void test_sgpio_sliceA_D(void)
{
SGPIO_GPIO_OENREG = 0; // All inputs for the moment.
// Disable all counters during configuration
SGPIO_CTRL_ENABLE = 0;
// Configure pin functions.
configure_sgpio_pin_functions();
/****************************************************/
/* Enable SGPIO pin outputs. */
/****************************************************/
SGPIO_GPIO_OENREG =
0xFFFF; // data: output for SGPIO0 to SGPIO15
/*******************************************************************************/
/* SGPIO pin 0 outputs slice A bit 0. (see Table 212. Output pin multiplexing) */
/*******************************************************************************/
SGPIO_OUT_MUX_CFG(0) =
(0L << 4) | // P_OE_CFG = X
(0L << 0); // P_OUT_CFG = 0, dout_doutm1 (1-bit mode)
// SGPIO pin 12 outputs slice D bit 0. (see Table 212. Output pin multiplexing)
SGPIO_OUT_MUX_CFG(12) =
(0L << 4) | // P_OE_CFG = X
(0L << 0); // P_OUT_CFG = 0, dout_doutm1 (1-bit mode)
/****************************************************/
/* Slice A */
/****************************************************/
SGPIO_MUX_CFG(SGPIO_SLICE_A) =
(0L << 12) | // CONCAT_ORDER = 0 (self-loop)
(1L << 11) | // CONCAT_ENABLE = 1 (concatenate data)
(0L << 9) | // QUALIFIER_SLICE_MODE = X
(0L << 7) | // QUALIFIER_PIN_MODE = X
(0L << 5) | // QUALIFIER_MODE = 0 (enable)
(0L << 3) | // CLK_SOURCE_SLICE_MODE = 0, slice D
(0L << 1) | // CLK_SOURCE_PIN_MODE = X
(0L << 0); // EXT_CLK_ENABLE = 0, internal clock signal (slice)
SGPIO_SLICE_MUX_CFG(SGPIO_SLICE_A) =
(0L << 8) | // INV_QUALIFIER = 0 (use normal qualifier)
(0L << 6) | // PARALLEL_MODE = 0 (shift 1 bit per clock)
(0L << 4) | // DATA_CAPTURE_MODE = 0 (detect rising edge)
(0L << 3) | // INV_OUT_CLK = 0 (normal clock)
(0L << 2) | // CLKGEN_MODE = 0 (use clock from COUNTER)
(0L << 1) | // CLK_CAPTURE_MODE = 0 (use rising clock edge)
(0L << 0); // MATCH_MODE = 0 (do not match data)
SGPIO_PRESET(SGPIO_SLICE_A) = 1;
SGPIO_COUNT(SGPIO_SLICE_A) = 0;
SGPIO_POS(SGPIO_SLICE_A) = (0x1FL << 8) | (0x1FL << 0);
SGPIO_REG(SGPIO_SLICE_A) = 0xAAAAAAAA; // Primary output data register
SGPIO_REG_SS(SGPIO_SLICE_A) = 0xAAAAAAAA; // Shadow output data register
/****************************************************/
/* Slice D (clock for Slice A) */
/****************************************************/
SGPIO_MUX_CFG(SGPIO_SLICE_D) =
(0L << 12) | // CONCAT_ORDER = 0 (self-loop)
(1L << 11) | // CONCAT_ENABLE = 1 (concatenate data)
(0L << 9) | // QUALIFIER_SLICE_MODE = X
(0L << 7) | // QUALIFIER_PIN_MODE = X
(0L << 5) | // QUALIFIER_MODE = 0 (enable)
(0L << 3) | // CLK_SOURCE_SLICE_MODE = 0, slice D
(0L << 1) | // CLK_SOURCE_PIN_MODE = X
(0L << 0); // EXT_CLK_ENABLE = 0, internal clock signal (slice)
