to the DMA controller and is currently being filled */
FULL, /* DMA controller signalled that the buffer is full */
PROCESSING,/* The buffer is currently processed by the consumer (e.g. decoder) */
PREFILLED, /* The buffer has been prefilled for later usage (only used for TX) */
} ssc_dma_buffer_state_t;
typedef struct {
volatile ssc_dma_buffer_state_t state;
u_int32_t len; /* Length of the content */
enum ssc_mode reception_mode;
u_int8_t data[SSC_DMA_BUFFER_SIZE];
} ssc_dma_rx_buffer_t;
extern xQueueHandle ssc_rx_queue;
/* in bytes, used for the sample buffer that holds the subcarrier modulation data at fc/8 = 1695 MHz */
#define SSC_TX_BUFFER_SIZE ((MAXIMUM_FRAME_SIZE*( (8+1)*2 ) ) + 2 + 2)
typedef struct {
volatile ssc_dma_buffer_state_t state;
u_int32_t len; /* Length of the content */
void *source; /* Source pointer for a prefilled buffer; set to NULL if not used */
u_int8_t data[SSC_TX_BUFFER_SIZE];
} ssc_dma_tx_buffer_t;
/* Declare one TX buffer. This means that only one buffer can ever be pending for sending. That's because
* this buffer must be huge (one frame of 256 bytes of subcarrier modulation data at 1695 MHz sample
* rate is approx 4k bytes). */
extern ssc_dma_tx_buffer_t ssc_tx_buffer;
extern void ssc_tx_start(ssc_dma_tx_buffer_t *buf);
#endif
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