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4aad65c3dcd736d53ccd9ceb87a8b4dd9e60c5c3
zSoft/startup/mk20dx128.c
Philip Smart 4aad65c3dc Further updates during tranZPUter SW dev
2020-06-03 00:39:12 +01:00

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/* Teensyduino Core Library
* http://www.pjrc.com/teensy/
* Copyright (c) 2017 PJRC.COM, LLC.
*
* Permission is hereby granted, free of charge, to any person obtaining
* a copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* 1. The above copyright notice and this permission notice shall be
* included in all copies or substantial portions of the Software.
*
* 2. If the Software is incorporated into a build system that allows
* selection among a list of target devices, then similar target
* devices manufactured by PJRC.COM must be included in the list of
* target devices and selectable in the same manner.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
* BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
* ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#include <stdio.h>
#include "kinetis.h"
#include "core_pins.h" // testing only
#include "ser_print.h" // testing only
#include "usb_serial.h"
#include "usb_ser_print.h" // testing only
#include <errno.h>
#if defined __TRANZPUTER__
//#define FRESULT uint8_t
#include <ff.h>
#include <tranzputer.h>
#endif
// Flash Security Setting. On Teensy 3.2, you can lock the MK20 chip to prevent
// anyone from reading your code. You CAN still reprogram your Teensy while
// security is set, but the bootloader will be unable to respond to auto-reboot
// requests from Arduino. Pressing the program button will cause a full chip
// erase to gain access, because the bootloader chip is locked out. Normally,
// erase occurs when uploading begins, so if you press the Program button
// accidentally, simply power cycling will run your program again. When
// security is locked, any Program button press causes immediate full erase.
// Special care must be used with the Program button, because it must be made
// accessible to initiate reprogramming, but it must not be accidentally
// pressed when Teensy Loader is not being used to reprogram. To set lock the
// security change this to 0xDC. Teensy 3.0 and 3.1 do not support security lock.
#define FSEC 0xDE
// Flash Options
#define FOPT 0xF9
extern unsigned long _stext;
extern unsigned long _etext;
extern unsigned long _sdata;
extern unsigned long _edata;
extern unsigned long _sbss;
extern unsigned long _ebss;
extern unsigned long _estack;
//extern void __init_array_start(void);
//extern void __init_array_end(void);
extern int main (void);
void ResetHandler(void);
void _init_Teensyduino_internal_(void) __attribute__((noinline));
void __libc_init_array(void);
static int fault_id = 0;
void fault_isr(void)
{
fault_id = 0;
__asm volatile
(
" tst lr, #4 \n"
" ite eq \n"
" mrseq r0, msp \n"
" mrsne r0, psp \n"
" ldr r1, [r0, #24] \n"
" ldr r2, handler0_address_const \n"
" bx r2 \n"
" handler0_address_const: .word prvGetRegistersFromStack \n"
);
}
void hard_fault_isr(void)
{
fault_id = 1;
__asm volatile
(
" tst lr, #4 \n"
" ite eq \n"
" mrseq r0, msp \n"
" mrsne r0, psp \n"
" ldr r1, [r0, #24] \n"
" ldr r2, handler1_address_const \n"
" bx r2 \n"
" handler1_address_const: .word prvGetRegistersFromStack \n"
);
}
void bus_fault_isr(void)
{
fault_id = 2;
__asm volatile
(
" tst lr, #4 \n"
" ite eq \n"
" mrseq r0, msp \n"
" mrsne r0, psp \n"
" ldr r1, [r0, #24] \n"
" ldr r2, handler2_address_const \n"
" bx r2 \n"
" handler2_address_const: .word prvGetRegistersFromStack \n"
);
}
void memmanage_fault_isr(void)
{
fault_id = 3;
__asm volatile
(
" tst lr, #4 \n"
" ite eq \n"
" mrseq r0, msp \n"
" mrsne r0, psp \n"
" ldr r1, [r0, #24] \n"
" ldr r2, handler3_address_const \n"
" bx r2 \n"
" handler3_address_const: .word prvGetRegistersFromStack \n"
);
}
void usage_fault_isr(void)
{
fault_id = 4;
__asm volatile
(
" tst lr, #4 \n"
" ite eq \n"
" mrseq r0, msp \n"
" mrsne r0, psp \n"
" ldr r1, [r0, #24] \n"
" ldr r2, handler4_address_const \n"
" bx r2 \n"
" handler4_address_const: .word prvGetRegistersFromStack \n"
);
}
void prvGetRegistersFromStack( uint32_t *pulFaultStackAddress )
{
volatile uint32_t r0;
volatile uint32_t r1;
volatile uint32_t r2;
volatile uint32_t r3;
volatile uint32_t r12;
volatile uint32_t lr; /* Link register. */
volatile uint32_t pc; /* Program counter. */
volatile uint32_t psr;/* Program status register. */
r0 = pulFaultStackAddress[ 0 ];
r1 = pulFaultStackAddress[ 1 ];
r2 = pulFaultStackAddress[ 2 ];
r3 = pulFaultStackAddress[ 3 ];
r12 = pulFaultStackAddress[ 4 ];
lr = pulFaultStackAddress[ 5 ];
pc = pulFaultStackAddress[ 6 ];
psr = pulFaultStackAddress[ 7 ];
puts("\n");
switch(fault_id)
{
case 1:
puts("HARD FAULT");
break;
case 2:
puts("BUS FAULT");
break;
case 3:
puts("MEMORY MANAGEMENT FAULT");
break;
case 4:
puts("USAGE FAULT");
break;
default:
puts("UNKNOWN FAULT");
break;
}
puts("\nRegister values at time of fault:");
printf(" R0 : 0x%08lx", r0);
printf(" R1 : 0x%08lx", r1);
printf(" R2 : 0x%08lx", r2);
printf(" R3 : 0x%08lx\n", r3);
printf(" R12 : 0x%08lx", r12);
printf(" LR : 0x%08lx", lr);
printf(" PC : 0x%08lx", pc);
printf(" PSR : 0x%08lx", psr);
printf(" SP : 0x%08lx\n", *pulFaultStackAddress);
printf(" CFSR : 0x%08lx", (*((volatile unsigned long *)(0xE000ED28))));
printf(" UFSR : 0x%08lx", (*((volatile unsigned long *)(0xE000ED2A))));
printf(" HFSR : 0x%08lx", (*((volatile unsigned long *)(0xE000ED2C))));
printf(" DFSR : 0x%08lx", (*((volatile unsigned long *)(0xE000ED30))));
printf(" BFAR : 0x%08lx\n", (*((volatile unsigned long *)(0xE000ED38))));
printf(" CCR : 0x%08lx", (*((volatile unsigned long *)(0xE000ED14))));
printf(" AFSR : 0x%08lx\n", (*((volatile unsigned long *)(0xE000ED3C))));
puts("\n");
uint32_t pnt = (uint32_t)pulFaultStackAddress - 0x200;
uint32_t pntEnd = (uint32_t)pulFaultStackAddress + 0x200;
uint32_t i = 0;
char c = 0;
puts("Stack contents:");
while (1)
{
printf("%08lX", pnt);
printf(": ");
if (SIM_SCGC4 & SIM_SCGC4_USBOTG) usb_isr();
// print hexadecimal data
for (i=0; i < 32; )
{
if(pnt+i < 0x20030000)
printf("%02X", *(uint8_t *)(pnt+i));
else
printf(" ");
i++;
putchar((char)' ');
if (SIM_SCGC4 & SIM_SCGC4_USBOTG) usb_isr();
}
// print ascii data
printf(" |");
// print single ascii char
for (i=0; i < 32; i++)
{
c = (char)*(uint8_t *)(pnt+i);
if ((pnt+i < 0x20030000) && (c >= ' ') && (c <= '~'))
putchar((char)c);
else
putchar((char)' ');
if (SIM_SCGC4 & SIM_SCGC4_USBOTG) usb_isr();
}
puts("|");
// Move on one row.
pnt += 32;
// End of buffer or RAM, exit the loop.
if(pnt >= pntEnd || pnt >= (0x20030000 - 32))
{
break;
}
}
/* When the following line is hit, the variables contain the register values. */
r0 = 0;
while (1)
{
// keep polling some communication while in fault
// mode, so we don't completely die.
if (SIM_SCGC4 & SIM_SCGC4_USBOTG) usb_isr();
if (SIM_SCGC4 & SIM_SCGC4_UART0) uart0_status_isr();
if (SIM_SCGC4 & SIM_SCGC4_UART1) uart1_status_isr();
if (SIM_SCGC4 & SIM_SCGC4_UART2) uart2_status_isr();
if(++r0 > 1000000)
{
//init_pins();
// __enable_irq();
// _init_Teensyduino_internal_();
// __libc_init_array();
//
// startup_late_hook();
// main();
}
}
for( ;; );
}
//void fault_isr(void)
//{
// uint32_t addr;
//
// SIM_SCGC4 |= 0x00000400;
// UART0_BDH = 0;
// UART0_BDL = 26; // 115200 at 48 MHz
// UART0_C2 = UART_C2_TE;
// PORTB_PCR17 = PORT_PCR_MUX(3);
// usb_ser_print("\nfault: \n??: ");
// asm("ldr %0, [sp, #52]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\n??: ");
// asm("ldr %0, [sp, #48]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\n??: ");
// asm("ldr %0, [sp, #44]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\npsr:");
// asm("ldr %0, [sp, #40]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\nadr:");
// asm("ldr %0, [sp, #36]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\nlr: ");
// asm("ldr %0, [sp, #32]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\nr12:");
// asm("ldr %0, [sp, #28]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\nr3: ");
// asm("ldr %0, [sp, #24]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\nr2: ");
// asm("ldr %0, [sp, #20]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\nr1: ");
// asm("ldr %0, [sp, #16]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\nr0: ");
// asm("ldr %0, [sp, #12]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\nr4: ");
// asm("ldr %0, [sp, #8]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\nlr: ");
// asm("ldr %0, [sp, #4]" : "=r" (addr) ::);
// usb_ser_print_hex32(addr);
// usb_ser_print("\n");
// asm("ldr %0, [sp, #0]" : "=r" (addr) ::);
//
// while (1) {
// // keep polling some communication while in fault
// // mode, so we don't completely die.