SGPIO_SLICE_MUX_CFG(SGPIO_SLICE_D) =
(0L << 8) | // INV_QUALIFIER = 0 (use normal qualifier)
(0L << 6) | // PARALLEL_MODE = 0 (shift 1 bit per clock)
(0L << 4) | // DATA_CAPTURE_MODE = 0 (detect rising edge)
(0L << 3) | // INV_OUT_CLK = 0 (normal clock)
(0L << 2) | // CLKGEN_MODE = 0 (use clock from COUNTER)
(0L << 1) | // CLK_CAPTURE_MODE = 0 (use rising clock edge)
(0L << 0); // MATCH_MODE = 0 (do not match data)
SGPIO_PRESET(SGPIO_SLICE_D) = 0;
SGPIO_COUNT(SGPIO_SLICE_D) = 0;
SGPIO_POS(SGPIO_SLICE_D) = (0x1FL << 8) | (0x1FL << 0);
SGPIO_REG(SGPIO_SLICE_D) = 0xAAAAAAAA; // Primary output data register
SGPIO_REG_SS(SGPIO_SLICE_D) = 0xAAAAAAAA; // Shadow output data register
/****************************************************/
/* Start SGPIO operation by enabling slice clocks. */
/****************************************************/
SGPIO_CTRL_ENABLE =
(1L << SGPIO_SLICE_D) | // Slice D
(1L << SGPIO_SLICE_A); // Slice A
// Start SGPIO operation by enabling slice clocks.
/*
Expected:
SGPIO12 = MCU Freq/2
SGPIO0 = SGPIO12/2 MHz= 51MHz (SliceD/2)
*/
}
/*
SGPIO0 to 7 = DAC/ADC data bits 0 to 7 (Nota: DAC is 10bits but only bit9 to bit2 are used bit1 & 0 are forced to 0 by CPLD)
ADC=> CLK x 2=CLKx2 with CLKx2(0)rising=D0Q, CLKx2(1)rising=D1I (corresponds to CLK(0)falling+tD0Q=>D0Q, CLK(1)rising+tDOI=>D1I, CLK(1)falling+tD0Q=>D1Q, CLK(1)rising+tDOI=>D2I ...)
tDOI(CLK Rise to I-ADC Channel-I Output Data Valid)=7.4 to 9ns, tD0Q(CLK Fall to Q-ADC Channel-Q Output Data Valid)=6.9 to 9ns
DAC=> CLK x 2=CLKx2 with CLKx2(0)rising=Q:N-2, CLKx2(1)rising=I:N-1(corresponds to CLK(0)rising=>Q:N-2, CLK(0)falling I:N-1, CLK(1)rising=>Q:N-1, CLK(1)falling I:N ...)
tDSI(I-DAC Data to CLK Fall Setup Time)=min 10ns, tDSQ(Q-DAC Data to CLK Rise Setup Time)=min 10ns
SGPIO8 Clock Input (External Clock)
SGPIO9 Capture Input (Capture/ChipSelect, 1=Enable Capture, 0=Disable capture)
SGPIO10 Disable Output (1/High=Disable codec data stream, 0/Low=Enable codec data stream)
SGPIO11 Direction Output (1/High=TX mode LPC43xx=>CPLD=>DAC, 0/Low=RX mode LPC43xx<=CPLD<=ADC)
*/
void sgpio_configure(
sgpio_config_t* const config,
const sgpio_direction_t direction
) {
// Disable all counters during configuration
SGPIO_CTRL_ENABLE = 0;
// Set SGPIO output values.
const uint_fast8_t cpld_direction =
(direction == SGPIO_DIRECTION_TX) ? 1 : 0;
SGPIO_GPIO_OUTREG =
(cpld_direction << 11) /* 1=Output SGPIO11 High(TX mode), 0=Output SGPIO11 Low(RX mode)*/
| (1L << 10) // disable codec data stream during configuration (Output SGPIO10 High)
;
#ifdef RAD1O
/* The data direction might have changed. Check if we need to
* adjust the q inversion. */
update_q_invert(config);
#endif
// Enable SGPIO pin outputs.
