rekahsoft
/
qmk-firmware
1
0
Fork 0
Code Issues Pull Requests Releases Wiki Activity

Bringing Massdrop keyboard hardware configuration to keyboard level (#4593) 

MCU Pins for debugging, LED, boot tracing, and shift registers are now configurable at keyboard level.
Macros led_* replaced by DBG_LED_*
Macros m15_* replaced by DBG_1_*
Macros m27_* replaced by DBG_2_*
Macros m28_* replaced by DBG_3_*
For CTRL and ALT keyboards, debug boot tracing pin default now set to pad M27 instead of M28 since although M28 is not being used, it is technically a signal for USB port detection.
m15_print(...) renamed to dbg_print(...) to get away from hard coded port names.
dbg_print function now follows similar pattern to debug led output.
This commit is contained in:
patrickmt 2018-12-10 14:28:06 -05:00 committed by Drashna Jaelre
parent e99615b2ac
commit 4a5e68f4f2
12 changed files with 374 additions and 185 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

51
keyboards/massdrop/alt/config.h
View File

@ -32,17 +32,64 @@ along with this program. If not, see <http://www.gnu.org/licenses/>.
#define MATRIX_ROWS 5
#define MATRIX_COLS 15
/* MCU Port name definitions */
#define PA 0
#define PB 1
/* Port and Pin definition of key row hardware configuration */
#define MATRIX_ROW_PORTS PA, PA, PA, PA, PA
#define MATRIX_ROW_PINS 0, 1, 2, 3, 4
/* Port and Pin definition of key column hardware configuration */
#define MATRIX_COL_PORTS PB, PB, PB, PB, PB, PB, PB, PB, PB, PB, PA, PA, PA, PA, PA
#define MATRIX_COL_PINS 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 5, 6, 7, 10, 11
/* Print boot debug codes using debug LED when M28 and M30 shorted */
#define DEBUG_BOOT_TRACING
/* This Shift Register expands available hardware output lines to control additional peripherals */
/* It uses four lines from the MCU to provide 16 output lines */
/* Shift Register Clock configuration (MCU to ShiftRegister.RCLK) */
#define SR_EXP_RCLK_PORT PB
#define SR_EXP_RCLK_PIN 14
/* Shift Register Output Enable configuration (MCU to ShiftRegister.OE_N) */
#define SR_EXP_OE_N_PORT PB
#define SR_EXP_OE_N_PIN 15
/* SERCOM port to use for Shift Register SPI */
/* DATAOUT and SCLK must be configured to use hardware pins of this port */
#define SR_EXP_SERCOM SERCOM2
/* Shift Register SPI Data Out configuration (MCU.SERCOMx.PAD[0] to ShiftRegister.SER) */
#define SR_EXP_DATAOUT_PORT PA
#define SR_EXP_DATAOUT_PIN 12
#define SR_EXP_DATAOUT_MUX 2
/* Shift Register SPI Serial Clock configuration (MCU.SERCOMx.PAD[1] to ShiftRegister.SRCLK) */
#define SR_EXP_SCLK_PORT PA
#define SR_EXP_SCLK_PIN 13
#define SR_EXP_SCLK_MUX 2
/* Debug LED (Small LED Located near MCU) */
#define DEBUG_LED_ENABLE 1
#define DEBUG_LED_PORT PA
#define DEBUG_LED_PIN 27
/* Additional debugging ports */
/* PCB M21 */
#define DEBUG_PORT1_ENABLE 1
#define DEBUG_PORT1_PORT PB
#define DEBUG_PORT1_PIN 3
/* PCB M23 */
#define DEBUG_PORT2_ENABLE 1
#define DEBUG_PORT2_PORT PB
#define DEBUG_PORT2_PIN 17
/* PCB M25 */
#define DEBUG_PORT3_ENABLE 1
#define DEBUG_PORT3_PORT PA
#define DEBUG_PORT3_PIN 20
/* Debug Boot Tracing - During boot sequence, ground this pin to halt and display debug code using Debug LED */
/* This is useful in determining which hardware device may have malfunctioned or is improperly configured */
/* Feature is automatically disabled after successful boot */
/* PCB M27 */
#define DEBUG_BOOT_TRACING_ENABLE 1
#define DEBUG_BOOT_TRACING_PORT PB
#define DEBUG_BOOT_TRACING_PIN 23
/* Debounce reduces chatter (unintended double-presses) - set 0 if debouncing is not needed */
#define DEBOUNCING_DELAY 5

6
keyboards/massdrop/alt/matrix.c
View File

@ -75,7 +75,7 @@ void matrix_init(void)
PORT->Group[col_ports[col]].DIRSET.reg = 1 << col_pins[col]; //Output
PORT->Group[col_ports[col]].OUTCLR.reg = 1 << col_pins[col]; //Low
}
matrix_init_quantum();
}
@ -91,7 +91,7 @@ uint8_t matrix_scan(void)
if (CLK_get_ms() < mdebouncing) return 1; //mdebouncing == 0 when no debouncing active
//m15_off; //Profiling scans
//DBG_1_OFF; //Profiling scans
memset(mlatest, 0, MATRIX_ROWS * sizeof(matrix_row_t)); //Zero the result buffer
@ -135,7 +135,7 @@ uint8_t matrix_scan(void)
mdebouncing = CLK_get_ms() + DEBOUNCING_DELAY;
}
//m15_on; //Profiling scans
//DBG_1_ON; //Profiling scans
matrix_scan_quantum();

