/* Copyright (c) 2012-2015 Ben Croston 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: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. 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 #include #include #include #include #include #include "c_gpio.h" #define BCM2708_PERI_BASE_DEFAULT 0x20000000 #define BCM2709_PERI_BASE_DEFAULT 0x3f000000 #define GPIO_BASE_OFFSET 0x200000 #define FSEL_OFFSET 0 // 0x0000 #define SET_OFFSET 7 // 0x001c / 4 #define CLR_OFFSET 10 // 0x0028 / 4 #define PINLEVEL_OFFSET 13 // 0x0034 / 4 #define EVENT_DETECT_OFFSET 16 // 0x0040 / 4 #define RISING_ED_OFFSET 19 // 0x004c / 4 #define FALLING_ED_OFFSET 22 // 0x0058 / 4 #define HIGH_DETECT_OFFSET 25 // 0x0064 / 4 #define LOW_DETECT_OFFSET 28 // 0x0070 / 4 #define PULLUPDN_OFFSET 37 // 0x0094 / 4 #define PULLUPDNCLK_OFFSET 38 // 0x0098 / 4 #define PAGE_SIZE (4*1024) #define BLOCK_SIZE (4*1024) // // For Pine A64/A64+ Board // #define PINEA64_GPIO_MASK (0xFFFFFF80) #define SUNXI_GPIO_BASE 0x01C20000 #define SUNXI_GPIO_REG_OFFSET 0x800 #define PINEA64_GPIO_BASE (SUNXI_GPIO_BASE + SUNXI_GPIO_REG_OFFSET) #define SUNXI_CFG_OFFSET 0x00 #define SUNXI_DATA_OFFSET 0x10 #define SUNXI_PUD_OFFSET 0x1C #define SUNXI_BANK_SIZE 0x24 #define MAP_SIZE (4096*2) #define MAP_MASK (MAP_SIZE - 1) typedef struct sunxi_gpio { unsigned int CFG[4]; unsigned int DAT; unsigned int DRV[2]; unsigned int PULL[2]; } sunxi_gpio_t; /* gpio interrupt control */ typedef struct sunxi_gpio_int { unsigned int CFG[3]; unsigned int CTL; unsigned int STA; unsigned int DEB; } sunxi_gpio_int_t; typedef struct sunxi_gpio_reg { struct sunxi_gpio gpio_bank[9]; unsigned char res[0xbc]; struct sunxi_gpio_int gpio_int; } sunxi_gpio_reg_t; #define GPIO_BANK(pin) ((pin) >> 5) #define GPIO_NUM(pin) ((pin) & 0x1F) #define GPIO_CFG_INDEX(pin) (((pin) & 0x1F) >> 3) #define GPIO_CFG_OFFSET(pin) ((((pin) & 0x1F) & 0x7) << 2) #define GPIO_PUL_INDEX(pin) (((pin) & 0x1F )>> 4) #define GPIO_PUL_OFFSET(pin) (((pin) & 0x0F) << 1) int pinea64_found = 1; static volatile uint32_t *pio_map; // end of Pine A64/A64+ static volatile uint32_t *gpio_map; void short_wait(void) { int i; for (i=0; i<150; i++) { // wait 150 cycles asm volatile("nop"); } } int setup(void) { int mem_fd; uint8_t *gpio_mem; uint32_t peri_base; uint32_t gpio_base; unsigned char buf[4]; FILE *fp; char buffer[1024]; char hardware[1024]; int found = 0; pinea64_found = 1; if ( !pinea64_found ) { // try /dev/gpiomem first - this does not require root privs if ((mem_fd = open("/dev/gpiomem", O_RDWR|O_SYNC)) > 0) { gpio_map = (uint32_t *)mmap(NULL, BLOCK_SIZE, PROT_READ|PROT_WRITE, MAP_SHARED, mem_fd, 0); if ((uint32_t)gpio_map < 0) { return SETUP_MMAP_FAIL; } else { return SETUP_OK; } } // revert to /dev/mem method - requires root // determine peri_base if ((fp = fopen("/proc/device-tree/soc/ranges", "rb")) != NULL) { // get peri base from device tree fseek(fp, 4, SEEK_SET); if (fread(buf, 1, sizeof buf, fp) == sizeof buf) { peri_base = buf[0] << 24 | buf[1] << 16 | buf[2] << 8 | buf[3] << 0; } fclose(fp); } else { // guess peri base based on /proc/cpuinfo hardware field if ((fp = fopen("/proc/cpuinfo", "r")) == NULL) return