const uint_fast16_t sgpio_gpio_data_direction =
(direction == SGPIO_DIRECTION_TX)
? (0xFF << 0)
: (0x00 << 0);
SGPIO_GPIO_OENREG =
(1L << 14) // GPDMA burst request SGPIO14 active
| (1L << 11) // direction output SGPIO11 active
| (1L << 10) // disable output SGPIO10 active
| (0L << 9) // capture input SGPIO9 (output i is tri-stated)
| (0L << 8) // clock input SGPIO8 (output i is tri-stated)
| sgpio_gpio_data_direction // 0xFF=Output all SGPIO High(TX mode), 0x00=Output all SPGIO Low(RX mode)
;
SGPIO_OUT_MUX_CFG( 8) = // SGPIO8: Input: clock
SGPIO_OUT_MUX_CFG_P_OE_CFG(0) /* 0x0 gpio_oe (state set by GPIO_OEREG) */
| SGPIO_OUT_MUX_CFG_P_OUT_CFG(0) /* 0x0 dout_doutm1 (1-bit mode) */
;
SGPIO_OUT_MUX_CFG( 9) = // SGPIO9: Input: qualifier
SGPIO_OUT_MUX_CFG_P_OE_CFG(0) /* 0x0 gpio_oe (state set by GPIO_OEREG) */
| SGPIO_OUT_MUX_CFG_P_OUT_CFG(0) /* 0x0 dout_doutm1 (1-bit mode) */
;
SGPIO_OUT_MUX_CFG(10) = // GPIO10: Output: disable
SGPIO_OUT_MUX_CFG_P_OE_CFG(0) /* 0x0 gpio_oe (state set by GPIO_OEREG) */
| SGPIO_OUT_MUX_CFG_P_OUT_CFG(4) /* 0x4=gpio_out (level set by GPIO_OUTREG) */
;
SGPIO_OUT_MUX_CFG(11) = // GPIO11: Output: direction
SGPIO_OUT_MUX_CFG_P_OE_CFG(0) /* 0x0 gpio_oe (state set by GPIO_OEREG) */
| SGPIO_OUT_MUX_CFG_P_OUT_CFG(4) /* 0x4=gpio_out (level set by GPIO_OUTREG) */
;
SGPIO_OUT_MUX_CFG(14) = // SGPIO14: Output: internal GPDMA burst request
SGPIO_OUT_MUX_CFG_P_OE_CFG(0) /* 0x4 dout_oem1 (1-bit mode) */
| SGPIO_OUT_MUX_CFG_P_OUT_CFG(0) /* 0x0 dout_doutm1 (1-bit mode) */
;
const uint_fast8_t output_multiplexing_mode =
config->slice_mode_multislice ? 11 : 9;
/* SGPIO0 to SGPIO7 */
for(uint_fast8_t i=0; i<8; i++) {
// SGPIO pin 0 outputs slice A bit "i".
