BlueSCSI-v2/lib/BlueSCSI_platform_template/BlueSCSI_platform.cpp

#include "BlueSCSI_platform.h"
#include "BlueSCSI_log.h"
#include "BlueSCSI_config.h"
#include <SdFat.h>
#include <scsi.h>
#include <assert.h>

extern "C" {

const char *g_platform_name = PLATFORM_NAME;

/***************/
/* GPIO init   */
/***************/

void platform_init()
{
    /* Initialize SCSI and SD card pins to required modes.
     * SCSI pins should be inactive / input at this point.
     */
}

void platform_late_init()
{
    /* This function can usually be left empty.
     * It can be used for initialization code that should not run in bootloader.
     */
}

void platform_disable_led(void)
{
    /* This function disables the LED on the BlueSCSI board
    *  Generally by switching the pin from output to input.
    */
}


/*****************************************/
/* Debug logging and watchdor            */
/*****************************************/

// This function is called for every log message.
// It can e.g. write the log to serial port in real time.
// It can also be left empty to use only the debug log file on SD card.
void platform_log(const char *s)
{
}

// This function can be used to periodically reset watchdog timer for crash handling.
// It can also be left empty if the platform does not use a watchdog timer.
void platform_reset_watchdog()
{
}

// Poll function that is called every few milliseconds.
// Can be left empty or used for platform-specific processing.
void platform_poll()
{

}

// Called periodically to get the state of any buttons installed on the platform.
// If none are installed the below function is fine.
uint8_t platform_get_buttons()
{
    return 0;
}

/**********************************************/
/* Mapping from data bytes to GPIO BOP values */
/**********************************************/

/* A lookup table is the fastest way to calculate parity and convert the IO pin mapping for
 * data bus. The method below uses the BOP register of GD32, this is called BSRR on STM32.
 * If there are no other pins on the same port, you can also use direct writes to the GPIO.
 */

#define PARITY(n) ((1 ^ (n) ^ ((n)>>1) ^ ((n)>>2) ^ ((n)>>3) ^ ((n)>>4) ^ ((n)>>5) ^ ((n)>>6) ^ ((n)>>7)) & 1)
#define X(n) (\
    ((n & 0x01) ? (SCSI_OUT_DB0 << 16) : SCSI_OUT_DB0) | \
    ((n & 0x02) ? (SCSI_OUT_DB1 << 16) : SCSI_OUT_DB1) | \
    ((n & 0x04) ? (SCSI_OUT_DB2 << 16) : SCSI_OUT_DB2) | \
    ((n & 0x08) ? (SCSI_OUT_DB3 << 16) : SCSI_OUT_DB3) | \
    ((n & 0x10) ? (SCSI_OUT_DB4 << 16) : SCSI_OUT_DB4) | \
    ((n & 0x20) ? (SCSI_OUT_DB5 << 16) : SCSI_OUT_DB5) | \
    ((n & 0x40) ? (SCSI_OUT_DB6 << 16) : SCSI_OUT_DB6) | \
    ((n & 0x80) ? (SCSI_OUT_DB7 << 16) : SCSI_OUT_DB7) | \
    (PARITY(n)  ? (SCSI_OUT_DBP << 16) : SCSI_OUT_DBP) | \
    (SCSI_OUT_REQ) \
)