51
keyboards/massdrop/ctrl/config.h
View File

@ -32,17 +32,64 @@ along with this program. If not, see <http://www.gnu.org/licenses/>.
#define MATRIX_ROWS 11
#define MATRIX_COLS 8
/* MCU Port name definitions */
#define PA 0
#define PB 1
/* Port and Pin definition of key row hardware configuration */
#define MATRIX_ROW_PORTS PB, PB, PB, PB, PB, PB, PA, PA, PB, PB, PB
#define MATRIX_ROW_PINS 4, 5, 6, 7, 8, 9, 10, 11, 10, 11, 12
/* Port and Pin definition of key column hardware configuration */
#define MATRIX_COL_PORTS PA, PA, PA, PA, PA, PA, PA, PA
#define MATRIX_COL_PINS 0, 1, 2, 3, 4, 5, 6, 7
/* Print boot debug codes using debug LED when M28 and M30 shorted */
#define DEBUG_BOOT_TRACING
/* This Shift Register expands available hardware output lines to control additional peripherals */
/* It uses four lines from the MCU to provide 16 output lines */
/* Shift Register Clock configuration (MCU to ShiftRegister.RCLK) */
#define SR_EXP_RCLK_PORT PB
#define SR_EXP_RCLK_PIN 14
/* Shift Register Output Enable configuration (MCU to ShiftRegister.OE_N) */
#define SR_EXP_OE_N_PORT PB
#define SR_EXP_OE_N_PIN 15
/* SERCOM port to use for Shift Register SPI */
/* DATAOUT and SCLK must be configured to use hardware pins of this port */
#define SR_EXP_SERCOM SERCOM2
/* Shift Register SPI Data Out configuration (MCU.SERCOMx.PAD[0] to ShiftRegister.SER) */
#define SR_EXP_DATAOUT_PORT PA
#define SR_EXP_DATAOUT_PIN 12
#define SR_EXP_DATAOUT_MUX 2
/* Shift Register SPI Serial Clock configuration (MCU.SERCOMx.PAD[1] to ShiftRegister.SRCLK) */
#define SR_EXP_SCLK_PORT PA
#define SR_EXP_SCLK_PIN 13
#define SR_EXP_SCLK_MUX 2
/* Debug LED (Small LED Located near MCU) */
#define DEBUG_LED_ENABLE 1
#define DEBUG_LED_PORT PA
#define DEBUG_LED_PIN 27
/* Additional debugging ports */
/* PCB M21 */
#define DEBUG_PORT1_ENABLE 1
#define DEBUG_PORT1_PORT PB
#define DEBUG_PORT1_PIN 3
/* PCB M23 */
#define DEBUG_PORT2_ENABLE 1
#define DEBUG_PORT2_PORT PB
#define DEBUG_PORT2_PIN 17
/* PCB M25 */
#define DEBUG_PORT3_ENABLE 1
#define DEBUG_PORT3_PORT PA
#define DEBUG_PORT3_PIN 20
/* Debug Boot Tracing - During boot sequence, ground this pin to halt and display debug code using Debug LED */
/* This is useful in determining which hardware device may have malfunctioned or is improperly configured */
/* Feature is automatically disabled after successful boot */
/* PCB M27 */
#define DEBUG_BOOT_TRACING_ENABLE 1
#define DEBUG_BOOT_TRACING_PORT PB
#define DEBUG_BOOT_TRACING_PIN 23
/* Debounce reduces chatter (unintended double-presses) - set 0 if debouncing is not needed */
#define DEBOUNCING_DELAY 5

6
keyboards/massdrop/ctrl/matrix.c
View File

@ -75,7 +75,7 @@ void matrix_init(void)
PORT->Group[col_ports[col]].DIRSET.reg = 1 << col_pins[col]; //Output
PORT->Group[col_ports[col]].OUTCLR.reg = 1 << col_pins[col]; //Low
}
matrix_init_quantum();
}
@ -91,7 +91,7 @@ uint8_t matrix_scan(void)
if (CLK_get_ms() < mdebouncing) return 1; //mdebouncing == 0 when no debouncing active
//m15_off; //Profiling scans
//DBG_1_OFF; //Profiling scans
memset(mlatest, 0, MATRIX_ROWS * sizeof(matrix_row_t)); //Zero the result buffer
@ -135,7 +135,7 @@ uint8_t matrix_scan(void)
mdebouncing = CLK_get_ms() + DEBOUNCING_DELAY;
}
//m15_on; //Profiling scans
//DBG_1_ON; //Profiling scans
matrix_scan_quantum();