SETUP_CPUINFO_FAIL; while(!feof(fp) && !found) { fgets(buffer, sizeof(buffer), fp); sscanf(buffer, "Hardware : %s", hardware); if (strcmp(hardware, "BCM2708") == 0 || strcmp(hardware, "BCM2835") == 0) { // pi 1 hardware peri_base = BCM2708_PERI_BASE_DEFAULT; found = 1; } else if (strcmp(hardware, "BCM2709") == 0 || strcmp(hardware, "BCM2836") == 0) { // pi 2 hardware peri_base = BCM2709_PERI_BASE_DEFAULT; found = 1; } } fclose(fp); if (!found) return SETUP_NOT_RPI_FAIL; } gpio_base = peri_base + GPIO_BASE_OFFSET; } // mmap the GPIO memory registers if ((mem_fd = open("/dev/mem", O_RDWR|O_SYNC) ) < 0) return SETUP_DEVMEM_FAIL; if ((gpio_mem = malloc(BLOCK_SIZE + (PAGE_SIZE-1))) == NULL) return SETUP_MALLOC_FAIL; if ((uint32_t)gpio_mem % PAGE_SIZE) gpio_mem += PAGE_SIZE - ((uint32_t)gpio_mem % PAGE_SIZE); if ( pinea64_found ) { gpio_map = (uint32_t *)mmap( (caddr_t)gpio_mem, BLOCK_SIZE, PROT_READ|PROT_WRITE, MAP_SHARED|MAP_FIXED, mem_fd, SUNXI_GPIO_BASE); pio_map = gpio_map + (SUNXI_GPIO_REG_OFFSET>>2); } else { gpio_map = (uint32_t *)mmap( (void *)gpio_mem, BLOCK_SIZE, PROT_READ|PROT_WRITE, MAP_SHARED|MAP_FIXED, mem_fd, gpio_base); } if ((uint32_t)gpio_map < 0) return SETUP_MMAP_FAIL; return SETUP_OK; } void clear_event_detect(int gpio) { if ( !pinea64_found ) { int offset = EVENT_DETECT_OFFSET + (gpio/32); int shift = (gpio%32); *(gpio_map+offset) |= (1 << shift); short_wait(); *(gpio_map+offset) = 0; } } int eventdetected(int gpio) { if ( !pinea64_found ) { int offset, value, bit; offset = EVENT_DETECT_OFFSET + (gpio/32); bit = (1 << (gpio%32)); value = *(gpio_map+offset) & bit; if (value) clear_event_detect(gpio); return value; } } void set_rising_event(int gpio, int enable) { if ( !pinea64_found ) { int offset = RISING_ED_OFFSET + (gpio/32); int shift = (gpio%32); if (enable) *(gpio_map+offset) |= 1 << shift; else *(gpio_map+offset) &= ~(1 << shift); clear_event_detect(gpio); } } void set_falling_event(int gpio, int enable) { if ( !pinea64_found ) { int offset = FALLING_ED_OFFSET + (gpio/32); int shift = (gpio%32); if (enable) { *(gpio_map+offset) |= (1 << shift); *(gpio_map+offset) = (1 << shift); } else { *(gpio_map+offset) &= ~(1 << shift); } clear_event_detect(gpio); } } void set_high_event(int gpio, int enable) { if ( !pinea64_found ) { int offset = HIGH_DETECT_OFFSET + (gpio/32); int shift = (gpio%32); if (enable) *(gpio_map+offset) |= (1 << shift); else *(gpio_map+offset) &= ~(1 << shift); clear_event_detect(gpio); } } void set_low_event(int gpio, int enable) { if ( !pinea64_found ) { int offset = LOW_DETECT_OFFSET + (gpio/32); int shift = (gpio%32); if (enable) *(gpio_map+offset) |= 1 << shift; else *(gpio_map+offset) &= ~(1 << shift); clear_event_detect(gpio); } } uint32_t sunxi_readl(volatile uint32_t *addr) { uint32_t val = 0; uint32_t mmap_base = (uint32_t)addr & (~MAP_MASK); uint32_t mmap_seek = ((uint32_t)addr - mmap_base) >> 2; val = *(gpio_map + mmap_seek); return val; } void sunxi_writel(volatile uint32_t *addr, uint32_t val) { uint32_t mmap_base = (uint32_t)addr & (~MAP_MASK); uint32_t mmap_seek =( (uint32_t)addr - mmap_base) >> 2; *(gpio_map + mmap_seek) = val; } void set_pullupdn(int gpio, int pud) { if ( pinea64_found ) { uint32_t regval = 0; int bank = GPIO_BANK(gpio); //gpio >> 5 int index = GPIO_PUL_INDEX(gpio); // (gpio & 0x1f) >> 4 int offset = GPIO_PUL_OFFSET(gpio); // (gpio) & 0x0F) << 1 sunxi_gpio_t *pio = &((sunxi_gpio_reg_t *) pio_map)->gpio_bank[bank]; regval = *(&pio->PULL[0] + index); regval &= ~(3 << offset); regval |= pud << offset; *(&pio->PULL[0] + index) = regval; } else { int clk_offset = PULLUPDNCLK_OFFSET + (gpio/32); int shift = (gpio%32); if (pud == PUD_DOWN) *(gpio_map+PULLUPDN_OFFSET) = (*(gpio_map+PULLUPDN_OFFSET) & ~3) | PUD_DOWN; else if (pud == PUD_UP) *(gpio_map+PULLUPDN_OFFSET) = (*(gpio_map+PULLUPDN_OFFSET) & ~3) | PUD_UP; else // pud == PUD_OFF *(gpio_map+PULLUPDN_OFFSET) &= ~3; short_wait(); *(gpio_map+clk_offset) = 1 << shift; short_wait(); *(gpio_map+PULLUPDN_OFFSET) &= ~3; *(gpio_map+clk_offset) = 0; } } void setup_gpio(int gpio, int direction, int pud) { if ( pinea64_found ) { uint32_t regval = 0; int bank = GPIO_BANK(gpio); //gpio >> 5 int index = GPIO_CFG_INDEX(gpio); // (gpio & 0x1F) >> 3 int offset = GPIO_CFG_OFFSET(gpio); // ((gpio & 0x1F) & 0x7) << 2 sunxi_gpio_t *pio = &((sunxi_gpio_reg_t *) pio_map)->gpio_bank[bank]; set_pullupdn(gpio, pud); regval = *(&pio->CFG[0] + index); regval &= ~(0x7 << offset); // 0xf? if (INPUT == direction) { *(&pio->CFG[0] + index) = regval; } else if (OUTPUT == direction) { regval |= (1 << offset); *(&pio->CFG[0] + index) = regval; } else { printf("line:%dgpio number error\n",__LINE__); } } else { int offset = FSEL_OFFSET + (gpio/10); int shift = (gpio%10)*3; set_pullupdn(gpio, pud); if (direction == OUTPUT) *(gpio_map+offset) = (*(gpio_map+offset) & ~(7< int gpio_function(int gpio) { if ( pinea64_found ) { uint32_t regval = 0; int bank = GPIO_BANK(gpio); //gpio >> 5 int index = GPIO_CFG_INDEX(gpio); // (gpio & 0x1F) >> 3 int offset = GPIO_CFG_OFFSET(gpio); // ((gpio & 0x1F) & 0x7) << 2 sunxi_gpio_t *pio = &((sunxi_gpio_reg_t *) pio_map)->gpio_bank[bank]; regval = *(&pio->CFG[0] + index); regval >>= offset; regval &= 7; return regval; // 0=input, 1=output, 4=alt0 } else { int offset = FSEL_OFFSET + (gpio/10); int shift = (gpio%10)*3; int value = *(gpio_map+offset); value >>= shift; value &= 7; return value; // 0=input, 1=output, 4=alt0 } } void output_gpio(int gpio, int value) { if ( pinea64_found ) { int bank = GPIO_BANK(gpio); //gpio >> 5 int num = GPIO_NUM(gpio); // gpio & 0x1F sunxi_gpio_t *pio = &((sunxi_gpio_reg_t *) pio_map)->gpio_bank[bank]; if (value == 0) *(&pio->DAT) &= ~(1 << num); else *(&pio->DAT) |= (1 << num); } else { int offset, shift; if (value) // value == HIGH offset = SET_OFFSET + (gpio/32); else // value == LOW offset = CLR_OFFSET + (gpio/32); shift = (gpio%32); *(gpio_map+offset) = 1 << shift; } } int input_gpio(int gpio) { if ( pinea64_found ) { uint32_t regval = 0; int bank = GPIO_BANK(gpio); //gpio >> 5 int num = GPIO_NUM(gpio); // gpio & 0x1F sunxi_gpio_t *pio = &((sunxi_gpio_reg_t *) pio_map)->gpio_bank[bank]; regval = *(&pio->DAT); regval = regval >> num; regval &= 1; return regval; } else { int offset, value, mask; offset = PINLEVEL_OFFSET + (gpio/32); mask = (1 << gpio%32); value = *(gpio_map+offset) & mask; return value; } } void cleanup(void) { munmap((void *)gpio_map, BLOCK_SIZE); }