Create separate xspn-fpga FW

Add xspn data for different accelerators
This commit is contained in:
Johannes Wirth 2021-03-04 11:19:35 +01:00
parent 7f8ddf3201
commit 6bfe684e73
110 changed files with 52472 additions and 35 deletions

28
fpga_spn/.project Normal file
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<?xml version="1.0" encoding="UTF-8"?>
<projectDescription>
<name>raven_spn</name>
<comment></comment>
<projects>
<project>bsp</project>
</projects>
<buildSpec>
<buildCommand>
<name>org.eclipse.cdt.managedbuilder.core.genmakebuilder</name>
<triggers>clean,full,incremental,</triggers>
<arguments>
</arguments>
</buildCommand>
<buildCommand>
<name>org.eclipse.cdt.managedbuilder.core.ScannerConfigBuilder</name>
<triggers>full,incremental,</triggers>
<arguments>
</arguments>
</buildCommand>
</buildSpec>
<natures>
<nature>org.eclipse.cdt.core.cnature</nature>
<nature>org.eclipse.cdt.core.ccnature</nature>
<nature>org.eclipse.cdt.managedbuilder.core.managedBuildNature</nature>
<nature>org.eclipse.cdt.managedbuilder.core.ScannerConfigNature</nature>
</natures>
</projectDescription>

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fpga_spn/Makefile Normal file
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TARGET = raven_spn
C_SRCS = $(wildcard src/*.c) $(BSP_BASE)/drivers/fe300prci/fe300prci_driver.c $(BSP_BASE)/drivers/plic/plic_driver.c
CXX_SRCS = $(wildcard src/*.cpp)
HEADERS = $(wildcard src/*.h)
CFLAGS = -g -fno-builtin-printf -DUSE_PLIC -I./src
CXXFLAGS = -fno-use-cxa-atexit
LDFLAGS += -g -lstdc++ -fno-use-cxa-atexit -march=$(RISCV_ARCH) -mabi=$(RISCV_ABI) -mcmodel=medany
BOARD=freedom-e300-hifive1
LINK_TARGET=flash
RISCV_ARCH=rv32imac
RISCV_ABI=ilp32
TOOL_DIR=/opt/shared/riscv/tools/Ubuntu/riscv64-unknown-elf-gcc-8.3.0-2020.04.1-x86_64-linux-ubuntu14/bin
BSP_BASE = ./bsp
include $(BSP_BASE)/env/common.mk
.PHONY: all
all: $(TARGET).dump
$(TARGET).dump: $(TARGET)
$(TOOL_DIR)/$(TRIPLET)-objdump -d -S -C $< > $@