124
tmk_core/protocol/arm_atsam/d51_util.c
View File

@ -1,8 +1,11 @@
#include "d51_util.h"
//Display unsigned 32-bit number through m15
//Read as follows: 1230 = || ||| |||| | (note always ending toggle)
void m15_print(uint32_t x)
static volatile uint32_t w;
//Display unsigned 32-bit number by port toggling DBG_1 (to view on a scope)
//Read as follows: 1230 = | | | | | | || (note zero is fast double toggle)
#define DBG_PAUSE 5
void dbg_print(uint32_t x)
{
int8_t t;
uint32_t n;
@ -26,24 +29,34 @@ void m15_print(uint32_t x)
while (p2--) p *= 10;
n = x / p;
x -= n * p;
while (n > 0)
if (!n)
{
m15_on;
DBG_1_ON;
DBG_1_OFF;
DBG_1_ON;
DBG_1_OFF;
n--;
m15_off;
}
//Will always end with an extra toggle
m15_on;
else
{
while (n > 0)
{
DBG_1_ON;
DBG_1_OFF;
n--;
}
}
t--;
m15_off;
}
for (w = DBG_PAUSE; w; w--); //Long pause after number is complete
}
//Display unsigned 32-bit number through debug led
//Read as follows: 1230 = [*] [* *] [* * *] [**] (note zero is fast double flash)
#define DLED_ONTIME 1000000
#define DLED_PAUSE 1500000
volatile uint32_t w;
void dled_print(uint32_t x, uint8_t long_pause)
{
int8_t t;
@ -70,13 +83,13 @@ void dled_print(uint32_t x, uint8_t long_pause)
x -= n * p;
if (!n)
{
led_on;
DBG_LED_ON;
for (w = DLED_ONTIME / 4; w; w--);
led_off;
DBG_LED_OFF;
for (w = DLED_ONTIME / 4; w; w--);
led_on;
DBG_LED_ON;
for (w = DLED_ONTIME / 4; w; w--);
led_off;
DBG_LED_OFF;
for (w = DLED_ONTIME / 4; w; w--);
n--;
}
@ -84,9 +97,9 @@ void dled_print(uint32_t x, uint8_t long_pause)
{
while (n > 0)
{
led_on;
DBG_LED_ON;
for (w = DLED_ONTIME; w; w--);
led_off;
DBG_LED_OFF;
for (w = DLED_ONTIME / 2; w; w--);
n--;
}
@ -102,11 +115,52 @@ void dled_print(uint32_t x, uint8_t long_pause)
}
}
#ifdef DEBUG_BOOT_TRACING
#ifdef DEBUG_BOOT_TRACING_ENABLE
volatile uint32_t debug_code;
void EIC_15_Handler()
//These macros are for compile time substitution
#define DEBUG_BOOT_TRACING_EXTINTn (DEBUG_BOOT_TRACING_PIN % _U_(0x10))
#define DEBUG_BOOT_TRACING_EXTINTb (_U_(0x1) << DEBUG_BOOT_TRACING_EXTINTn)
#define DEBUG_BOOT_TRACING_CONFIG_INDn (DEBUG_BOOT_TRACING_EXTINTn / _U_(0x8))
#define DEBUG_BOOT_TRACING_CONFIG_SENSEn (DEBUG_BOOT_TRACING_EXTINTn % _U_(0x8))
#define DEBUG_BOOT_TRACING_CONFIG_SENSEb (DEBUG_BOOT_TRACING_CONFIG_SENSEn * _U_(0x4))
#define DEBUG_BOOT_TRACING_IRQn (EIC_0_IRQn + DEBUG_BOOT_TRACING_EXTINTn)
//These macros perform PORT+PIN definition translation to IRQn in the preprocessor
#define PORTPIN_TO_IRQn_EXPAND(def) def
#define PORTPIN_TO_IRQn_DEF(def) PORTPIN_TO_IRQn_EXPAND(def)
#if DEBUG_BOOT_TRACING_PIN < 10
#define PORTPIN_TO_IRQn_TODEF(port, pin) PORTPIN_TO_IRQn_DEF(PIN_ ## port ## 0 ## pin ## A_EIC_EXTINT_NUM)
#else
#define PORTPIN_TO_IRQn_TODEF(port, pin) PORTPIN_TO_IRQn_DEF(PIN_ ## port ## pin ## A_EIC_EXTINT_NUM)
#endif
#define PORTPIN_TO_IRQn(port, pin) PORTPIN_TO_IRQn_TODEF(port, pin)
//These macros perform function name output in the preprocessor
#define DEBUG_BOOT_TRACING_HANDLER_CONCAT(irq) void EIC_ ## irq ## _Handler(void)
#define DEBUG_BOOT_TRACING_HANDLER(irq) DEBUG_BOOT_TRACING_HANDLER_CONCAT(irq)
//To generate the function name of the IRQ handler catching boot tracing,
// certain macros must be undefined, so save their current values to macro stack
#pragma push_macro("PA")
#pragma push_macro("PB")
#pragma push_macro("_L_")
//Undefine / redefine pushed macros
#undef PA
#undef PB
#undef _L_
#define _L_(x) x
//Perform the work and output
//Ex: PORT PB, PIN 31 = void EIC_15_Handler(void)
DEBUG_BOOT_TRACING_HANDLER(PORTPIN_TO_IRQn(DEBUG_BOOT_TRACING_PORT, DEBUG_BOOT_TRACING_PIN))
//Restore macros
#pragma pop_macro("PA")
#pragma pop_macro("PB")
#pragma pop_macro("_L_")
{
//This is only for non-functional keyboard troubleshooting and should be disabled after boot
//Intention is to lock up the keyboard here with repeating debug led code
@ -120,13 +174,13 @@ void debug_code_init(void)
{
DBGC(DC_UNSET);
//Configure Ports for EIC on PB31
PORT->Group[1].DIRCLR.reg = 1 << 31; //Input
PORT->Group[1].OUTSET.reg = 1 << 31; //High
PORT->Group[1].PINCFG[31].bit.INEN = 1; //Input Enable
PORT->Group[1].PINCFG[31].bit.PULLEN = 1; //Pull Enable
PORT->Group[1].PINCFG[31].bit.PMUXEN = 1; //Mux Enable
PORT->Group[1].PMUX[15].bit.PMUXO = 0; //Mux A
//Configure Ports for EIC
PORT->Group[DEBUG_BOOT_TRACING_PORT].DIRCLR.reg = 1 << DEBUG_BOOT_TRACING_PIN; //Input
PORT->Group[DEBUG_BOOT_TRACING_PORT].OUTSET.reg = 1 << DEBUG_BOOT_TRACING_PIN; //High
PORT->Group[DEBUG_BOOT_TRACING_PORT].PINCFG[DEBUG_BOOT_TRACING_PIN].bit.INEN = 1; //Input Enable
PORT->Group[DEBUG_BOOT_TRACING_PORT].PINCFG[DEBUG_BOOT_TRACING_PIN].bit.PULLEN = 1; //Pull Enable
PORT->Group[DEBUG_BOOT_TRACING_PORT].PINCFG[DEBUG_BOOT_TRACING_PIN].bit.PMUXEN = 1; //Mux Enable
PORT->Group[DEBUG_BOOT_TRACING_PORT].PMUX[DEBUG_BOOT_TRACING_PIN / 2].bit.PMUXO = 0; //Mux A
//Enable CLK_EIC_APB
MCLK->APBAMASK.bit.EIC_ = 1;
@ -134,25 +188,33 @@ void debug_code_init(void)
//Configure EIC
EIC->CTRLA.bit.SWRST = 1;
while (EIC->SYNCBUSY.bit.SWRST) {}
EIC->ASYNCH.reg = 1 << 15;
EIC->INTENSET.reg = 1 << 15;
EIC->CONFIG[1].bit.SENSE7 = 2;
EIC->ASYNCH.reg = DEBUG_BOOT_TRACING_EXTINTb;
EIC->INTENSET.reg = DEBUG_BOOT_TRACING_EXTINTb;
EIC->CONFIG[DEBUG_BOOT_TRACING_CONFIG_INDn].reg |= (EIC_CONFIG_SENSE0_FALL_Val << DEBUG_BOOT_TRACING_CONFIG_SENSEb);
EIC->CTRLA.bit.ENABLE = 1;
while (EIC->SYNCBUSY.bit.ENABLE) {}
//Enable EIC IRQ
NVIC_EnableIRQ(EIC_15_IRQn);
NVIC_EnableIRQ(DEBUG_BOOT_TRACING_IRQn);
}
void debug_code_disable(void)
{
//Disable EIC IRQ
NVIC_DisableIRQ(EIC_15_IRQn);
NVIC_DisableIRQ(DEBUG_BOOT_TRACING_IRQn);
//Disable EIC
EIC->CTRLA.bit.ENABLE = 0;
while (EIC->SYNCBUSY.bit.ENABLE) {}
//Default port configuration
PORT->Group[DEBUG_BOOT_TRACING_PORT].DIRCLR.reg = 1 << DEBUG_BOOT_TRACING_PIN; //Input
PORT->Group[DEBUG_BOOT_TRACING_PORT].OUTCLR.reg = 1 << DEBUG_BOOT_TRACING_PIN; //Low
PORT->Group[DEBUG_BOOT_TRACING_PORT].PINCFG[DEBUG_BOOT_TRACING_PIN].bit.INEN = 0; //Input Disable
PORT->Group[DEBUG_BOOT_TRACING_PORT].PINCFG[DEBUG_BOOT_TRACING_PIN].bit.PULLEN = 0; //Pull Disable
PORT->Group[DEBUG_BOOT_TRACING_PORT].PINCFG[DEBUG_BOOT_TRACING_PIN].bit.PMUXEN = 0; //Mux Disable
PORT->Group[DEBUG_BOOT_TRACING_PORT].PMUX[DEBUG_BOOT_TRACING_PIN / 2].bit.PMUXO = 0; //Mux A
//Disable CLK_EIC_APB
MCLK->APBAMASK.bit.EIC_ = 0;
}
@ -162,4 +224,4 @@ void debug_code_disable(void)
void debug_code_init(void) {}
void debug_code_disable(void) {}
#endif //DEBUG_BOOT_TRACING
#endif //DEBUG_BOOT_TRACING_ENABLE