// if (SIM_SCGC4 & SIM_SCGC4_USBOTG) usb_isr();
// if (SIM_SCGC4 & SIM_SCGC4_UART0) uart0_status_isr();
// if (SIM_SCGC4 & SIM_SCGC4_UART1) uart1_status_isr();
// if (SIM_SCGC4 & SIM_SCGC4_UART2) uart2_status_isr();
// }
//}
void unused_isr(void)
{
fault_isr();
}
void nmi_isr(void) __attribute__ ((weak, alias("unused_isr")));
//void hard_fault_isr(void) __attribute__ ((weak, alias("fault_isr")));
//void memmanage_fault_isr(void) __attribute__ ((weak, alias("fault_isr")));
//void bus_fault_isr(void) __attribute__ ((weak, alias("fault_isr")));
//void usage_fault_isr(void) __attribute__ ((weak, alias("fault_isr")));
void svcall_isr(void) __attribute__ ((weak, alias("unused_isr")));
void debugmonitor_isr(void) __attribute__ ((weak, alias("unused_isr")));
void pendablesrvreq_isr(void) __attribute__ ((weak, alias("unused_isr")));
void systick_isr(void);
void dma_ch0_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch1_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch2_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch3_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch4_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch5_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch6_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch7_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch8_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch9_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch10_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch11_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch12_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch13_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch14_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_ch15_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dma_error_isr(void) __attribute__ ((weak, alias("unused_isr")));
void mcm_isr(void) __attribute__ ((weak, alias("unused_isr")));
void randnum_isr(void) __attribute__ ((weak, alias("unused_isr")));
void flash_cmd_isr(void) __attribute__ ((weak, alias("unused_isr")));
void flash_error_isr(void) __attribute__ ((weak, alias("unused_isr")));
void low_voltage_isr(void) __attribute__ ((weak, alias("unused_isr")));
void wakeup_isr(void) __attribute__ ((weak, alias("unused_isr")));
void watchdog_isr(void) __attribute__ ((weak, alias("unused_isr")));
void i2c0_isr(void) __attribute__ ((weak, alias("unused_isr")));
void i2c1_isr(void) __attribute__ ((weak, alias("unused_isr")));
void i2c2_isr(void) __attribute__ ((weak, alias("unused_isr")));
void i2c3_isr(void) __attribute__ ((weak, alias("unused_isr")));
void spi0_isr(void) __attribute__ ((weak, alias("unused_isr")));
void spi1_isr(void) __attribute__ ((weak, alias("unused_isr")));
void spi2_isr(void) __attribute__ ((weak, alias("unused_isr")));
void sdhc_isr(void) __attribute__ ((weak, alias("unused_isr")));
void enet_timer_isr(void) __attribute__ ((weak, alias("unused_isr")));
void enet_tx_isr(void) __attribute__ ((weak, alias("unused_isr")));
void enet_rx_isr(void) __attribute__ ((weak, alias("unused_isr")));
void enet_error_isr(void) __attribute__ ((weak, alias("unused_isr")));
void can0_message_isr(void) __attribute__ ((weak, alias("unused_isr")));
void can0_bus_off_isr(void) __attribute__ ((weak, alias("unused_isr")));
void can0_error_isr(void) __attribute__ ((weak, alias("unused_isr")));
void can0_tx_warn_isr(void) __attribute__ ((weak, alias("unused_isr")));
void can0_rx_warn_isr(void) __attribute__ ((weak, alias("unused_isr")));
void can0_wakeup_isr(void) __attribute__ ((weak, alias("unused_isr")));
void can1_message_isr(void) __attribute__ ((weak, alias("unused_isr")));
void can1_bus_off_isr(void) __attribute__ ((weak, alias("unused_isr")));
void can1_error_isr(void) __attribute__ ((weak, alias("unused_isr")));
void can1_tx_warn_isr(void) __attribute__ ((weak, alias("unused_isr")));
void can1_rx_warn_isr(void) __attribute__ ((weak, alias("unused_isr")));
void can1_wakeup_isr(void) __attribute__ ((weak, alias("unused_isr")));
void i2s0_tx_isr(void) __attribute__ ((weak, alias("unused_isr")));
void i2s0_rx_isr(void) __attribute__ ((weak, alias("unused_isr")));
void i2s0_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart0_lon_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart0_status_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart0_error_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart1_status_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart1_error_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart2_status_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart2_error_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart3_status_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart3_error_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart4_status_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart4_error_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart5_status_isr(void) __attribute__ ((weak, alias("unused_isr")));
void uart5_error_isr(void) __attribute__ ((weak, alias("unused_isr")));
void lpuart0_status_isr(void) __attribute__ ((weak, alias("unused_isr")));
void adc0_isr(void) __attribute__ ((weak, alias("unused_isr")));
void adc1_isr(void) __attribute__ ((weak, alias("unused_isr")));
void cmp0_isr(void) __attribute__ ((weak, alias("unused_isr")));
void cmp1_isr(void) __attribute__ ((weak, alias("unused_isr")));
void cmp2_isr(void) __attribute__ ((weak, alias("unused_isr")));
void cmp3_isr(void) __attribute__ ((weak, alias("unused_isr")));
void ftm0_isr(void) __attribute__ ((weak, alias("unused_isr")));
void ftm1_isr(void) __attribute__ ((weak, alias("unused_isr")));
void ftm2_isr(void) __attribute__ ((weak, alias("unused_isr")));
void ftm3_isr(void) __attribute__ ((weak, alias("unused_isr")));
void tpm0_isr(void) __attribute__ ((weak, alias("unused_isr")));
void tpm1_isr(void) __attribute__ ((weak, alias("unused_isr")));
void tpm2_isr(void) __attribute__ ((weak, alias("unused_isr")));
void cmt_isr(void) __attribute__ ((weak, alias("unused_isr")));
void rtc_alarm_isr(void) __attribute__ ((weak, alias("unused_isr")));
void rtc_seconds_isr(void) __attribute__ ((weak, alias("unused_isr")));
void pit_isr(void) __attribute__ ((weak, alias("unused_isr")));
void pit0_isr(void) __attribute__ ((weak, alias("unused_isr")));
void pit1_isr(void) __attribute__ ((weak, alias("unused_isr")));
void pit2_isr(void) __attribute__ ((weak, alias("unused_isr")));
void pit3_isr(void) __attribute__ ((weak, alias("unused_isr")));
void pdb_isr(void) __attribute__ ((weak, alias("unused_isr")));
void usb_isr(void) __attribute__ ((weak, alias("unused_isr")));
void usb_charge_isr(void) __attribute__ ((weak, alias("unused_isr")));
void usbhs_isr(void) __attribute__ ((weak, alias("unused_isr")));
void usbhs_phy_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dac0_isr(void) __attribute__ ((weak, alias("unused_isr")));
void dac1_isr(void) __attribute__ ((weak, alias("unused_isr")));
void tsi0_isr(void) __attribute__ ((weak, alias("unused_isr")));
void mcg_isr(void) __attribute__ ((weak, alias("unused_isr")));
void lptmr_isr(void) __attribute__ ((weak, alias("unused_isr")));
void porta_isr(void) __attribute__ ((weak, alias("unused_isr")));
void portb_isr(void) __attribute__ ((weak, alias("unused_isr")));