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// See LICENSE for license details.
#include "sifive/devices/clic.h"
#include "clic/clic_driver.h"
#include "platform.h"
#include "encoding.h"
#include <string.h>
void volatile_memzero(uint8_t * base, unsigned int size) {
volatile uint8_t * ptr;
for (ptr = base; ptr < (base + size); ptr++){
*ptr = 0;
}
}
// Note that there are no assertions or bounds checking on these
// parameter values.
void clic_init (
clic_instance_t * this_clic,
uintptr_t hart_addr,
interrupt_function_ptr_t* vect_table,
interrupt_function_ptr_t default_handler,
uint32_t num_irq,
uint32_t num_config_bits
)
{
this_clic->hart_addr= hart_addr;
this_clic->vect_table= vect_table;
this_clic->num_config_bits= num_config_bits;
//initialize vector table
for(int i=0;i++;i<num_irq) {
this_clic->vect_table[i] = default_handler;
}
//set base vectors
write_csr(mtvt, vect_table);
//clear all interrupt enables and pending
volatile_memzero((uint8_t*)(this_clic->hart_addr+CLIC_INTIE), num_irq);
volatile_memzero((uint8_t*)(this_clic->hart_addr+CLIC_INTIP), num_irq);
//clear nlbits and nvbits; all interrupts trap to level 15
*(volatile uint8_t*)(this_clic->hart_addr+CLIC_CFG)=0;
}
void clic_install_handler (clic_instance_t * this_clic, uint32_t source, interrupt_function_ptr_t handler) {
this_clic->vect_table[source] = handler;
}
void clic_enable_interrupt (clic_instance_t * this_clic, uint32_t source) {
*(volatile uint8_t*)(this_clic->hart_addr+CLIC_INTIE+source) = 1;
}
void clic_disable_interrupt (clic_instance_t * this_clic, uint32_t source){
*(volatile uint8_t*)(this_clic->hart_addr+CLIC_INTIE+source) = 0;
}
void clic_set_pending(clic_instance_t * this_clic, uint32_t source){
*(volatile uint8_t*)(this_clic->hart_addr+CLIC_INTIP+source) = 1;
}
void clic_clear_pending(clic_instance_t * this_clic, uint32_t source){
*(volatile uint8_t*)(this_clic->hart_addr+CLIC_INTIP+source) = 0;
}
void clic_set_intcfg (clic_instance_t * this_clic, uint32_t source, uint32_t intcfg){
*(volatile uint8_t*)(this_clic->hart_addr+CLIC_INTCFG+source) = intcfg;
}
uint8_t clic_get_intcfg (clic_instance_t * this_clic, uint32_t source){
return *(volatile uint8_t*)(this_clic->hart_addr+CLIC_INTCFG+source);
}
void clic_set_cliccfg (clic_instance_t * this_clic, uint32_t cfg){
*(volatile uint8_t*)(this_clic->hart_addr+CLIC_CFG) = cfg;
}
uint8_t clic_get_cliccfg (clic_instance_t * this_clic){
return *(volatile uint8_t*)(this_clic->hart_addr+CLIC_CFG);
}
//sets an interrupt level based encoding of nmbits, nlbits
uint8_t clic_set_int_level( clic_instance_t * this_clic, uint32_t source, uint8_t level) {
//extract nlbits
uint8_t nlbits = clic_get_cliccfg(this_clic);
nlbits = (nlbits >>1) & 0x7;
//shift level right to mask off unused bits
level = level>>((this_clic->num_config_bits)-nlbits); //plus this_clic->nmbits which is always 0 for now.
//shift level into correct bit position
level = level << (8-this_clic->num_config_bits) + (this_clic->num_config_bits - nlbits);
//write to clicintcfg
uint8_t current_intcfg = clic_get_intcfg(this_clic, source);
clic_set_intcfg(this_clic, source, (current_intcfg | level));
return level;
}
//gets an interrupt level based encoding of nmbits, nlbits
uint8_t clic_get_int_level( clic_instance_t * this_clic, uint32_t source) {
uint8_t level;
level = clic_get_intcfg(this_clic, source);
//extract nlbits
uint8_t nlbits = clic_get_cliccfg(this_clic);
nlbits = (nlbits >>1) & 0x7;
//shift level
level = level >> (8-(this_clic->num_config_bits));
//shift level right to mask off priority bits
level = level>>(this_clic->num_config_bits-nlbits); //this_clic->nmbits which is always 0 for now.
return level;
}
//sets an interrupt priority based encoding of nmbits, nlbits
uint8_t clic_set_int_priority( clic_instance_t * this_clic, uint32_t source, uint8_t priority) {
//priority bits = num_config_bits - nlbits
//extract nlbits
uint8_t nlbits = clic_get_cliccfg(this_clic);
nlbits = (nlbits >>1) & 0x7;
uint8_t priority_bits = this_clic->num_config_bits-nlbits;
if(priority_bits = 0) {
//no bits to set
return 0;
}
//mask off unused bits
priority = priority >> (8-priority_bits);
//shift into the correct bit position
priority = priority << (8-(this_clic->num_config_bits));
//write to clicintcfg
uint8_t current_intcfg = clic_get_intcfg(this_clic, source);
clic_set_intcfg(this_clic, source, (current_intcfg | priority));
return current_intcfg;
}
//gets an interrupt priority based encoding of nmbits, nlbits
uint8_t clic_get_int_priority( clic_instance_t * this_clic, uint32_t source) {
uint8_t priority;
priority = clic_get_intcfg(this_clic, source);
//extract nlbits
uint8_t nlbits = clic_get_cliccfg(this_clic);
nlbits = (nlbits >>1) & 0x7;
//shift left to mask off level bits
priority = priority << nlbits;
//shift priority
priority = priority >> (8-((this_clic->num_config_bits)+nlbits));
return priority;
}