74
tmk_core/protocol/arm_atsam/d51_util.h
View File

@ -20,37 +20,65 @@ along with this program. If not, see <http://www.gnu.org/licenses/>.
#include "samd51j18a.h"
//TODO: PS: Should bring these ports out to keyboard level configuration
/* Debug LED */
#if DEBUG_LED_ENABLE == 1
#define DBG_LED_ENA PORT->Group[DEBUG_LED_PORT].DIRSET.reg = (1 << DEBUG_LED_PIN)
#define DBG_LED_DIS PORT->Group[DEBUG_LED_PORT].DIRCLR.reg = (1 << DEBUG_LED_PIN)
#define DBG_LED_ON PORT->Group[DEBUG_LED_PORT].OUTSET.reg = (1 << DEBUG_LED_PIN)
#define DBG_LED_OFF PORT->Group[DEBUG_LED_PORT].OUTCLR.reg = (1 << DEBUG_LED_PIN)
#else
#define DBG_LED_ENA
#define DBG_LED_DIS
#define DBG_LED_ON
#define DBG_LED_OFF
#endif
//Debug LED PA27
#define led_ena REG_PORT_DIRSET0 = 0x08000000 //PA27 Output
#define led_on REG_PORT_OUTSET0 = 0x08000000 //PA27 High
#define led_off REG_PORT_OUTCLR0 = 0x08000000 //PA27 Low
/* Debug Port 1 */
#if DEBUG_PORT1_ENABLE == 1
#define DBG_1_ENA PORT->Group[DEBUG_PORT1_PORT].DIRSET.reg = (1 << DEBUG_PORT1_PIN)
#define DBG_1_DIS PORT->Group[DEBUG_PORT1_PORT].DIRCLR.reg = (1 << DEBUG_PORT1_PIN)
#define DBG_1_ON PORT->Group[DEBUG_PORT1_PORT].OUTSET.reg = (1 << DEBUG_PORT1_PIN)
#define DBG_1_OFF PORT->Group[DEBUG_PORT1_PORT].OUTCLR.reg = (1 << DEBUG_PORT1_PIN)
#else
#define DBG_1_ENA
#define DBG_1_DIS
#define DBG_1_ON
#define DBG_1_OFF
#endif
//Debug Port PB30
#define m15_ena REG_PORT_DIRSET1 = 0x40000000 //PB30 Output
#define m15_on REG_PORT_OUTSET1 = 0x40000000 //PB30 High
#define m15_off REG_PORT_OUTCLR1 = 0x40000000 //PB30 Low
/* Debug Port 2 */
#if DEBUG_PORT2_ENABLE == 1
#define DBG_2_ENA PORT->Group[DEBUG_PORT2_PORT].DIRSET.reg = (1 << DEBUG_PORT2_PIN)
#define DBG_2_DIS PORT->Group[DEBUG_PORT2_PORT].DIRCLR.reg = (1 << DEBUG_PORT2_PIN)
#define DBG_2_ON PORT->Group[DEBUG_PORT2_PORT].OUTSET.reg = (1 << DEBUG_PORT2_PIN)
#define DBG_2_OFF PORT->Group[DEBUG_PORT2_PORT].OUTCLR.reg = (1 << DEBUG_PORT2_PIN)
#else
#define DBG_2_ENA
#define DBG_2_DIS
#define DBG_2_ON
#define DBG_2_OFF
#endif
//Debug Port PB23
#define m27_ena REG_PORT_DIRSET1 = 0x800000 //PB23 Output
#define m27_on REG_PORT_OUTSET1 = 0x800000 //PB23 High
#define m27_off REG_PORT_OUTCLR1 = 0x800000 //PB23 Low
/* Debug Port 3 */
#if DEBUG_PORT3_ENABLE == 1
#define DBG_3_ENA PORT->Group[DEBUG_PORT3_PORT].DIRSET.reg = (1 << DEBUG_PORT3_PIN)
#define DBG_3_DIS PORT->Group[DEBUG_PORT3_PORT].DIRCLR.reg = (1 << DEBUG_PORT3_PIN)
#define DBG_3_ON PORT->Group[DEBUG_PORT3_PORT].OUTSET.reg = (1 << DEBUG_PORT3_PIN)
#define DBG_3_OFF PORT->Group[DEBUG_PORT3_PORT].OUTCLR.reg = (1 << DEBUG_PORT3_PIN)
#else
#define DBG_3_ENA
#define DBG_3_DIS
#define DBG_3_ON
#define DBG_3_OFF
#endif
//Debug Port PB31
#define m28_ena REG_PORT_DIRSET1 = 0x80000000 //PB31 Output
#define m28_on REG_PORT_OUTSET1 = 0x80000000 //PB31 High
#define m28_off REG_PORT_OUTCLR1 = 0x80000000 //PB31 Low
#define m15_loop(M15X) {uint8_t M15L=M15X; while(M15L--){m15_on;CLK_delay_us(1);m15_off;}}
void m15_print(uint32_t x);
void dbg_print(uint32_t x);
void dled_print(uint32_t x, uint8_t long_pause);
void debug_code_init(void);
void debug_code_disable(void);
#ifdef DEBUG_BOOT_TRACING
#ifdef DEBUG_BOOT_TRACING_ENABLE
#define DBGC(n) debug_code = n
@ -190,6 +218,6 @@ enum debug_code_list {
#define DBGC(n) {}
#endif //DEBUG_BOOT_TRACING
#endif //DEBUG_BOOT_TRACING_ENABLE
#endif //_D51_UTIL_H_