void portc_isr(void) __attribute__ ((weak, alias("unused_isr")));
void portd_isr(void) __attribute__ ((weak, alias("unused_isr")));
void porte_isr(void) __attribute__ ((weak, alias("unused_isr")));
void portcd_isr(void) __attribute__ ((weak, alias("unused_isr")));
void software_isr(void) __attribute__ ((weak, alias("unused_isr")));
#if defined(__MK20DX128__)
__attribute__ ((section(".dmabuffers"), used, aligned(256)))
#elif defined(__MK20DX256__)
__attribute__ ((section(".dmabuffers"), used, aligned(512)))
#elif defined(__MKL26Z64__)
__attribute__ ((section(".dmabuffers"), used, aligned(256)))
#elif defined(__MK64FX512__)
__attribute__ ((section(".dmabuffers"), used, aligned(512)))
#elif defined(__MK66FX1M0__)
__attribute__ ((section(".dmabuffers"), used, aligned(512)))
#endif
void (* _VectorsRam[NVIC_NUM_INTERRUPTS+16])(void);
__attribute__ ((section(".vectors"), used))
void (* const _VectorsFlash[NVIC_NUM_INTERRUPTS+16])(void) =
{
(void (*)(void))((unsigned long)&_estack), // 0 ARM: Initial Stack Pointer
ResetHandler, // 1 ARM: Initial Program Counter
nmi_isr, // 2 ARM: Non-maskable Interrupt (NMI)
hard_fault_isr, // 3 ARM: Hard Fault
memmanage_fault_isr, // 4 ARM: MemManage Fault
bus_fault_isr, // 5 ARM: Bus Fault
usage_fault_isr, // 6 ARM: Usage Fault
fault_isr, // 7 --
fault_isr, // 8 --
fault_isr, // 9 --
fault_isr, // 10 --
svcall_isr, // 11 ARM: Supervisor call (SVCall)
debugmonitor_isr, // 12 ARM: Debug Monitor
fault_isr, // 13 --
pendablesrvreq_isr, // 14 ARM: Pendable req serv(PendableSrvReq)
systick_isr, // 15 ARM: System tick timer (SysTick)
#if defined(__MK20DX128__)
dma_ch0_isr, // 16 DMA channel 0 transfer complete
dma_ch1_isr, // 17 DMA channel 1 transfer complete
dma_ch2_isr, // 18 DMA channel 2 transfer complete
dma_ch3_isr, // 19 DMA channel 3 transfer complete
dma_error_isr, // 20 DMA error interrupt channel
unused_isr, // 21 DMA --
flash_cmd_isr, // 22 Flash Memory Command complete
flash_error_isr, // 23 Flash Read collision
low_voltage_isr, // 24 Low-voltage detect/warning
wakeup_isr, // 25 Low Leakage Wakeup
watchdog_isr, // 26 Both EWM and WDOG interrupt
i2c0_isr, // 27 I2C0
spi0_isr, // 28 SPI0
i2s0_tx_isr, // 29 I2S0 Transmit
i2s0_rx_isr, // 30 I2S0 Receive
uart0_lon_isr, // 31 UART0 CEA709.1-B (LON) status
uart0_status_isr, // 32 UART0 status
uart0_error_isr, // 33 UART0 error
uart1_status_isr, // 34 UART1 status
uart1_error_isr, // 35 UART1 error
uart2_status_isr, // 36 UART2 status
uart2_error_isr, // 37 UART2 error
adc0_isr, // 38 ADC0
cmp0_isr, // 39 CMP0
cmp1_isr, // 40 CMP1
ftm0_isr, // 41 FTM0
ftm1_isr, // 42 FTM1
cmt_isr, // 43 CMT
rtc_alarm_isr, // 44 RTC Alarm interrupt
rtc_seconds_isr, // 45 RTC Seconds interrupt
pit0_isr, // 46 PIT Channel 0
pit1_isr, // 47 PIT Channel 1
pit2_isr, // 48 PIT Channel 2
pit3_isr, // 49 PIT Channel 3
pdb_isr, // 50 PDB Programmable Delay Block
usb_isr, // 51 USB OTG
usb_charge_isr, // 52 USB Charger Detect
tsi0_isr, // 53 TSI0
mcg_isr, // 54 MCG
lptmr_isr, // 55 Low Power Timer
porta_isr, // 56 Pin detect (Port A)
portb_isr, // 57 Pin detect (Port B)
portc_isr, // 58 Pin detect (Port C)
portd_isr, // 59 Pin detect (Port D)
porte_isr, // 60 Pin detect (Port E)
software_isr, // 61 Software interrupt
#elif defined(__MK20DX256__)
dma_ch0_isr, // 16 DMA channel 0 transfer complete
dma_ch1_isr, // 17 DMA channel 1 transfer complete
dma_ch2_isr, // 18 DMA channel 2 transfer complete
dma_ch3_isr, // 19 DMA channel 3 transfer complete
dma_ch4_isr, // 20 DMA channel 4 transfer complete
dma_ch5_isr, // 21 DMA channel 5 transfer complete
dma_ch6_isr, // 22 DMA channel 6 transfer complete
dma_ch7_isr, // 23 DMA channel 7 transfer complete
dma_ch8_isr, // 24 DMA channel 8 transfer complete
dma_ch9_isr, // 25 DMA channel 9 transfer complete
dma_ch10_isr, // 26 DMA channel 10 transfer complete
dma_ch11_isr, // 27 DMA channel 11 transfer complete
dma_ch12_isr, // 28 DMA channel 12 transfer complete
dma_ch13_isr, // 29 DMA channel 13 transfer complete
dma_ch14_isr, // 30 DMA channel 14 transfer complete
dma_ch15_isr, // 31 DMA channel 15 transfer complete
dma_error_isr, // 32 DMA error interrupt channel
unused_isr, // 33 --
flash_cmd_isr, // 34 Flash Memory Command complete
flash_error_isr, // 35 Flash Read collision
low_voltage_isr, // 36 Low-voltage detect/warning
wakeup_isr, // 37 Low Leakage Wakeup
watchdog_isr, // 38 Both EWM and WDOG interrupt
unused_isr, // 39 --
i2c0_isr, // 40 I2C0
i2c1_isr, // 41 I2C1
spi0_isr, // 42 SPI0
spi1_isr, // 43 SPI1
unused_isr, // 44 --
can0_message_isr, // 45 CAN OR'ed Message buffer (0-15)
can0_bus_off_isr, // 46 CAN Bus Off
can0_error_isr, // 47 CAN Error
can0_tx_warn_isr, // 48 CAN Transmit Warning
can0_rx_warn_isr, // 49 CAN Receive Warning
can0_wakeup_isr, // 50 CAN Wake Up
i2s0_tx_isr, // 51 I2S0 Transmit
i2s0_rx_isr, // 52 I2S0 Receive
unused_isr, // 53 --
unused_isr, // 54 --
unused_isr, // 55 --
unused_isr, // 56 --
unused_isr, // 57 --
unused_isr, // 58 --
unused_isr, // 59 --
uart0_lon_isr, // 60 UART0 CEA709.1-B (LON) status
uart0_status_isr, // 61 UART0 status
uart0_error_isr, // 62 UART0 error
uart1_status_isr, // 63 UART1 status
uart1_error_isr, // 64 UART1 error
uart2_status_isr, // 65 UART2 status
uart2_error_isr, // 66 UART2 error
unused_isr, // 67 --
unused_isr, // 68 --
unused_isr, // 69 --
unused_isr, // 70 --
unused_isr, // 71 --
unused_isr, // 72 --
adc0_isr, // 73 ADC0
adc1_isr, // 74 ADC1
cmp0_isr, // 75 CMP0
cmp1_isr, // 76 CMP1
cmp2_isr, // 77 CMP2
ftm0_isr, // 78 FTM0
ftm1_isr, // 79 FTM1
ftm2_isr, // 80 FTM2
cmt_isr, // 81 CMT
rtc_alarm_isr, // 82 RTC Alarm interrupt
rtc_seconds_isr, // 83 RTC Seconds interrupt
pit0_isr, // 84 PIT Channel 0
pit1_isr, // 85 PIT Channel 1
pit2_isr, // 86 PIT Channel 2
pit3_isr, // 87 PIT Channel 3
pdb_isr, // 88 PDB Programmable Delay Block
usb_isr, // 89 USB OTG
usb_charge_isr, // 90 USB Charger Detect
unused_isr, // 91 --
unused_isr, // 92 --
unused_isr, // 93 --
unused_isr, // 94 --
unused_isr, // 95 --
unused_isr, // 96 --
dac0_isr, // 97 DAC0
unused_isr, // 98 --
tsi0_isr, // 99 TSI0
mcg_isr, // 100 MCG
lptmr_isr, // 101 Low Power Timer
unused_isr, // 102 --
porta_isr, // 103 Pin detect (Port A)
portb_isr, // 104 Pin detect (Port B)
portc_isr, // 105 Pin detect (Port C)
portd_isr, // 106 Pin detect (Port D)
porte_isr, // 107 Pin detect (Port E)
unused_isr, // 108 --
unused_isr, // 109 --
software_isr, // 110 Software interrupt
#elif defined(__MKL26Z64__)
dma_ch0_isr, // 16 DMA channel 0 transfer complete
dma_ch1_isr, // 17 DMA channel 1 transfer complete
dma_ch2_isr, // 18 DMA channel 2 transfer complete
dma_ch3_isr, // 19 DMA channel 3 transfer complete
unused_isr, // 20 --
flash_cmd_isr, // 21 Flash Memory Command complete
low_voltage_isr, // 22 Low-voltage detect/warning
wakeup_isr, // 23 Low Leakage Wakeup
i2c0_isr, // 24 I2C0
i2c1_isr, // 25 I2C1
spi0_isr, // 26 SPI0
spi1_isr, // 27 SPI1
uart0_status_isr, // 28 UART0 status & error
uart1_status_isr, // 29 UART1 status & error
uart2_status_isr, // 30 UART2 status & error
adc0_isr, // 31 ADC0
cmp0_isr, // 32 CMP0
ftm0_isr, // 33 FTM0
ftm1_isr, // 34 FTM1
ftm2_isr, // 35 FTM2
rtc_alarm_isr, // 36 RTC Alarm interrupt
rtc_seconds_isr, // 37 RTC Seconds interrupt
pit_isr, // 38 PIT Both Channels
i2s0_isr, // 39 I2S0 Transmit & Receive
usb_isr, // 40 USB OTG
dac0_isr, // 41 DAC0