SGPIO_OUT_MUX_CFG(i) =
SGPIO_OUT_MUX_CFG_P_OE_CFG(0)
| SGPIO_OUT_MUX_CFG_P_OUT_CFG(output_multiplexing_mode) /* 11/0xB=dout_doutm8c (8-bit mode 8c)(multislice L0/7, N0/7), 9=dout_doutm8a (8-bit mode 8a)(A0/7,B0/7) */
;
}
const uint_fast8_t slice_indices[] = {
SGPIO_SLICE_A,
SGPIO_SLICE_I,
SGPIO_SLICE_E,
SGPIO_SLICE_J,
SGPIO_SLICE_C,
SGPIO_SLICE_K,
SGPIO_SLICE_F,
SGPIO_SLICE_L,
};
const uint_fast8_t slice_gpdma = SGPIO_SLICE_H;
const uint_fast8_t pos = config->slice_mode_multislice ? 0x1f : 0x03;
const bool single_slice = !config->slice_mode_multislice;
const uint_fast8_t slice_count = config->slice_mode_multislice ? 8 : 1;
const uint_fast8_t clk_capture_mode = (direction == SGPIO_DIRECTION_TX) ? 0 : 0;
uint32_t slice_enable_mask = 0;
/* Configure Slice A, I, E, J, C, K, F, L (sgpio_slice_mode_multislice mode) */
for(uint_fast8_t i=0; i<slice_count; i++)
{
const uint_fast8_t slice_index = slice_indices[i];
const bool input_slice = (i == 0) && (direction != SGPIO_DIRECTION_TX); /* Only for slice0/A and RX mode set input_slice to 1 */
const uint_fast8_t concat_order = (input_slice || single_slice) ? 0 : 3; /* 0x0=Self-loop(slice0/A RX mode), 0x3=8 slices */
const uint_fast8_t concat_enable = (input_slice || single_slice) ? 0 : 1; /* 0x0=External data pin(slice0/A RX mode), 0x1=Concatenate data */
SGPIO_MUX_CFG(slice_index) =
SGPIO_MUX_CFG_CONCAT_ORDER(concat_order)
| SGPIO_MUX_CFG_CONCAT_ENABLE(concat_enable)
| SGPIO_MUX_CFG_QUALIFIER_SLICE_MODE(0) /* Select qualifier slice A(0x0) */
| SGPIO_MUX_CFG_QUALIFIER_PIN_MODE(1) /* Select qualifier pin SGPIO9(0x1) */
| SGPIO_MUX_CFG_QUALIFIER_MODE(3) /* External SGPIO */
| SGPIO_MUX_CFG_CLK_SOURCE_SLICE_MODE(0) /* Select clock source slice D(0x0) */
| SGPIO_MUX_CFG_CLK_SOURCE_PIN_MODE(0) /* Source Clock Pin 0x0 = SGPIO8 */
| SGPIO_MUX_CFG_EXT_CLK_ENABLE(1) /* External clock signal(pin) selected */
;
SGPIO_SLICE_MUX_CFG(slice_index) =
SGPIO_SLICE_MUX_CFG_INV_QUALIFIER(0) /* 0x0=Use normal qualifier. */
| SGPIO_SLICE_MUX_CFG_PARALLEL_MODE(3) /* 0x3=Shift 1 byte(8bits) per clock. */
| SGPIO_SLICE_MUX_CFG_DATA_CAPTURE_MODE(0) /* 0x0=Detect rising edge. (Condition for input bit match interrupt) */
| SGPIO_SLICE_MUX_CFG_INV_OUT_CLK(0) /* 0x0=Normal clock. */
| SGPIO_SLICE_MUX_CFG_CLKGEN_MODE(1) /* 0x1=Use external clock from a pin or other slice */
| SGPIO_SLICE_MUX_CFG_CLK_CAPTURE_MODE(clk_capture_mode) /* 0x0=Use rising clock edge, 0x1=Use falling clock edge */