10
tmk_core/protocol/arm_atsam/i2c_master.c
View File

@ -267,8 +267,8 @@ uint8_t I2C3733_Init_Control(void)
CLK_delay_ms(1);
srdata.bit.IRST = 0;
SPI_WriteSRData();
sr_exp_data.bit.IRST = 0;
SR_EXP_WriteData();
CLK_delay_ms(1);
@ -357,8 +357,8 @@ void I2C3733_Control_Set(uint8_t state)
{
DBGC(DC_I2C3733_CONTROL_SET_BEGIN);
srdata.bit.SDB_N = (state == 1 ? 1 : 0);
SPI_WriteSRData();
sr_exp_data.bit.SDB_N = (state == 1 ? 1 : 0);
SR_EXP_WriteData();
DBGC(DC_I2C3733_CONTROL_SET_COMPLETE);
}
@ -489,7 +489,7 @@ uint8_t i2c_led_q_request_room(uint8_t request_size)
if (i2c_led_q_full >= 100) //Give the queue a chance to clear up
{
led_on;
DBG_LED_ON;
I2C_DMAC_LED_Init();
i2c_led_q_init();
return 1;

4
tmk_core/protocol/arm_atsam/led_matrix.c
View File

@ -520,9 +520,9 @@ void led_matrix_task(void)
//Process more data if not finished
if (led_cur != lede)
{
//m15_off; //debug profiling
//DBG_1_OFF; //debug profiling
led_matrix_run();
//m15_on; //debug profiling
//DBG_1_ON; //debug profiling
}
}

14
tmk_core/protocol/arm_atsam/main_arm_atsam.c
View File

@ -247,8 +247,13 @@ void main_subtasks(void)
int main(void)
{
led_ena;
m15_ena;
DBG_LED_ENA;
DBG_1_ENA;
DBG_1_OFF;
DBG_2_ENA;
DBG_2_OFF;
DBG_3_ENA;
DBG_3_OFF;
debug_code_init();
@ -256,7 +261,7 @@ int main(void)
ADC0_init();
SPI_Init();
SR_EXP_Init();
i2c1_init();
@ -274,8 +279,7 @@ int main(void)
while (USB2422_Port_Detect_Init() == 0) {}
led_off;
m15_off;
DBG_LED_OFF;
led_matrix_init();