tsi0_isr, // 42 TSI0
mcg_isr, // 43 MCG
lptmr_isr, // 44 Low Power Timer
software_isr, // 45 Software interrupt
porta_isr, // 46 Pin detect (Port A)
portcd_isr, // 47 Pin detect (Port C and D)
#elif defined(__MK64FX512__)
dma_ch0_isr, // 16 DMA channel 0 transfer complete
dma_ch1_isr, // 17 DMA channel 1 transfer complete
dma_ch2_isr, // 18 DMA channel 2 transfer complete
dma_ch3_isr, // 19 DMA channel 3 transfer complete
dma_ch4_isr, // 20 DMA channel 4 transfer complete
dma_ch5_isr, // 21 DMA channel 5 transfer complete
dma_ch6_isr, // 22 DMA channel 6 transfer complete
dma_ch7_isr, // 23 DMA channel 7 transfer complete
dma_ch8_isr, // 24 DMA channel 8 transfer complete
dma_ch9_isr, // 25 DMA channel 9 transfer complete
dma_ch10_isr, // 26 DMA channel 10 transfer complete
dma_ch11_isr, // 27 DMA channel 11 transfer complete
dma_ch12_isr, // 28 DMA channel 12 transfer complete
dma_ch13_isr, // 29 DMA channel 13 transfer complete
dma_ch14_isr, // 30 DMA channel 14 transfer complete
dma_ch15_isr, // 31 DMA channel 15 transfer complete
dma_error_isr, // 32 DMA error interrupt channel
mcm_isr, // 33 MCM
flash_cmd_isr, // 34 Flash Memory Command complete
flash_error_isr, // 35 Flash Read collision
low_voltage_isr, // 36 Low-voltage detect/warning
wakeup_isr, // 37 Low Leakage Wakeup
watchdog_isr, // 38 Both EWM and WDOG interrupt
randnum_isr, // 39 Random Number Generator
i2c0_isr, // 40 I2C0
i2c1_isr, // 41 I2C1
spi0_isr, // 42 SPI0
spi1_isr, // 43 SPI1
i2s0_tx_isr, // 44 I2S0 Transmit
i2s0_rx_isr, // 45 I2S0 Receive
unused_isr, // 46 --
uart0_status_isr, // 47 UART0 status
uart0_error_isr, // 48 UART0 error
uart1_status_isr, // 49 UART1 status
uart1_error_isr, // 50 UART1 error
uart2_status_isr, // 51 UART2 status
uart2_error_isr, // 52 UART2 error
uart3_status_isr, // 53 UART3 status
uart3_error_isr, // 54 UART3 error
adc0_isr, // 55 ADC0
cmp0_isr, // 56 CMP0
cmp1_isr, // 57 CMP1
ftm0_isr, // 58 FTM0
ftm1_isr, // 59 FTM1
ftm2_isr, // 60 FTM2
cmt_isr, // 61 CMT
rtc_alarm_isr, // 62 RTC Alarm interrupt
rtc_seconds_isr, // 63 RTC Seconds interrupt
pit0_isr, // 64 PIT Channel 0
pit1_isr, // 65 PIT Channel 1
pit2_isr, // 66 PIT Channel 2
pit3_isr, // 67 PIT Channel 3
pdb_isr, // 68 PDB Programmable Delay Block
usb_isr, // 69 USB OTG
usb_charge_isr, // 70 USB Charger Detect
unused_isr, // 71 --
dac0_isr, // 72 DAC0
mcg_isr, // 73 MCG
lptmr_isr, // 74 Low Power Timer
porta_isr, // 75 Pin detect (Port A)
portb_isr, // 76 Pin detect (Port B)
portc_isr, // 77 Pin detect (Port C)
portd_isr, // 78 Pin detect (Port D)
porte_isr, // 79 Pin detect (Port E)
software_isr, // 80 Software interrupt
spi2_isr, // 81 SPI2
uart4_status_isr, // 82 UART4 status
uart4_error_isr, // 83 UART4 error
uart5_status_isr, // 84 UART4 status
uart5_error_isr, // 85 UART4 error
cmp2_isr, // 86 CMP2
ftm3_isr, // 87 FTM3
dac1_isr, // 88 DAC1
adc1_isr, // 89 ADC1
i2c2_isr, // 90 I2C2
can0_message_isr, // 91 CAN OR'ed Message buffer (0-15)
can0_bus_off_isr, // 92 CAN Bus Off
can0_error_isr, // 93 CAN Error
can0_tx_warn_isr, // 94 CAN Transmit Warning
can0_rx_warn_isr, // 95 CAN Receive Warning
can0_wakeup_isr, // 96 CAN Wake Up
sdhc_isr, // 97 SDHC
enet_timer_isr, // 98 Ethernet IEEE1588 Timers
enet_tx_isr, // 99 Ethernet Transmit
enet_rx_isr, // 100 Ethernet Receive
enet_error_isr, // 101 Ethernet Error
#elif defined(__MK66FX1M0__)
dma_ch0_isr, // 16 DMA channel 0 transfer complete
dma_ch1_isr, // 17 DMA channel 1 transfer complete
dma_ch2_isr, // 18 DMA channel 2 transfer complete
dma_ch3_isr, // 19 DMA channel 3 transfer complete
dma_ch4_isr, // 20 DMA channel 4 transfer complete
dma_ch5_isr, // 21 DMA channel 5 transfer complete
dma_ch6_isr, // 22 DMA channel 6 transfer complete
dma_ch7_isr, // 23 DMA channel 7 transfer complete
dma_ch8_isr, // 24 DMA channel 8 transfer complete
dma_ch9_isr, // 25 DMA channel 9 transfer complete
dma_ch10_isr, // 26 DMA channel 10 transfer complete
dma_ch11_isr, // 27 DMA channel 11 transfer complete
dma_ch12_isr, // 28 DMA channel 12 transfer complete
dma_ch13_isr, // 29 DMA channel 13 transfer complete
dma_ch14_isr, // 30 DMA channel 14 transfer complete
dma_ch15_isr, // 31 DMA channel 15 transfer complete
dma_error_isr, // 32 DMA error interrupt channel
mcm_isr, // 33 MCM
flash_cmd_isr, // 34 Flash Memory Command complete
flash_error_isr, // 35 Flash Read collision
low_voltage_isr, // 36 Low-voltage detect/warning
wakeup_isr, // 37 Low Leakage Wakeup
watchdog_isr, // 38 Both EWM and WDOG interrupt
randnum_isr, // 39 Random Number Generator
i2c0_isr, // 40 I2C0
i2c1_isr, // 41 I2C1
spi0_isr, // 42 SPI0
spi1_isr, // 43 SPI1
i2s0_tx_isr, // 44 I2S0 Transmit
i2s0_rx_isr, // 45 I2S0 Receive
unused_isr, // 46 --
uart0_status_isr, // 47 UART0 status
uart0_error_isr, // 48 UART0 error
uart1_status_isr, // 49 UART1 status
uart1_error_isr, // 50 UART1 error
uart2_status_isr, // 51 UART2 status
uart2_error_isr, // 52 UART2 error
uart3_status_isr, // 53 UART3 status
uart3_error_isr, // 54 UART3 error
adc0_isr, // 55 ADC0
cmp0_isr, // 56 CMP0
cmp1_isr, // 57 CMP1
ftm0_isr, // 58 FTM0
ftm1_isr, // 59 FTM1
ftm2_isr, // 60 FTM2
cmt_isr, // 61 CMT
rtc_alarm_isr, // 62 RTC Alarm interrupt
rtc_seconds_isr, // 63 RTC Seconds interrupt
pit0_isr, // 64 PIT Channel 0
pit1_isr, // 65 PIT Channel 1
pit2_isr, // 66 PIT Channel 2
pit3_isr, // 67 PIT Channel 3
pdb_isr, // 68 PDB Programmable Delay Block
usb_isr, // 69 USB OTG
usb_charge_isr, // 70 USB Charger Detect
unused_isr, // 71 --
dac0_isr, // 72 DAC0
mcg_isr, // 73 MCG
lptmr_isr, // 74 Low Power Timer
porta_isr, // 75 Pin detect (Port A)
portb_isr, // 76 Pin detect (Port B)
portc_isr, // 77 Pin detect (Port C)
portd_isr, // 78 Pin detect (Port D)
porte_isr, // 79 Pin detect (Port E)
software_isr, // 80 Software interrupt
spi2_isr, // 81 SPI2
uart4_status_isr, // 82 UART4 status
uart4_error_isr, // 83 UART4 error
unused_isr, // 84 --
unused_isr, // 85 --
cmp2_isr, // 86 CMP2
ftm3_isr, // 87 FTM3
dac1_isr, // 88 DAC1
adc1_isr, // 89 ADC1
i2c2_isr, // 90 I2C2
can0_message_isr, // 91 CAN OR'ed Message buffer (0-15)
can0_bus_off_isr, // 92 CAN Bus Off
can0_error_isr, // 93 CAN Error
can0_tx_warn_isr, // 94 CAN Transmit Warning
can0_rx_warn_isr, // 95 CAN Receive Warning
can0_wakeup_isr, // 96 CAN Wake Up
sdhc_isr, // 97 SDHC
enet_timer_isr, // 98 Ethernet IEEE1588 Timers
enet_tx_isr, // 99 Ethernet Transmit
enet_rx_isr, // 100 Ethernet Receive
enet_error_isr, // 101 Ethernet Error
lpuart0_status_isr, // 102 LPUART
tsi0_isr, // 103 TSI0
tpm1_isr, // 104 FTM1
tpm2_isr, // 105 FTM2
usbhs_phy_isr, // 106 USB-HS Phy
i2c3_isr, // 107 I2C3
cmp3_isr, // 108 CMP3
usbhs_isr, // 109 USB-HS
can1_message_isr, // 110 CAN OR'ed Message buffer (0-15)
can1_bus_off_isr, // 111 CAN Bus Off
can1_error_isr, // 112 CAN Error
can1_tx_warn_isr, // 113 CAN Transmit Warning
can1_rx_warn_isr, // 114 CAN Receive Warning
can1_wakeup_isr, // 115 CAN Wake Up
#endif
};
__attribute__ ((section(".flashconfig"), used))
const uint8_t flashconfigbytes[16] = {
0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF,
0xFF, 0xFF, 0xFF, 0xFF, FSEC, FOPT, 0xFF, 0xFF
};
// zOS/ZPUTA Function call table.
// This table is used by applications to call the corresponding function within the OS. This saves on size of an application and
// necessary initialisation/open streams etc.