| SGPIO_SLICE_MUX_CFG_MATCH_MODE(0) /* 0x0=Do not match data */
;
SGPIO_PRESET(slice_index) = 0; // External clock, don't care
SGPIO_COUNT(slice_index) = 0; // External clock, don't care
SGPIO_POS(slice_index) =
SGPIO_POS_POS_RESET(pos)
| SGPIO_POS_POS(pos)
;
SGPIO_REG(slice_index) = 0x00000000; // Primary output data register
SGPIO_REG_SS(slice_index) = 0x00000000; // Shadow output data register
slice_enable_mask |= (1 << slice_index);
}
if( config->slice_mode_multislice == false ) {
SGPIO_MUX_CFG(slice_gpdma) =
SGPIO_MUX_CFG_CONCAT_ORDER(0) /* Self-loop */
| SGPIO_MUX_CFG_CONCAT_ENABLE(1)
| SGPIO_MUX_CFG_QUALIFIER_SLICE_MODE(0) /* Select qualifier slice A(0x0) */
| SGPIO_MUX_CFG_QUALIFIER_PIN_MODE(1) /* Select qualifier pin SGPIO9(0x1) */
| SGPIO_MUX_CFG_QUALIFIER_MODE(3) /* External SGPIO */
| SGPIO_MUX_CFG_CLK_SOURCE_SLICE_MODE(0) /* Select clock source slice D(0x0) */
| SGPIO_MUX_CFG_CLK_SOURCE_PIN_MODE(0) /* Source Clock Pin 0x0 = SGPIO8 */
| SGPIO_MUX_CFG_EXT_CLK_ENABLE(1) /* External clock signal(pin) selected */
;
SGPIO_SLICE_MUX_CFG(slice_gpdma) =
SGPIO_SLICE_MUX_CFG_INV_QUALIFIER(0) /* 0x0=Use normal qualifier. */
| SGPIO_SLICE_MUX_CFG_PARALLEL_MODE(0) /* 0x0=Shift 1 bit per clock. */
| SGPIO_SLICE_MUX_CFG_DATA_CAPTURE_MODE(0) /* 0x0=Detect rising edge. (Condition for input bit match interrupt) */
| SGPIO_SLICE_MUX_CFG_INV_OUT_CLK(0) /* 0x0=Normal clock. */
| SGPIO_SLICE_MUX_CFG_CLKGEN_MODE(1) /* 0x1=Use external clock from a pin or other slice */
| SGPIO_SLICE_MUX_CFG_CLK_CAPTURE_MODE(clk_capture_mode) /* 0x0=Use rising clock edge, 0x1=Use falling clock edge */
| SGPIO_SLICE_MUX_CFG_MATCH_MODE(0) /* 0x0=Do not match data */
;
SGPIO_PRESET(slice_gpdma) = 0; // External clock, don't care
SGPIO_COUNT(slice_gpdma) = 0; // External clock, don't care
SGPIO_POS(slice_gpdma) =
SGPIO_POS_POS_RESET(0x1f)
| SGPIO_POS_POS(0x1f)
;
SGPIO_REG(slice_gpdma) = 0x11111111; // Primary output data register, LSB -> out
SGPIO_REG_SS(slice_gpdma) = 0x11111111; // Shadow output data register, LSB -> out1
slice_enable_mask |= (1 << slice_gpdma);
}
// Start SGPIO operation by enabling slice clocks.
SGPIO_CTRL_ENABLE = slice_enable_mask;
}
void test_sgpio_all_slices(void)
{
SGPIO_GPIO_OENREG = 0; // All inputs for the moment.
// Disable all counters during configuration
SGPIO_CTRL_ENABLE = 0;
// Configure pin functions.