95
tmk_core/protocol/arm_atsam/spi.c
View File

@ -17,73 +17,70 @@ along with this program. If not, see <http://www.gnu.org/licenses/>.
#include "arm_atsam_protocol.h"
Srdata_t srdata;
sr_exp_t sr_exp_data;
void SPI_WriteSRData(void)
void SR_EXP_WriteData(void)
{
uint16_t timeout;
SR_EXP_RCLK_LO;
SC2_RCLCK_LO;
while (!(SR_EXP_SERCOM->SPI.INTFLAG.bit.DRE)) { DBGC(DC_SPI_WRITE_DRE); }
timeout = 50000;
while (!(SCSPI->SPI.INTFLAG.bit.DRE) && --timeout) { DBGC(DC_SPI_WRITE_DRE); }
SR_EXP_SERCOM->SPI.DATA.bit.DATA = sr_exp_data.reg & 0xFF; //Shift in bits 7-0
while (!(SR_EXP_SERCOM->SPI.INTFLAG.bit.TXC)) { DBGC(DC_SPI_WRITE_TXC_1); }
SCSPI->SPI.DATA.bit.DATA = srdata.reg & 0xFF; //Shift in bits 7-0
timeout = 50000;
while (!(SCSPI->SPI.INTFLAG.bit.TXC) && --timeout) { DBGC(DC_SPI_WRITE_TXC_1); }
SR_EXP_SERCOM->SPI.DATA.bit.DATA = (sr_exp_data.reg >> 8) & 0xFF; //Shift in bits 15-8
while (!(SR_EXP_SERCOM->SPI.INTFLAG.bit.TXC)) { DBGC(DC_SPI_WRITE_TXC_2); }
SCSPI->SPI.DATA.bit.DATA = (srdata.reg >> 8) & 0xFF; //Shift in bits 15-8
timeout = 50000;
while (!(SCSPI->SPI.INTFLAG.bit.TXC) && --timeout) { DBGC(DC_SPI_WRITE_TXC_2); }
SC2_RCLCK_HI;
SR_EXP_RCLK_HI;
}
void SPI_Init(void)
void SR_EXP_Init(void)
{
uint32_t timeout;
DBGC(DC_SPI_INIT_BEGIN);
CLK_set_spi_freq(CHAN_SERCOM_SPI, FREQ_SPI_DEFAULT);
PORT->Group[0].PMUX[6].bit.PMUXE = 2;
PORT->Group[0].PMUX[6].bit.PMUXO = 2;
PORT->Group[0].PINCFG[12].bit.PMUXEN = 1;
PORT->Group[0].PINCFG[13].bit.PMUXEN = 1;
//Set up MCU Shift Register pins
PORT->Group[SR_EXP_RCLK_PORT].DIRSET.reg = (1 << SR_EXP_RCLK_PIN);
PORT->Group[SR_EXP_OE_N_PORT].DIRSET.reg = (1 << SR_EXP_OE_N_PIN);
//Set up MCU SPI pins
PORT->Group[SR_EXP_DATAOUT_PORT].PMUX[SR_EXP_DATAOUT_PIN / 2].bit.SR_EXP_DATAOUT_MUX_SEL = SR_EXP_DATAOUT_MUX; //MUX select for sercom
PORT->Group[SR_EXP_SCLK_PORT].PMUX[SR_EXP_SCLK_PIN / 2].bit.SR_EXP_SCLK_MUX_SEL = SR_EXP_SCLK_MUX; //MUX select for sercom
PORT->Group[SR_EXP_DATAOUT_PORT].PINCFG[SR_EXP_DATAOUT_PIN].bit.PMUXEN = 1; //MUX Enable
PORT->Group[SR_EXP_SCLK_PORT].PINCFG[SR_EXP_SCLK_PIN].bit.PMUXEN = 1; //MUX Enable
//Configure Shift Registers
SC2_DIRSET;
SC2_RCLCK_HI;
SC2_OE_DIS;
//Initialize Shift Register
SR_EXP_OE_N_DIS;
SR_EXP_RCLK_HI;
SCSPI->SPI.CTRLA.bit.DORD = 1;
SCSPI->SPI.CTRLA.bit.CPOL = 1;
SCSPI->SPI.CTRLA.bit.CPHA = 1;
SCSPI->SPI.CTRLA.bit.DIPO = 3;
SCSPI->SPI.CTRLA.bit.MODE = 3; //master
SR_EXP_SERCOM->SPI.CTRLA.bit.DORD = 1; //Data Order - LSB is transferred first
SR_EXP_SERCOM->SPI.CTRLA.bit.CPOL = 1; //Clock Polarity - SCK high when idle. Leading edge of cycle is falling. Trailing rising.
SR_EXP_SERCOM->SPI.CTRLA.bit.CPHA = 1; //Clock Phase - Leading Edge Falling, change, Trailing Edge - Rising, sample
SR_EXP_SERCOM->SPI.CTRLA.bit.DIPO = 3; //Data In Pinout - SERCOM PAD[3] is used as data input (Configure away from DOPO. Not using input.)
SR_EXP_SERCOM->SPI.CTRLA.bit.DOPO = 0; //Data Output PAD[0], Serial Clock PAD[1]
SR_EXP_SERCOM->SPI.CTRLA.bit.MODE = 3; //Operating Mode - Master operation
SCSPI->SPI.CTRLA.bit.ENABLE = 1;
timeout = 50000;
while (SCSPI->SPI.SYNCBUSY.bit.ENABLE && timeout--) { DBGC(DC_SPI_SYNC_ENABLING); }
SR_EXP_SERCOM->SPI.CTRLA.bit.ENABLE = 1; //Enable - Peripheral is enabled or being enabled
while (SR_EXP_SERCOM->SPI.SYNCBUSY.bit.ENABLE) { DBGC(DC_SPI_SYNC_ENABLING); }
srdata.reg = 0;
srdata.bit.HUB_CONNECT = 0;
srdata.bit.HUB_RESET_N = 0;
srdata.bit.S_UP = 0;
srdata.bit.E_UP_N = 1;
srdata.bit.S_DN1 = 1;
srdata.bit.E_DN1_N = 1;
srdata.bit.E_VBUS_1 = 0;
srdata.bit.E_VBUS_2 = 0;
srdata.bit.SRC_1 = 1;
srdata.bit.SRC_2 = 1;
srdata.bit.IRST = 1;
srdata.bit.SDB_N = 0;
SPI_WriteSRData();
sr_exp_data.reg = 0;
sr_exp_data.bit.HUB_CONNECT = 0;
sr_exp_data.bit.HUB_RESET_N = 0;
sr_exp_data.bit.S_UP = 0;
sr_exp_data.bit.E_UP_N = 1;
sr_exp_data.bit.S_DN1 = 1;
sr_exp_data.bit.E_DN1_N = 1;
sr_exp_data.bit.E_VBUS_1 = 0;
sr_exp_data.bit.E_VBUS_2 = 0;
sr_exp_data.bit.SRC_1 = 1;
sr_exp_data.bit.SRC_2 = 1;
sr_exp_data.bit.IRST = 1;
sr_exp_data.bit.SDB_N = 0;
SR_EXP_WriteData();
//Enable register output
SC2_OE_ENA;
//Enable Shift Register output
SR_EXP_OE_N_ENA;
DBGC(DC_SPI_INIT_COMPLETE);
}