//
#if defined __ZOS__
__attribute__ ((section(".zosvectors"), used))
void _zOS_Vectors(void)
{
#elif defined __ZPUTA__
__attribute__ ((section(".zputavectors"), used))
void _ZPUTA_Vectors(void)
{
#else
#error OS not defined, should be __ZPUTA__ or __ZOS__
#endif
//
// Break point handler primarily for the ZPU, not really used for the K64F.
//
__asm__ volatile ("bx lr"); __asm__ volatile ("nop");
//
// putc and xprint calls
//
__asm__ volatile ("b putchar");
__asm__ volatile ("b putc");
__asm__ volatile ("b fputc");
__asm__ volatile ("b puts");
__asm__ volatile ("b gets");
__asm__ volatile ("b fgets");
__asm__ volatile ("b fputs");
__asm__ volatile ("b xatoi");
__asm__ volatile ("b uxatoi");
__asm__ volatile ("b printf");
__asm__ volatile ("b sprintf");
__asm__ volatile ("b fprintf");
//
// getc calls
//
__asm__ volatile ("b usb_serial_getchar");
//
// Util calls.
//
// __asm__ volatile ("b crc32_init");
// __asm__ volatile ("b crc32_addword");
__asm__ volatile ("b get_dword");
__asm__ volatile ("b rtcSet");
__asm__ volatile ("b rtcGet");
//
// FatFS System Calls.
//
__asm__ volatile ("b f_open");
__asm__ volatile ("b f_close");
__asm__ volatile ("b f_read");
__asm__ volatile ("b f_write");
__asm__ volatile ("b f_lseek");
__asm__ volatile ("b f_truncate");
__asm__ volatile ("b f_sync");
__asm__ volatile ("b f_opendir");
__asm__ volatile ("b f_closedir");
__asm__ volatile ("b f_readdir");
// __asm__ volatile ("b f_findfirst");
// __asm__ volatile ("b f_findnext");
__asm__ volatile ("b f_mkdir");
__asm__ volatile ("b f_unlink");
__asm__ volatile ("b f_rename");
__asm__ volatile ("b f_stat");
__asm__ volatile ("b f_chmod");
__asm__ volatile ("b f_utime");
__asm__ volatile ("b f_chdir");
__asm__ volatile ("b f_chdrive");
__asm__ volatile ("b f_getcwd");
__asm__ volatile ("b f_getfree");
__asm__ volatile ("b f_getlabel");
__asm__ volatile ("b f_setlabel");
// __asm__ volatile ("b f_forward");
__asm__ volatile ("b f_expand");
__asm__ volatile ("b f_mount");
__asm__ volatile ("b f_mkfs");
// __asm__ volatile ("b f_fdisk");
// __asm__ volatile ("b f_setcp");
__asm__ volatile ("b f_putc");
// __asm__ volatile ("b f_puts");
// __asm__ volatile ("b f_printf");
__asm__ volatile ("b f_gets");
//
// Low level disk calls.
//
__asm__ volatile ("b disk_read");
__asm__ volatile ("b disk_write");
__asm__ volatile ("b disk_ioctl");
//
// Miscellaneous Calls.
//
__asm__ volatile ("b getStrParam");
__asm__ volatile ("b getUintParam");
__asm__ volatile ("bx lr"); __asm__ volatile ("nop");
// __asm__ volatile ("b printBytesPerSec");
__asm__ volatile ("b printFSCode");
//
// Memory management calls for memory managed by OS.
//
__asm__ volatile ("b malloc");
__asm__ volatile ("b realloc");
__asm__ volatile ("b calloc");
__asm__ volatile ("b free");
#if defined __TRANZPUTER__
//
// tranZPUter methods which need to be called via the kernel not accessed by the application directly.
//
__asm__ volatile ("b setupZ80Pins");
__asm__ volatile ("b resetZ80");
__asm__ volatile ("b reqZ80Bus");
__asm__ volatile ("b reqMainboardBus");
__asm__ volatile ("b reqTranZPUterBus");
__asm__ volatile ("b setupSignalsForZ80Access");
__asm__ volatile ("b releaseZ80");
__asm__ volatile ("b writeZ80Memory");
__asm__ volatile ("b readZ80Memory");
__asm__ volatile ("b writeZ80IO");
__asm__ volatile ("b readZ80IO");
__asm__ volatile ("b refreshZ80");
__asm__ volatile ("b refreshZ80AllRows");
__asm__ volatile ("b setCtrlLatch");
__asm__ volatile ("b copyFromZ80");
__asm__ volatile ("b copyToZ80");
__asm__ volatile ("b fillZ80Memory");
__asm__ volatile ("b captureVideoFrame");
__asm__ volatile ("b refreshVideoFrame");
__asm__ volatile ("b loadVideoFrameBuffer");
__asm__ volatile ("b saveVideoFrameBuffer");
__asm__ volatile ("b getVideoFrame");
__asm__ volatile ("b getAttributeFrame");
__asm__ volatile ("b loadZ80Memory");
__asm__ volatile ("b loadMZFZ80Memory");
__asm__ volatile ("b saveZ80Memory");
__asm__ volatile ("b memoryDumpZ80");
__asm__ volatile ("b isZ80Reset");
__asm__ volatile ("b isZ80MemorySwapped");
__asm__ volatile ("b getZ80IO");
__asm__ volatile ("b clearZ80Reset");
__asm__ volatile ("b loadTranZPUterDefaultROMS");
__asm__ volatile ("b convertSharpFilenameToAscii");
#endif
}
// Automatically initialize the RTC. When the build defines the compile
// time, and the user has added a crystal, the RTC will automatically
// begin at the time of the first upload.
#ifndef TIME_T
#define TIME_T 1349049600 // default 1 Oct 2012 (never used, Arduino sets this)
#endif
extern void *__rtc_localtime; // Arduino build process sets this
extern void rtc_set(unsigned long t);
static void startup_default_early_hook(void) {
#if defined(KINETISK)
WDOG_STCTRLH = WDOG_STCTRLH_ALLOWUPDATE;
#elif defined(KINETISL)
SIM_COPC = 0; // disable the watchdog
#endif
}
static void startup_default_late_hook(void) {}
void startup_early_hook(void) __attribute__ ((weak, alias("startup_default_early_hook")));
void startup_late_hook(void) __attribute__ ((weak, alias("startup_default_late_hook")));
#if defined(__PURE_CODE__) || !defined(__OPTIMIZE__) || defined(__clang__)
// cases known to compile too large for 0-0x400 memory region
__attribute__ ((optimize("-Os")))
#else
// hopefully all others fit into startup section (below 0x400)
__attribute__ ((section(".startup"),optimize("-Os")))
#endif
void ResetHandler(void)
{
uint32_t *src = &_etext;
uint32_t *dest = &_sdata;
unsigned int i;
#if F_CPU <= 2000000
volatile int n;
#endif
//volatile int count;
#ifdef KINETISK
WDOG_UNLOCK = WDOG_UNLOCK_SEQ1;
WDOG_UNLOCK = WDOG_UNLOCK_SEQ2;
__asm__ volatile ("nop");
__asm__ volatile ("nop");
#endif
// programs using the watchdog timer or needing to initialize hardware as
// early as possible can implement startup_early_hook()
startup_early_hook();
// enable clocks to always-used peripherals
#if defined(__MK20DX128__)
SIM_SCGC5 = 0x00043F82; // clocks active to all GPIO
SIM_SCGC6 = SIM_SCGC6_RTC | SIM_SCGC6_FTM0 | SIM_SCGC6_FTM1 | SIM_SCGC6_ADC0 | SIM_SCGC6_FTFL;
#elif defined(__MK20DX256__)
SIM_SCGC3 = SIM_SCGC3_ADC1 | SIM_SCGC3_FTM2;
SIM_SCGC5 = 0x00043F82; // clocks active to all GPIO
SIM_SCGC6 = SIM_SCGC6_RTC | SIM_SCGC6_FTM0 | SIM_SCGC6_FTM1 | SIM_SCGC6_ADC0 | SIM_SCGC6_FTFL;
#elif defined(__MK64FX512__) || defined(__MK66FX1M0__)
SIM_SCGC3 = SIM_SCGC3_ADC1 | SIM_SCGC3_FTM2 | SIM_SCGC3_FTM3;
SIM_SCGC5 = 0x00043F82; // clocks active to all GPIO
SIM_SCGC6 = SIM_SCGC6_RTC | SIM_SCGC6_FTM0 | SIM_SCGC6_FTM1 | SIM_SCGC6_ADC0 | SIM_SCGC6_FTFL;
//PORTC_PCR5 = PORT_PCR_MUX(1) | PORT_PCR_DSE | PORT_PCR_SRE;
//GPIOC_PDDR |= (1<<5);
//GPIOC_PSOR = (1<<5);
//while (1);
#elif defined(__MKL26Z64__)
SIM_SCGC4 = SIM_SCGC4_USBOTG | 0xF0000030;
SIM_SCGC5 = 0x00003F82; // clocks active to all GPIO
SIM_SCGC6 = SIM_SCGC6_ADC0 | SIM_SCGC6_TPM0 | SIM_SCGC6_TPM1 | SIM_SCGC6_TPM2 | SIM_SCGC6_FTFL;
#endif
#if defined(__MK64FX512__) || defined(__MK66FX1M0__)
SCB_CPACR = 0x00F00000;
#endif
#if defined(__MK66FX1M0__)
LMEM_PCCCR = 0x85000003;
#endif
#if 0
// testing only, enable ser_print
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV4(1);
MCG_C4 |= MCG_C4_DMX32 | MCG_C4_DRST_DRS(1);
SIM_SOPT2 = SIM_SOPT2_UART0SRC(1) | SIM_SOPT2_TPMSRC(1);
SIM_SCGC4 |= 0x00000400;
UART0_BDH = 0;
UART0_BDL = 26; // 115200 at 48 MHz
UART0_C2 = UART_C2_TE;
PORTB_PCR17 = PORT_PCR_MUX(3);
#endif
#if defined(KINETISK) && !defined(__MK66FX1M0__)
// If the RTC oscillator isn't enabled, get it started early.
