Firmwares/raven/bsp/env/coreplexip-arty.h

103 lines
3.3 KiB
C

// See LICENSE for license details.
#ifndef _SIFIVE_COREPLEXIP_ARTY_H
#define _SIFIVE_COREPLEXIP_ARTY_H
#include <stdint.h>
/****************************************************************************
* GPIO Connections
*****************************************************************************/
// These are the GPIO bit offsets for the directly driven
// RGB LEDs on the Freedom Exx Coreplex IP Evaluation Arty FPGA Dev Kit.
// Additional RGB LEDs are driven by the 3 PWM outputs.
#define RED_LED_OFFSET 0
#define GREEN_LED_OFFSET 1
#define BLUE_LED_OFFSET 2
// Switch 3 is used as a GPIO input. (Switch 0 is used to set
// the reset vector, the other switches are unused).
#define SW_3_OFFSET 3
// These are the buttons which are mapped as inputs.
#define HAS_BOARD_BUTTONS
#define BUTTON_0_OFFSET 4
#define BUTTON_1_OFFSET 5
#define BUTTON_2_OFFSET 6
#define BUTTON_3_OFFSET 7
// These are the bit offsets for the different GPIO pins
// mapped onto the PMOD A header.
#define JA_0_OFFSET 8
#define JA_1_OFFSET 9
#define JA_2_OFFSET 10
#define JA_3_OFFSET 11
#define JA_4_OFFSET 12
#define JA_5_OFFSET 13
#define JA_6_OFFSET 14
#define JA_7_OFFSET 15
// The below gives a mapping between global interrupt
// sources and their number. Note that on the coreplex
// deliverable, the io_global_interrupts go directly into
// the PLIC. The evaluation image on the FPGA mimics a
// system with peripheral devices which are driving the
// global interrupt lines.
// So, on this image, in order to get an interrupt from
// e.g. pressing BUTTON_0:
// 1) Steps which are external to the delivery coreplex:
// a) The corresponding GPIO pin must be configured as in input
// b) The "interrupt on fall" bit must be set for the GPIO pin
// 2) Steps which would also need to be performed for the delivery coreplex:
// a) The corresponding global interrupt, priority, and threshold must be configured in the PLIC.
// b) The external interrupt bit must be enabled in MSTATUS
// c) Interrupts must be enabled globally in the core.
// Any of the above GPIO pins can be used as global interrupt
// sources by adding their offset to the INT_GPIO_BASE.
// For example, the buttons are shown here:
#define INT_DEVICE_BUTTON_0 (GPIO_INT_BASE + BUTTON_0_OFFSET)
#define INT_DEVICE_BUTTON_1 (GPIO_INT_BASE + BUTTON_1_OFFSET)
#define INT_DEVICE_BUTTON_2 (GPIO_INT_BASE + BUTTON_2_OFFSET)
#define INT_DEVICE_BUTTON_3 (GPIO_INT_BASE + BUTTON_3_OFFSET)
// In addition, the Switches are mapped directly to
// the PLIC (without going through the GPIO Peripheral).
#define INT_EXT_DEVICE_SW_0 (EXTERNAL_INT_BASE + 0)
#define INT_EXT_DEVICE_SW_1 (EXTERNAL_INT_BASE + 1)
#define INT_EXT_DEVICE_SW_2 (EXTERNAL_INT_BASE + 2)
#define INT_EXT_DEVICE_SW_3 (EXTERNAL_INT_BASE + 3)
// This gives the mapping from inputs to LOCAL interrupts.
#define LOCAL_INT_SW_0 0
#define LOCAL_INT_SW_1 1
#define LOCAL_INT_SW_2 2
#define LOCAL_INT_SW_3 3
#define LOCAL_INT_BTN_0 4
#define LOCAL_INT_BTN_1 5
#define LOCAL_INT_BTN_2 6
#define LOCAL_INT_BTN_3 7
#define LOCAL_INT_JA_0 8
#define LOCAL_INT_JA_1 9
#define LOCAL_INT_JA_2 10
#define LOCAL_INT_JA_3 11
#define LOCAL_INT_JA_4 12
#define LOCAL_INT_JA_5 13
#define LOCAL_INT_JA_6 14
#define LOCAL_INT_JA_7 15
#define RTC_FREQ 32768
void write_hex(int fd, unsigned long int hex);
#endif /* _SIFIVE_COREPLEXIP_ARTY_H */