configure_sgpio_pin_functions();
/****************************************************/
/* Enable SGPIO pin outputs. */
/****************************************************/
SGPIO_GPIO_OENREG =
0xFFFF; // data: output for SGPIO0 to SGPIO15
for(uint_fast8_t i=0; i<16; i++)
{
SGPIO_OUT_MUX_CFG(i) =
(0L << 4) | // P_OE_CFG = X
(0L << 0); // P_OUT_CFG = 0, dout_doutm1 (1-bit mode)
}
/****************************************************/
/* Slice A to P */
/****************************************************/
for(uint_fast8_t i=0; i<16; i++)
{
SGPIO_MUX_CFG(i) =
(0L << 12) | // CONCAT_ORDER = 0 (self-loop)
(1L << 11) | // CONCAT_ENABLE = 1 (concatenate data)
(0L << 9) | // QUALIFIER_SLICE_MODE = X
(0L << 7) | // QUALIFIER_PIN_MODE = X
(0L << 5) | // QUALIFIER_MODE = 0 (enable)
(0L << 3) | // CLK_SOURCE_SLICE_MODE = 0, slice D
(0L << 1) | // CLK_SOURCE_PIN_MODE = X
(0L << 0); // EXT_CLK_ENABLE = 0, internal clock signal (slice)
SGPIO_SLICE_MUX_CFG(i) =
(0L << 8) | // INV_QUALIFIER = 0 (use normal qualifier)
(0L << 6) | // PARALLEL_MODE = 0 (shift 1 bit per clock)
(0L << 4) | // DATA_CAPTURE_MODE = 0 (detect rising edge)
(0L << 3) | // INV_OUT_CLK = 0 (normal clock)
(0L << 2) | // CLKGEN_MODE = 0 (use clock from COUNTER)
(0L << 1) | // CLK_CAPTURE_MODE = 0 (use rising clock edge)
(0L << 0); // MATCH_MODE = 0 (do not match data)
SGPIO_PRESET(i) = slice_preset_tab[i];
SGPIO_COUNT(i) = 0;
SGPIO_POS(i) = (0x1FL << 8) | (0x1FL << 0);
SGPIO_REG(i) = 0xAAAAAAAA; // Primary output data register
SGPIO_REG_SS(i) = 0xAAAAAAAA; // Shadow output data register
}
/****************************************************/
/* Start SGPIO operation by enabling slice clocks. */
/****************************************************/
SGPIO_CTRL_ENABLE = 0xFFFF; /* Start all slices A to P */
/*
(1L << SGPIO_SLICE_D) | // Slice D
(1L << SGPIO_SLICE_A); // Slice A
// Start SGPIO operation by enabling slice clocks.
*/
/*
Expected:
MCU Freq MHz = 204
SGPIO Theorical Freq MHz
SGPIO00 = 102,00000
SGPIO01 = 51,00000
SGPIO02 = 34,00000
SGPIO03 = 25,50000
SGPIO04 = 20,40000
SGPIO05 = 17,00000
SGPIO06 = 14,57143
SGPIO07 = 12,75000
SGPIO08 = 11,33333
SGPIO09 = 10,20000
SGPIO10 = 9,27273
SGPIO11 = 8,50000
SGPIO12 = 7,84615
SGPIO13 = 7,28571
SGPIO14 = 6,80000
SGPIO15 = 6,37500
TitanMKD: I have problems with my boards and this test see document Test_SGPIO0_to15.ods / Test_SGPIO0_to15.pdf
*/
}
void sgpio_configure(
const transceiver_mode_t transceiver_mode,
const bool multi_slice
) {
// Disable all counters during configuration
SGPIO_CTRL_ENABLE = 0;
sgpio_configure_pin_functions();
// Set SGPIO output values.
const uint_fast8_t cpld_direction =
(transceiver_mode == TRANSCEIVER_MODE_TX) ? 1 : 0;
SGPIO_GPIO_OUTREG =
(cpld_direction << 11)
| (1L << 10) // disable
;
// Enable SGPIO pin outputs.
const uint_fast16_t sgpio_gpio_data_direction =
(transceiver_mode == TRANSCEIVER_MODE_TX)
? (0xFF << 0)
: (0x00 << 0);
SGPIO_GPIO_OENREG =
(1L << 11) // direction
| (1L << 10) // disable
| (0L << 9) // capture
| (0L << 8) // clock
| sgpio_gpio_data_direction
;
SGPIO_OUT_MUX_CFG( 8) = // SGPIO: Input: clock
SGPIO_OUT_MUX_CFG_P_OE_CFG(0)
| SGPIO_OUT_MUX_CFG_P_OUT_CFG(0)
;
SGPIO_OUT_MUX_CFG( 9) = // SGPIO: Input: qualifier
SGPIO_OUT_MUX_CFG_P_OE_CFG(0)
| SGPIO_OUT_MUX_CFG_P_OUT_CFG(0)
;
SGPIO_OUT_MUX_CFG(10) = // GPIO: Output: disable
SGPIO_OUT_MUX_CFG_P_OE_CFG(0)
| SGPIO_OUT_MUX_CFG_P_OUT_CFG(4)
;
SGPIO_OUT_MUX_CFG(11) = // GPIO: Output: direction
SGPIO_OUT_MUX_CFG_P_OE_CFG(0)
| SGPIO_OUT_MUX_CFG_P_OUT_CFG(4)
;
const uint_fast8_t output_multiplexing_mode =
multi_slice ? 11 : 9;
for(uint_fast8_t i=0; i<8; i++) {
// SGPIO pin 0 outputs slice A bit "i".