39
tmk_core/protocol/arm_atsam/spi.h
View File

@ -18,21 +18,28 @@ along with this program. If not, see <http://www.gnu.org/licenses/>.
#ifndef _SPI_H_
#define _SPI_H_
//TODO: PS: Should bring ports to keyboard configuration
/* Macros for Shift Register control */
#define SR_EXP_RCLK_LO PORT->Group[SR_EXP_RCLK_PORT].OUTCLR.reg = (1 << SR_EXP_RCLK_PIN)
#define SR_EXP_RCLK_HI PORT->Group[SR_EXP_RCLK_PORT].OUTSET.reg = (1 << SR_EXP_RCLK_PIN)
#define SR_EXP_OE_N_ENA PORT->Group[SR_EXP_OE_N_PORT].OUTCLR.reg = (1 << SR_EXP_OE_N_PIN)
#define SR_EXP_OE_N_DIS PORT->Group[SR_EXP_OE_N_PORT].OUTSET.reg = (1 << SR_EXP_OE_N_PIN)
#define SCSPI SERCOM2
/* Determine bits to set for mux selection */
#if SR_EXP_DATAOUT_PIN % 2 == 0
#define SR_EXP_DATAOUT_MUX_SEL PMUXE
#else
#define SR_EXP_DATAOUT_MUX_SEL PMUXO
#endif
#define P14_DIR 0x00004000 /* PIN14 DIR Bit */
#define P14_OUT 0x00004000 /* PIN14 OUT Bit */
#define P15_DIR 0x00008000 /* PIN15 DIR Bit */
#define P15_OUT 0x00008000 /* PIN15 OUT Bit */
#define SC2_RCLCK_LO REG_PORT_OUTCLR1 = P14_OUT /* PB14 Low, SC2_RCLCK Low */
#define SC2_RCLCK_HI REG_PORT_OUTSET1 = P14_OUT /* PB14 High, SC2_RCLCK High */
#define SC2_OE_ENA REG_PORT_OUTCLR1 = P15_OUT /* PB15 Low, SC2_OE_N Low (Shift register enabled) */
#define SC2_OE_DIS REG_PORT_OUTSET1 = P15_OUT /* PB15 High, SC2_OE_N High (Shift register disabled) */
#define SC2_DIRSET REG_PORT_DIRSET1 = P14_DIR | P15_DIR; /* PB14 PB15 OUT */
/* Determine bits to set for mux selection */
#if SR_EXP_SCLK_PIN % 2 == 0
#define SR_EXP_SCLK_MUX_SEL PMUXE
#else
#define SR_EXP_SCLK_MUX_SEL PMUXO
#endif
/* Data structure to define Shift Register output expander hardware */
/* This structure gets shifted into registers LSB first */
typedef union {
struct {
uint16_t RSVD4:1; /*!< bit: 0 */
@ -53,11 +60,11 @@ typedef union {
uint16_t HUB_CONNECT:1; /*!< bit: 15 SIGNAL VBUS CONNECT TO USB HUB WHEN 1 */
} bit; /*!< Structure used for bit access */
uint16_t reg; /*!< Type used for register access */
} Srdata_t;
} sr_exp_t;
extern Srdata_t srdata;
extern sr_exp_t sr_exp_data;
void SPI_WriteSRData(void);
void SPI_Init(void);
void SR_EXP_WriteData(void);
void SR_EXP_Init(void);
#endif //_SPI_H_