// But don't do this early on Teensy 3.6 - RTC_CR depends on 3.3V+VBAT
// which may be ~0.4V "behind" 3.3V if the power ramps up slowly.
if (!(RTC_CR & RTC_CR_OSCE)) {
RTC_SR = 0;
RTC_CR = RTC_CR_SC16P | RTC_CR_SC4P | RTC_CR_OSCE;
}
#endif
// release I/O pins hold, if we woke up from VLLS mode
if (PMC_REGSC & PMC_REGSC_ACKISO) PMC_REGSC |= PMC_REGSC_ACKISO;
// since this is a write once register, make it visible to all F_CPU's
// so we can into other sleep modes in the future at any speed
#if defined(__MK66FX1M0__)
SMC_PMPROT = SMC_PMPROT_AHSRUN | SMC_PMPROT_AVLP | SMC_PMPROT_ALLS | SMC_PMPROT_AVLLS;
#else
SMC_PMPROT = SMC_PMPROT_AVLP | SMC_PMPROT_ALLS | SMC_PMPROT_AVLLS;
#endif
// TODO: do this while the PLL is waiting to lock....
while (dest < &_edata) *dest++ = *src++;
dest = &_sbss;
while (dest < &_ebss) *dest++ = 0;
// default all interrupts to medium priority level
for (i=0; i < NVIC_NUM_INTERRUPTS + 16; i++) _VectorsRam[i] = _VectorsFlash[i];
for (i=0; i < NVIC_NUM_INTERRUPTS; i++) NVIC_SET_PRIORITY(i, 128);
SCB_VTOR = (uint32_t)_VectorsRam; // use vector table in RAM
// hardware always starts in FEI mode
// C1[CLKS] bits are written to 00
// C1[IREFS] bit is written to 1
// C6[PLLS] bit is written to 0
// MCG_SC[FCDIV] defaults to divide by two for internal ref clock
// I tried changing MSG_SC to divide by 1, it didn't work for me
#if F_CPU <= 2000000
#if defined(KINETISK)
MCG_C1 = MCG_C1_CLKS(1) | MCG_C1_IREFS;
#elif defined(KINETISL)
// use the internal oscillator
MCG_C1 = MCG_C1_CLKS(1) | MCG_C1_IREFS | MCG_C1_IRCLKEN;
#endif
// wait for MCGOUT to use oscillator
while ((MCG_S & MCG_S_CLKST_MASK) != MCG_S_CLKST(1)) ;
for (n=0; n<10; n++) ; // TODO: why do we get 2 mA extra without this delay?
MCG_C2 = MCG_C2_IRCS;
while (!(MCG_S & MCG_S_IRCST)) ;
// now in FBI mode:
// C1[CLKS] bits are written to 01
// C1[IREFS] bit is written to 1
// C6[PLLS] is written to 0
// C2[LP] is written to 0
MCG_C2 = MCG_C2_IRCS | MCG_C2_LP;
// now in BLPI mode:
// C1[CLKS] bits are written to 01
// C1[IREFS] bit is written to 1
// C6[PLLS] bit is written to 0
// C2[LP] bit is written to 1
#else
#if defined(KINETISK)
// enable capacitors for crystal
OSC0_CR = OSC_SC8P | OSC_SC2P | OSC_ERCLKEN;
#elif defined(KINETISL)
// enable capacitors for crystal
OSC0_CR = OSC_SC8P | OSC_SC2P | OSC_ERCLKEN;
#endif
// enable osc, 8-32 MHz range, low power mode
MCG_C2 = MCG_C2_RANGE0(2) | MCG_C2_EREFS;
// switch to crystal as clock source, FLL input = 16 MHz / 512
MCG_C1 = MCG_C1_CLKS(2) | MCG_C1_FRDIV(4);
// wait for crystal oscillator to begin
while ((MCG_S & MCG_S_OSCINIT0) == 0) ;
// wait for FLL to use oscillator
while ((MCG_S & MCG_S_IREFST) != 0) ;
// wait for MCGOUT to use oscillator
while ((MCG_S & MCG_S_CLKST_MASK) != MCG_S_CLKST(2)) ;
// now in FBE mode
// C1[CLKS] bits are written to 10
// C1[IREFS] bit is written to 0
// C1[FRDIV] must be written to divide xtal to 31.25-39 kHz
// C6[PLLS] bit is written to 0
// C2[LP] is written to 0
#if F_CPU <= 16000000
// if the crystal is fast enough, use it directly (no FLL or PLL)
MCG_C2 = MCG_C2_RANGE0(2) | MCG_C2_EREFS | MCG_C2_LP;
// BLPE mode:
// C1[CLKS] bits are written to 10
// C1[IREFS] bit is written to 0
// C2[LP] bit is written to 1
#else
// if we need faster than the crystal, turn on the PLL
#if defined(__MK66FX1M0__)
#if F_CPU > 120000000
SMC_PMCTRL = SMC_PMCTRL_RUNM(3); // enter HSRUN mode
while (SMC_PMSTAT != SMC_PMSTAT_HSRUN) ; // wait for HSRUN
#endif
#if F_CPU == 256000000
//See table in 27.4.6 MCG Control 6 Register (MCG_C6)
//16 -> Multiply factor 32. 32*8MHz =256MHz
MCG_C5 = MCG_C5_PRDIV0(0);
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(16);
#elif F_CPU == 240000000
MCG_C5 = MCG_C5_PRDIV0(0);
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(14);
#elif F_CPU == 216000000
MCG_C5 = MCG_C5_PRDIV0(0);
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(11);
#elif F_CPU == 192000000
MCG_C5 = MCG_C5_PRDIV0(0);
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(8);
#elif F_CPU == 180000000
MCG_C5 = MCG_C5_PRDIV0(1);
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(29);
#elif F_CPU == 168000000
MCG_C5 = MCG_C5_PRDIV0(0);
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(5);
#elif F_CPU == 144000000
MCG_C5 = MCG_C5_PRDIV0(0);
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(2);
#elif F_CPU == 120000000
MCG_C5 = MCG_C5_PRDIV0(1);
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(14);
#elif F_CPU == 96000000 || F_CPU == 48000000 || F_CPU == 24000000
MCG_C5 = MCG_C5_PRDIV0(1);
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(8);
#elif F_CPU == 72000000
MCG_C5 = MCG_C5_PRDIV0(1);
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(2);
#elif F_CPU > 16000000
#error "MK66FX1M0 does not support this clock speed yet...."
#endif
#else
#if F_CPU == 72000000
MCG_C5 = MCG_C5_PRDIV0(5); // config PLL input for 16 MHz Crystal / 6 = 2.667 Hz
#else
MCG_C5 = MCG_C5_PRDIV0(3); // config PLL input for 16 MHz Crystal / 4 = 4 MHz
#endif
#if F_CPU == 168000000
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(18); // config PLL for 168 MHz output
#elif F_CPU == 144000000
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(12); // config PLL for 144 MHz output
#elif F_CPU == 120000000
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(6); // config PLL for 120 MHz output
#elif F_CPU == 72000000
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(3); // config PLL for 72 MHz output
#elif F_CPU == 96000000 || F_CPU == 48000000 || F_CPU == 24000000
MCG_C6 = MCG_C6_PLLS | MCG_C6_VDIV0(0); // config PLL for 96 MHz output
#elif F_CPU > 16000000
#error "This clock speed isn't supported..."