SGPIO_OUT_MUX_CFG(i) =
SGPIO_OUT_MUX_CFG_P_OE_CFG(0)
| SGPIO_OUT_MUX_CFG_P_OUT_CFG(output_multiplexing_mode)
;
}
const uint_fast8_t slice_indices[] = {
SGPIO_SLICE_A,
SGPIO_SLICE_I,
SGPIO_SLICE_E,
SGPIO_SLICE_J,
SGPIO_SLICE_C,
SGPIO_SLICE_K,
SGPIO_SLICE_F,
SGPIO_SLICE_L,
};
const uint_fast8_t pos = multi_slice ? 0x1f : 0x03;
const bool single_slice = !multi_slice;
const uint_fast8_t slice_count = multi_slice ? 8 : 1;
uint32_t slice_enable_mask = 0;
for(uint_fast8_t i=0; i<slice_count; i++) {
const uint_fast8_t slice_index = slice_indices[i];
const bool input_slice = (i == 0) && (transceiver_mode == TRANSCEIVER_MODE_RX);
const uint_fast8_t concat_order = (input_slice || single_slice) ? 0 : 3;
const uint_fast8_t concat_enable = (input_slice || single_slice) ? 0 : 1;
SGPIO_MUX_CFG(slice_index) =
SGPIO_MUX_CFG_CONCAT_ORDER(concat_order)
| SGPIO_MUX_CFG_CONCAT_ENABLE(concat_enable)
| SGPIO_MUX_CFG_QUALIFIER_SLICE_MODE(0)
| SGPIO_MUX_CFG_QUALIFIER_PIN_MODE(1)
| SGPIO_MUX_CFG_QUALIFIER_MODE(3)
| SGPIO_MUX_CFG_CLK_SOURCE_SLICE_MODE(0)
| SGPIO_MUX_CFG_CLK_SOURCE_PIN_MODE(0)
| SGPIO_MUX_CFG_EXT_CLK_ENABLE(1)
;
SGPIO_SLICE_MUX_CFG(slice_index) =
SGPIO_SLICE_MUX_CFG_INV_QUALIFIER(0)
| SGPIO_SLICE_MUX_CFG_PARALLEL_MODE(3)
| SGPIO_SLICE_MUX_CFG_DATA_CAPTURE_MODE(0)
| SGPIO_SLICE_MUX_CFG_INV_OUT_CLK(0)
| SGPIO_SLICE_MUX_CFG_CLKGEN_MODE(1)
| SGPIO_SLICE_MUX_CFG_CLK_CAPTURE_MODE(1)
| SGPIO_SLICE_MUX_CFG_MATCH_MODE(0)
;
SGPIO_PRESET(slice_index) = 0; // External clock, don't care
SGPIO_COUNT(slice_index) = 0; // External clock, don't care
SGPIO_POS(slice_index) =
SGPIO_POS_POS_RESET(pos)
| SGPIO_POS_POS(pos)
;
SGPIO_REG(slice_index) = 0x80808080; // Primary output data register
SGPIO_REG_SS(slice_index) = 0x80808080; // Shadow output data register
slice_enable_mask |= (1 << slice_index);
}
// Start SGPIO operation by enabling slice clocks.
SGPIO_CTRL_ENABLE = slice_enable_mask;
}