85
tmk_core/protocol/arm_atsam/usb/usb2422.c
View File

@ -77,7 +77,6 @@ void USB2422_init(void)
Port *pport = PORT;
Oscctrl *posc = OSCCTRL;
Usb *pusb = USB;
Srdata_t *pspi = &srdata;
DBGC(DC_USB2422_INIT_BEGIN);
@ -132,9 +131,9 @@ void USB2422_init(void)
i2c0_init(); //IC2 clk must be high at USB2422 reset release time to signal SMB configuration
pspi->bit.HUB_CONNECT = 1; //connect signal
pspi->bit.HUB_RESET_N = 1; //reset high
SPI_WriteSRData();
sr_exp_data.bit.HUB_CONNECT = 1; //connect signal
sr_exp_data.bit.HUB_RESET_N = 1; //reset high
SR_EXP_WriteData();
CLK_delay_us(100);
@ -150,16 +149,14 @@ void USB2422_init(void)
void USB_reset(void)
{
Srdata_t *pspi = &srdata;
DBGC(DC_USB_RESET_BEGIN);
//pulse reset for at least 1 usec
pspi->bit.HUB_RESET_N = 0; //reset low
SPI_WriteSRData();
sr_exp_data.bit.HUB_RESET_N = 0; //reset low
SR_EXP_WriteData();
CLK_delay_us(1);
pspi->bit.HUB_RESET_N = 1; //reset high to run
SPI_WriteSRData();
sr_exp_data.bit.HUB_RESET_N = 1; //reset high to run
SR_EXP_WriteData();
CLK_delay_us(1);
DBGC(DC_USB_RESET_COMPLETE);
@ -241,14 +238,14 @@ void USB_set_host_by_voltage(void)
#ifndef MD_BOOTLOADER
usb_extra_state = USB_EXTRA_STATE_UNKNOWN;
#endif //MD_BOOTLOADER
srdata.bit.SRC_1 = 1; //USBC-1 available for test
srdata.bit.SRC_2 = 1; //USBC-2 available for test
srdata.bit.E_UP_N = 1; //HOST disable
srdata.bit.E_DN1_N = 1; //EXTRA disable
srdata.bit.E_VBUS_1 = 0; //USBC-1 disable full power I/O
srdata.bit.E_VBUS_2 = 0; //USBC-2 disable full power I/O
sr_exp_data.bit.SRC_1 = 1; //USBC-1 available for test
sr_exp_data.bit.SRC_2 = 1; //USBC-2 available for test
sr_exp_data.bit.E_UP_N = 1; //HOST disable
sr_exp_data.bit.E_DN1_N = 1; //EXTRA disable
sr_exp_data.bit.E_VBUS_1 = 0; //USBC-1 disable full power I/O
sr_exp_data.bit.E_VBUS_2 = 0; //USBC-2 disable full power I/O
SPI_WriteSRData();
SR_EXP_WriteData();
CLK_delay_ms(250);
@ -262,37 +259,37 @@ void USB_set_host_by_voltage(void)
if (v_con_1 > v_con_2)
{
srdata.bit.S_UP = 0; //HOST to USBC-1
srdata.bit.S_DN1 = 1; //EXTRA to USBC-2
srdata.bit.SRC_1 = 1; //HOST on USBC-1
srdata.bit.SRC_2 = 0; //EXTRA available on USBC-2
sr_exp_data.bit.S_UP = 0; //HOST to USBC-1
sr_exp_data.bit.S_DN1 = 1; //EXTRA to USBC-2
sr_exp_data.bit.SRC_1 = 1; //HOST on USBC-1
sr_exp_data.bit.SRC_2 = 0; //EXTRA available on USBC-2
srdata.bit.E_VBUS_1 = 1; //USBC-1 enable full power I/O
srdata.bit.E_VBUS_2 = 0; //USBC-2 disable full power I/O
sr_exp_data.bit.E_VBUS_1 = 1; //USBC-1 enable full power I/O
sr_exp_data.bit.E_VBUS_2 = 0; //USBC-2 disable full power I/O
SPI_WriteSRData();
SR_EXP_WriteData();
srdata.bit.E_UP_N = 0; //HOST enable
sr_exp_data.bit.E_UP_N = 0; //HOST enable
SPI_WriteSRData();
SR_EXP_WriteData();
usb_host_port = USB_HOST_PORT_1;
}
else
{
srdata.bit.S_UP = 1; //EXTRA to USBC-1
srdata.bit.S_DN1 = 0; //HOST to USBC-2
srdata.bit.SRC_1 = 0; //EXTRA available on USBC-1
srdata.bit.SRC_2 = 1; //HOST on USBC-2
sr_exp_data.bit.S_UP = 1; //EXTRA to USBC-1
sr_exp_data.bit.S_DN1 = 0; //HOST to USBC-2
sr_exp_data.bit.SRC_1 = 0; //EXTRA available on USBC-1
sr_exp_data.bit.SRC_2 = 1; //HOST on USBC-2
srdata.bit.E_VBUS_1 = 0; //USBC-1 disable full power I/O
srdata.bit.E_VBUS_2 = 1; //USBC-2 enable full power I/O
sr_exp_data.bit.E_VBUS_1 = 0; //USBC-1 disable full power I/O
sr_exp_data.bit.E_VBUS_2 = 1; //USBC-2 enable full power I/O
SPI_WriteSRData();
SR_EXP_WriteData();
srdata.bit.E_UP_N = 0; //HOST enable
sr_exp_data.bit.E_UP_N = 0; //HOST enable
SPI_WriteSRData();
SR_EXP_WriteData();
usb_host_port = USB_HOST_PORT_2;
}
@ -325,15 +322,15 @@ uint8_t USB2422_Port_Detect_Init(void)
if (v_con_1 > v_con_2) //Values updated from USB_set_host_by_voltage();
{
//1 flash for port 1 detected
if (tmod > 500 && tmod < 600) { led_on; }
else { led_off; }
if (tmod > 500 && tmod < 600) { DBG_LED_ON; }
else { DBG_LED_OFF; }
}
else if (v_con_2 > v_con_1) //Values updated from USB_set_host_by_voltage();
{
//2 flash for port 2 detected
if (tmod > 500 && tmod < 600) { led_on; }
else if (tmod > 700 && tmod < 800) { led_on; }
else { led_off; }
if (tmod > 500 && tmod < 600) { DBG_LED_ON; }
else if (tmod > 700 && tmod < 800) { DBG_LED_ON; }
else { DBG_LED_OFF; }
}
if (CLK_get_ms() > port_detect_retry_ms)
@ -357,12 +354,12 @@ void USB_ExtraSetState(uint8_t state)
if (state == USB_EXTRA_STATE_DISABLED_UNTIL_REPLUG)
state = USB_EXTRA_STATE_DISABLED;
if (usb_host_port == USB_HOST_PORT_1) srdata.bit.E_VBUS_2 = state;
else if (usb_host_port == USB_HOST_PORT_2) srdata.bit.E_VBUS_1 = state;
if (usb_host_port == USB_HOST_PORT_1) sr_exp_data.bit.E_VBUS_2 = state;
else if (usb_host_port == USB_HOST_PORT_2) sr_exp_data.bit.E_VBUS_1 = state;
else return;
srdata.bit.E_DN1_N = !state;
SPI_WriteSRData();
sr_exp_data.bit.E_DN1_N = !state;
SR_EXP_WriteData();
usb_extra_state = state_save;