#endif
#endif
// wait for PLL to start using xtal as its input
while (!(MCG_S & MCG_S_PLLST)) ;
// wait for PLL to lock
while (!(MCG_S & MCG_S_LOCK0)) ;
// now we're in PBE mode
#endif
#endif
// now program the clock dividers
#if F_CPU == 256000000
// config divisors: 256 MHz core, 64 MHz bus, 32 MHz flash, USB = IRC48M
// TODO: gradual ramp-up for HSRUN mode
#if F_BUS == 64000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(3) | SIM_CLKDIV1_OUTDIV4(7);
#elif F_BUS == 128000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(1) | SIM_CLKDIV1_OUTDIV4(7);
#else
#error "This F_CPU & F_BUS combination is not supported"
#endif
SIM_CLKDIV2 = SIM_CLKDIV2_USBDIV(0);
#elif F_CPU == 240000000
// config divisors: 240 MHz core, 60 MHz bus, 30 MHz flash, USB = 240 / 5
// TODO: gradual ramp-up for HSRUN mode
#if F_BUS == 60000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(3) | SIM_CLKDIV1_OUTDIV4(7);
#elif F_BUS == 80000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(2) | SIM_CLKDIV1_OUTDIV4(7);
#elif F_BUS == 120000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(1) | SIM_CLKDIV1_OUTDIV4(7);
#else
#error "This F_CPU & F_BUS combination is not supported"
#endif
SIM_CLKDIV2 = SIM_CLKDIV2_USBDIV(4);
#elif F_CPU == 216000000
// config divisors: 216 MHz core, 54 MHz bus, 27 MHz flash, USB = IRC48M
// TODO: gradual ramp-up for HSRUN mode
#if F_BUS == 54000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(3) | SIM_CLKDIV1_OUTDIV4(7);
#elif F_BUS == 72000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(2) | SIM_CLKDIV1_OUTDIV4(7);
#elif F_BUS == 108000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(1) | SIM_CLKDIV1_OUTDIV4(7);
#else
#error "This F_CPU & F_BUS combination is not supported"
#endif
SIM_CLKDIV2 = SIM_CLKDIV2_USBDIV(0);
#elif F_CPU == 192000000
// config divisors: 192 MHz core, 48 MHz bus, 27.4 MHz flash, USB = 192 / 4
// TODO: gradual ramp-up for HSRUN mode
#if F_BUS == 48000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(3) | SIM_CLKDIV1_OUTDIV4(6);
#elif F_BUS == 64000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(2) | SIM_CLKDIV1_OUTDIV4(6);
#elif F_BUS == 96000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(1) | SIM_CLKDIV1_OUTDIV4(6);
#else
#error "This F_CPU & F_BUS combination is not supported"
#endif
SIM_CLKDIV2 = SIM_CLKDIV2_USBDIV(3);
#elif F_CPU == 180000000
// config divisors: 180 MHz core, 60 MHz bus, 25.7 MHz flash, USB = IRC48M
#if F_BUS == 60000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(2) | SIM_CLKDIV1_OUTDIV4(6);
#elif F_BUS == 90000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(1) | SIM_CLKDIV1_OUTDIV4(6);
#else
#error "This F_CPU & F_BUS combination is not supported"
#endif
SIM_CLKDIV2 = SIM_CLKDIV2_USBDIV(0);
#elif F_CPU == 168000000
// config divisors: 168 MHz core, 56 MHz bus, 28 MHz flash, USB = 168 * 2 / 7
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(2) | SIM_CLKDIV1_OUTDIV4(5);
SIM_CLKDIV2 = SIM_CLKDIV2_USBDIV(6) | SIM_CLKDIV2_USBFRAC;
#elif F_CPU == 144000000
// config divisors: 144 MHz core, 48 MHz bus, 28.8 MHz flash, USB = 144 / 3
#if F_BUS == 48000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(2) | SIM_CLKDIV1_OUTDIV4(4);
#elif F_BUS == 72000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(1) | SIM_CLKDIV1_OUTDIV4(4);
#else
#error "This F_CPU & F_BUS combination is not supported"
#endif
SIM_CLKDIV2 = SIM_CLKDIV2_USBDIV(2);
#elif F_CPU == 120000000
// config divisors: 120 MHz core, 60 MHz bus, 24 MHz flash, USB = 128 * 2 / 5
#if F_BUS == 60000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(1) | SIM_CLKDIV1_OUTDIV4(4);
#elif F_BUS == 120000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(0) | SIM_CLKDIV1_OUTDIV4(4);
#else
#error "This F_CPU & F_BUS combination is not supported"
#endif
SIM_CLKDIV2 = SIM_CLKDIV2_USBDIV(4) | SIM_CLKDIV2_USBFRAC;
#elif F_CPU == 96000000
// config divisors: 96 MHz core, 48 MHz bus, 24 MHz flash, USB = 96 / 2
#if F_BUS == 48000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(1) | SIM_CLKDIV1_OUTDIV4(3);
#elif F_BUS == 96000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(0) | SIM_CLKDIV1_OUTDIV4(3);
#else
#error "This F_CPU & F_BUS combination is not supported"
#endif
SIM_CLKDIV2 = SIM_CLKDIV2_USBDIV(1);
#elif F_CPU == 72000000
// config divisors: 72 MHz core, 36 MHz bus, 24 MHz flash, USB = 72 * 2 / 3
#if F_BUS == 36000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(1) | SIM_CLKDIV1_OUTDIV4(2);
#elif F_BUS == 72000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(0) | SIM_CLKDIV1_OUTDIV4(2);
#else
#error "This F_CPU & F_BUS combination is not supported"
#endif
SIM_CLKDIV2 = SIM_CLKDIV2_USBDIV(2) | SIM_CLKDIV2_USBFRAC;
#elif F_CPU == 48000000
// config divisors: 48 MHz core, 48 MHz bus, 24 MHz flash, USB = 96 / 2
#if defined(KINETISK)
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(1) | SIM_CLKDIV1_OUTDIV2(1) | SIM_CLKDIV1_OUTDIV3(1) | SIM_CLKDIV1_OUTDIV4(3);
SIM_CLKDIV2 = SIM_CLKDIV2_USBDIV(1);
#elif defined(KINETISL)
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(1) | SIM_CLKDIV1_OUTDIV4(1);
#endif
#elif F_CPU == 24000000
// config divisors: 24 MHz core, 24 MHz bus, 24 MHz flash, USB = 96 / 2
#if defined(KINETISK)
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(3) | SIM_CLKDIV1_OUTDIV2(3) | SIM_CLKDIV1_OUTDIV3(3) | SIM_CLKDIV1_OUTDIV4(3);
SIM_CLKDIV2 = SIM_CLKDIV2_USBDIV(1);
#elif defined(KINETISL)
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(3) | SIM_CLKDIV1_OUTDIV4(0);
#endif
#elif F_CPU == 16000000
// config divisors: 16 MHz core, 16 MHz bus, 16 MHz flash
#if defined(KINETISK)
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(0) | SIM_CLKDIV1_OUTDIV3(0) | SIM_CLKDIV1_OUTDIV4(0);
#elif defined(KINETISL)
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV4(0);
#endif
#elif F_CPU == 8000000
// config divisors: 8 MHz core, 8 MHz bus, 8 MHz flash
#if defined(KINETISK)
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(1) | SIM_CLKDIV1_OUTDIV2(1) | SIM_CLKDIV1_OUTDIV3(1) | SIM_CLKDIV1_OUTDIV4(1);
#elif defined(KINETISL)
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(1) | SIM_CLKDIV1_OUTDIV4(0);
#endif
#elif F_CPU == 4000000
// config divisors: 4 MHz core, 4 MHz bus, 2 MHz flash
// since we are running from external clock 16MHz
// fix outdiv too -> cpu 16/4, bus 16/4, flash 16/4
// here we can go into vlpr?
// config divisors: 4 MHz core, 4 MHz bus, 4 MHz flash
#if defined(KINETISK)
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(3) | SIM_CLKDIV1_OUTDIV2(3) | SIM_CLKDIV1_OUTDIV3(3) | SIM_CLKDIV1_OUTDIV4(3);
#elif defined(KINETISL)
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(3) | SIM_CLKDIV1_OUTDIV4(0);
#endif
#elif F_CPU == 2000000
// since we are running from the fast internal reference clock 4MHz
// but is divided down by 2 so we actually have a 2MHz, MCG_SC[FCDIV] default is 2
// fix outdiv -> cpu 2/1, bus 2/1, flash 2/2
// config divisors: 2 MHz core, 2 MHz bus, 1 MHz flash
#if defined(KINETISK)
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV2(0) | SIM_CLKDIV1_OUTDIV4(1);
#elif defined(KINETISL)
// config divisors: 2 MHz core, 1 MHz bus, 1 MHz flash
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIV1(0) | SIM_CLKDIV1_OUTDIV4(1);
#endif
#else
#error "Error, F_CPU must be 256, 240, 216, 192, 180, 168, 144, 120, 96, 72, 48, 24, 16, 8, 4, or 2 MHz"
#endif
#if F_CPU > 16000000
// switch to PLL as clock source, FLL input = 16 MHz / 512
MCG_C1 = MCG_C1_CLKS(0) | MCG_C1_FRDIV(4);
// wait for PLL clock to be used
while ((MCG_S & MCG_S_CLKST_MASK) != MCG_S_CLKST(3)) ;
// now we're in PEE mode
// trace is CPU clock, CLKOUT=OSCERCLK0
#if defined(KINETISK)
#if F_CPU == 256000000 || F_CPU == 216000000 || F_CPU == 180000000
// USB uses IRC48
SIM_SOPT2 = SIM_SOPT2_USBSRC | SIM_SOPT2_IRC48SEL | SIM_SOPT2_TRACECLKSEL | SIM_SOPT2_CLKOUTSEL(6);
#else
// USB uses PLL clock
SIM_SOPT2 = SIM_SOPT2_USBSRC | SIM_SOPT2_PLLFLLSEL | SIM_SOPT2_TRACECLKSEL | SIM_SOPT2_CLKOUTSEL(6);
#endif
#elif defined(KINETISL)
SIM_SOPT2 = SIM_SOPT2_USBSRC | SIM_SOPT2_PLLFLLSEL | SIM_SOPT2_CLKOUTSEL(6)
| SIM_SOPT2_UART0SRC(1) | SIM_SOPT2_TPMSRC(1);
#endif
#else
#if F_CPU == 2000000
SIM_SOPT2 = SIM_SOPT2_TRACECLKSEL | SIM_SOPT2_CLKOUTSEL(4) | SIM_SOPT2_UART0SRC(3);
#else
SIM_SOPT2 = SIM_SOPT2_TRACECLKSEL | SIM_SOPT2_CLKOUTSEL(6) | SIM_SOPT2_UART0SRC(2);
#endif
#endif
#if F_CPU <= 2000000
// since we are not going into "stop mode" i removed it
SMC_PMCTRL = SMC_PMCTRL_RUNM(2); // VLPR mode :-)
#endif
#if defined(__MK66FX1M0__)
// If the RTC oscillator isn't enabled, get it started. For Teensy 3.6
// we don't do this early. See comment above about slow rising power.
if (!(RTC_CR & RTC_CR_OSCE)) {
RTC_SR = 0;
RTC_CR = RTC_CR_SC16P | RTC_CR_SC4P | RTC_CR_OSCE;
}
#endif
// initialize the SysTick counter
SYST_RVR = (F_CPU / 1000) - 1;
SYST_CVR = 0;
SYST_CSR = SYST_CSR_CLKSOURCE | SYST_CSR_TICKINT | SYST_CSR_ENABLE;
SCB_SHPR3 = 0x20200000; // Systick = priority 32
// Earliest point when the K64F can change the GPIO pins.