const uint32_t g_scsi_out_byte_to_bop[256] =
{
    X(0x00), X(0x01), X(0x02), X(0x03), X(0x04), X(0x05), X(0x06), X(0x07), X(0x08), X(0x09), X(0x0a), X(0x0b), X(0x0c), X(0x0d), X(0x0e), X(0x0f),
    X(0x10), X(0x11), X(0x12), X(0x13), X(0x14), X(0x15), X(0x16), X(0x17), X(0x18), X(0x19), X(0x1a), X(0x1b), X(0x1c), X(0x1d), X(0x1e), X(0x1f),
    X(0x20), X(0x21), X(0x22), X(0x23), X(0x24), X(0x25), X(0x26), X(0x27), X(0x28), X(0x29), X(0x2a), X(0x2b), X(0x2c), X(0x2d), X(0x2e), X(0x2f),
    X(0x30), X(0x31), X(0x32), X(0x33), X(0x34), X(0x35), X(0x36), X(0x37), X(0x38), X(0x39), X(0x3a), X(0x3b), X(0x3c), X(0x3d), X(0x3e), X(0x3f),
    X(0x40), X(0x41), X(0x42), X(0x43), X(0x44), X(0x45), X(0x46), X(0x47), X(0x48), X(0x49), X(0x4a), X(0x4b), X(0x4c), X(0x4d), X(0x4e), X(0x4f),
    X(0x50), X(0x51), X(0x52), X(0x53), X(0x54), X(0x55), X(0x56), X(0x57), X(0x58), X(0x59), X(0x5a), X(0x5b), X(0x5c), X(0x5d), X(0x5e), X(0x5f),
    X(0x60), X(0x61), X(0x62), X(0x63), X(0x64), X(0x65), X(0x66), X(0x67), X(0x68), X(0x69), X(0x6a), X(0x6b), X(0x6c), X(0x6d), X(0x6e), X(0x6f),
    X(0x70), X(0x71), X(0x72), X(0x73), X(0x74), X(0x75), X(0x76), X(0x77), X(0x78), X(0x79), X(0x7a), X(0x7b), X(0x7c), X(0x7d), X(0x7e), X(0x7f),
    X(0x80), X(0x81), X(0x82), X(0x83), X(0x84), X(0x85), X(0x86), X(0x87), X(0x88), X(0x89), X(0x8a), X(0x8b), X(0x8c), X(0x8d), X(0x8e), X(0x8f),
    X(0x90), X(0x91), X(0x92), X(0x93), X(0x94), X(0x95), X(0x96), X(0x97), X(0x98), X(0x99), X(0x9a), X(0x9b), X(0x9c), X(0x9d), X(0x9e), X(0x9f),
    X(0xa0), X(0xa1), X(0xa2), X(0xa3), X(0xa4), X(0xa5), X(0xa6), X(0xa7), X(0xa8), X(0xa9), X(0xaa), X(0xab), X(0xac), X(0xad), X(0xae), X(0xaf),
    X(0xb0), X(0xb1), X(0xb2), X(0xb3), X(0xb4), X(0xb5), X(0xb6), X(0xb7), X(0xb8), X(0xb9), X(0xba), X(0xbb), X(0xbc), X(0xbd), X(0xbe), X(0xbf),
    X(0xc0), X(0xc1), X(0xc2), X(0xc3), X(0xc4), X(0xc5), X(0xc6), X(0xc7), X(0xc8), X(0xc9), X(0xca), X(0xcb), X(0xcc), X(0xcd), X(0xce), X(0xcf),
    X(0xd0), X(0xd1), X(0xd2), X(0xd3), X(0xd4), X(0xd5), X(0xd6), X(0xd7), X(0xd8), X(0xd9), X(0xda), X(0xdb), X(0xdc), X(0xdd), X(0xde), X(0xdf),
    X(0xe0), X(0xe1), X(0xe2), X(0xe3), X(0xe4), X(0xe5), X(0xe6), X(0xe7), X(0xe8), X(0xe9), X(0xea), X(0xeb), X(0xec), X(0xed), X(0xee), X(0xef),
    X(0xf0), X(0xf1), X(0xf2), X(0xf3), X(0xf4), X(0xf5), X(0xf6), X(0xf7), X(0xf8), X(0xf9), X(0xfa), X(0xfb), X(0xfc), X(0xfd), X(0xfe), X(0xff)
};

#undef X

} /* extern "C" */

/* The SdFat library is used for SD card access.
 * You can set the configuration here.
 * Refer to SdFat examples for usage on various CPUs.
 */
SdSpiConfig g_sd_spi_config(0, DEDICATED_SPI, SD_SCK_MHZ(25));

void platform_set_sd_callback(sd_callback_t func, const uint8_t *buffer)
{
    /* This function can be left empty.
     * If the platform supports DMA for SD card transfers, this function
     * can be used to set a callback that is invoked while waiting for DMA
     * to finish. In that way the SD card and SCSI transfers can execute
     * simultaneously.
     */
}