// This macro sets the CTL_BUSRQ signal as an output and low to halt the Z80 from going through its startup
// procedure. This then gives the needed time for the K64F to startup and bring the SD card online so
// that the tranZPUter board can be configured before releasing the Z80.
//
//#if defined __TRANZPUTER__
// holdZ80();
//#endif
//init_pins();
__enable_irq();
_init_Teensyduino_internal_();
#if defined(KINETISK)
// RTC initialization
if (RTC_SR & RTC_SR_TIF) {
// this code will normally run on a power-up reset
// when VBAT has detected a power-up. Normally our
// compiled-in time will be stale. Write a special
// flag into the VBAT register file indicating the
// RTC is set with known-stale time and should be
// updated when fresh time is known.
#if ARDUINO >= 10600
rtc_set((uint32_t)&__rtc_localtime);
#else
rtc_set(TIME_T);
#endif
*(uint32_t *)0x4003E01C = 0x5A94C3A5;
}
if ((RCM_SRS0 & RCM_SRS0_PIN) && (*(uint32_t *)0x4003E01C == 0x5A94C3A5)) {
// this code should run immediately after an upload
// where the Teensy Loader causes the Mini54 to reset.
// Our compiled-in time will be very fresh, so set
// the RTC with this, and clear the VBAT resister file
// data so we don't mess with the time after it's been
// set well.
#if ARDUINO >= 10600
rtc_set((uint32_t)&__rtc_localtime);
#else
rtc_set(TIME_T);
#endif
*(uint32_t *)0x4003E01C = 0;
}
#endif
__libc_init_array();
startup_late_hook();
main();
while (1) ;
}
char *__brkval = (char *)&_ebss;
#ifndef STACK_MARGIN
#if defined(__MKL26Z64__)
#define STACK_MARGIN 512
#elif defined(__MK20DX128__)
#define STACK_MARGIN 1024
#elif defined(__MK20DX256__)
#define STACK_MARGIN 4096
#elif defined(__MK64FX512__) || defined(__MK66FX1M0__)
#define STACK_MARGIN 8192
#endif
#endif
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wunused-parameter"
void * _sbrk(int incr)
{
char *prev, *stack;
prev = __brkval;
if (incr != 0) {
__asm__ volatile("mov %0, sp" : "=r" (stack) ::);
if (prev + incr >= stack - STACK_MARGIN) {
errno = ENOMEM;
return (void *)-1;
}
__brkval = prev + incr;
}
return prev;
}
int _write(int file, char *ptr, int len)
{
int count = len;
if (file == 1) { // stdout
while (count > 0)
{
if(*ptr == '\n')
{
usb_serial_putchar('\r');
}
usb_serial_putchar(*ptr);
++ptr;
--count;
}
}
return len;
}
int __putchar(int c)
{
return(usb_serial_putchar(c));
}
int _read(int file, char *ptr, int len)
{
int i = 0;
int t;
for (i = 0; i < len; i++)
{
while((t=usb_serial_getchar()) == -1);
if (((char)t != '\r') && ((char)t != '\n'))
{
*(ptr + i) = t;
usb_serial_putchar(t); // echo
} else
{
// terminate the line in the way expected by the libraries
*(ptr + i) = '\n';
i++;
usb_serial_putchar('\r');
usb_serial_putchar('\n');
break;
}
}
return (i);
}
__attribute__((weak))
int _close(int fd)
{
return -1;
}
#include <sys/stat.h>
__attribute__((weak))
int _fstat(int fd, struct stat *st)
{
st->st_mode = S_IFCHR;
return 0;
}
__attribute__((weak))
int _isatty(int fd)
{
return 1;
}
__attribute__((weak))
int _lseek(int fd, long long offset, int whence)
{
return -1;
}
__attribute__((weak))
void _exit(int status)
{
while (1);
}
__attribute__((weak))
void __cxa_pure_virtual()
{
while (1);
}
__attribute__((weak))
int __cxa_guard_acquire (char *g)
{
return !(*g);
}
__attribute__((weak))
void __cxa_guard_release(char *g)
{
*g = 1;
}
__attribute__((weak))
void abort(void)
{
while (1) ;
}
#pragma GCC diagnostic pop
int nvic_execution_priority(void)
{
uint32_t priority=256;
uint32_t primask, faultmask, basepri, ipsr;
// full algorithm in ARM DDI0403D, page B1-639
// this isn't quite complete, but hopefully good enough
__asm__ volatile("mrs %0, faultmask\n" : "=r" (faultmask)::);
if (faultmask) return -1;
__asm__ volatile("mrs %0, primask\n" : "=r" (primask)::);
if (primask) return 0;
__asm__ volatile("mrs %0, ipsr\n" : "=r" (ipsr)::);
if (ipsr) {
if (ipsr < 16) priority = 0; // could be non-zero
else priority = NVIC_GET_PRIORITY(ipsr - 16);
}
__asm__ volatile("mrs %0, basepri\n" : "=r" (basepri)::);
if (basepri > 0 && basepri < priority) priority = basepri;
return priority;
}
#if defined(HAS_KINETIS_HSRUN) && F_CPU > 120000000
int kinetis_hsrun_disable(void)
{
if (SMC_PMSTAT == SMC_PMSTAT_HSRUN) {
// First, reduce the CPU clock speed, but do not change
// the peripheral speed (F_BUS). Serial1 & Serial2 baud
// rates will be impacted, but most other peripherals
// will continue functioning at the same speed.
#if F_CPU == 256000000 && F_BUS == 64000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(1, 3, 1, 7); // TODO: TEST
#elif F_CPU == 256000000 && F_BUS == 128000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(1, 1, 1, 7); // TODO: TEST
#elif F_CPU == 240000000 && F_BUS == 60000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(1, 3, 1, 7); // ok
#elif F_CPU == 240000000 && F_BUS == 80000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(2, 2, 2, 8); // ok
#elif F_CPU == 240000000 && F_BUS == 120000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(1, 1, 1, 7); // ok
#elif F_CPU == 216000000 && F_BUS == 54000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(1, 3, 1, 7); // ok
#elif F_CPU == 216000000 && F_BUS == 72000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(2, 2, 2, 8); // ok
#elif F_CPU == 216000000 && F_BUS == 108000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(1, 1, 1, 7); // ok
#elif F_CPU == 192000000 && F_BUS == 48000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(1, 3, 1, 7); // ok
#elif F_CPU == 192000000 && F_BUS == 64000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(2, 2, 2, 8); // ok
#elif F_CPU == 192000000 && F_BUS == 96000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(1, 1, 1, 7); // ok
#elif F_CPU == 180000000 && F_BUS == 60000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(2, 2, 2, 8); // ok
#elif F_CPU == 180000000 && F_BUS == 90000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(1, 1, 1, 7); // ok
#elif F_CPU == 168000000 && F_BUS == 56000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(2, 2, 2, 5); // ok
#elif F_CPU == 144000000 && F_BUS == 48000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(2, 2, 2, 5); // ok
#elif F_CPU == 144000000 && F_BUS == 72000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(1, 1, 1, 5); // ok
#else
return 0;
#endif
// Then turn off HSRUN mode
SMC_PMCTRL = SMC_PMCTRL_RUNM(0);
while (SMC_PMSTAT == SMC_PMSTAT_HSRUN) ; // wait
return 1;
}
return 0;
}
int kinetis_hsrun_enable(void)
{
if (SMC_PMSTAT == SMC_PMSTAT_RUN) {
// Turn HSRUN mode on
SMC_PMCTRL = SMC_PMCTRL_RUNM(3);
while (SMC_PMSTAT != SMC_PMSTAT_HSRUN) {;} // wait
// Then configure clock for full speed
#if F_CPU == 256000000 && F_BUS == 64000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 3, 0, 7);
#elif F_CPU == 256000000 && F_BUS == 128000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 1, 0, 7);
#elif F_CPU == 240000000 && F_BUS == 60000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 3, 0, 7);
#elif F_CPU == 240000000 && F_BUS == 80000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 2, 0, 7);
#elif F_CPU == 240000000 && F_BUS == 120000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 1, 0, 7);
#elif F_CPU == 216000000 && F_BUS == 54000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 3, 0, 7);
#elif F_CPU == 216000000 && F_BUS == 72000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 2, 0, 7);
#elif F_CPU == 216000000 && F_BUS == 108000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 1, 0, 7);
#elif F_CPU == 192000000 && F_BUS == 48000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 3, 0, 6);
#elif F_CPU == 192000000 && F_BUS == 64000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 2, 0, 6);
#elif F_CPU == 192000000 && F_BUS == 96000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 1, 0, 6);
#elif F_CPU == 180000000 && F_BUS == 60000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 2, 0, 6);
#elif F_CPU == 180000000 && F_BUS == 90000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 1, 0, 6);
#elif F_CPU == 168000000 && F_BUS == 56000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 2, 0, 5);
#elif F_CPU == 144000000 && F_BUS == 48000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 2, 0, 4);
#elif F_CPU == 144000000 && F_BUS == 72000000
SIM_CLKDIV1 = SIM_CLKDIV1_OUTDIVS(0, 1, 0, 4);
#else
return 0;
#endif
return 1;
}
return 0;
}
#endif // HAS_KINETIS_HSRUN && F_CPU > 120000000
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