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// See LICENSE file for licence details
#ifndef PLIC_DRIVER_H
#define PLIC_DRIVER_H
__BEGIN_DECLS
#include "platform.h"
typedef void (*interrupt_function_ptr_t) (void);
typedef struct __clic_instance_t
{
uintptr_t hart_addr;
interrupt_function_ptr_t* vect_table;
uint32_t num_config_bits;
uint32_t num_sources;
} clic_instance_t;
// Note that there are no assertions or bounds checking on these
// parameter values.
void clic_init (clic_instance_t * this_clic, uintptr_t hart_addr, interrupt_function_ptr_t* vect_table, interrupt_function_ptr_t default_handler, uint32_t num_irq,uint32_t num_config_bits);
void clic_install_handler (clic_instance_t * this_clic, uint32_t source, interrupt_function_ptr_t handler);
void clic_enable_interrupt (clic_instance_t * this_clic, uint32_t source);
void clic_disable_interrupt (clic_instance_t * this_clic, uint32_t source);
void clic_set_pending(clic_instance_t * this_clic, uint32_t source);
void clic_clear_pending(clic_instance_t * this_clic, uint32_t source);
void clic_set_intcfg (clic_instance_t * this_clic, uint32_t source, uint32_t intcfg);
uint8_t clic_get_intcfg (clic_instance_t * this_clic, uint32_t source);
void clic_set_cliccfg (clic_instance_t * this_clic, uint32_t cfg);
uint8_t clic_get_cliccfg (clic_instance_t * this_clic);
//sets an interrupt level based encoding of nmbits, nlbits
uint8_t clic_set_int_level( clic_instance_t * this_clic, uint32_t source, uint8_t level);
//get an interrupt level based encoding of nmbits, nlbits
uint8_t clic_get_int_level( clic_instance_t * this_clic, uint32_t source);
//sets an interrupt priority based encoding of nmbits, nlbits
uint8_t clic_set_int_priority( clic_instance_t * this_clic, uint32_t source, uint8_t priority);
//sets an interrupt priority based encoding of nmbits, nlbits
uint8_t clic_get_int_priority( clic_instance_t * this_clic, uint32_t source);
__END_DECLS
#endif

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// See LICENSE file for license details
#include "platform.h"
#ifdef PRCI_CTRL_ADDR
#include "fe300prci/fe300prci_driver.h"
#include <unistd.h>
#define rdmcycle(x) { \
uint32_t lo, hi, hi2; \
__asm__ __volatile__ ("1:\n\t" \
"csrr %0, mcycleh\n\t" \
"csrr %1, mcycle\n\t" \
"csrr %2, mcycleh\n\t" \
"bne %0, %2, 1b\n\t" \
: "=r" (hi), "=r" (lo), "=r" (hi2)) ; \
*(x) = lo | ((uint64_t) hi << 32); \
}
uint32_t PRCI_measure_mcycle_freq(uint32_t mtime_ticks, uint32_t mtime_freq)
{
uint32_t start_mtime = CLINT_REG(CLINT_MTIME);
uint32_t end_mtime = start_mtime + mtime_ticks + 1;
// Make sure we won't get rollover.
while (end_mtime < start_mtime){
start_mtime = CLINT_REG(CLINT_MTIME);
end_mtime = start_mtime + mtime_ticks + 1;
}
// Don't start measuring until mtime edge.
uint32_t tmp = start_mtime;
do {
start_mtime = CLINT_REG(CLINT_MTIME);
} while (start_mtime == tmp);
uint64_t start_mcycle;
rdmcycle(&start_mcycle);
while (CLINT_REG(CLINT_MTIME) < end_mtime) ;
uint64_t end_mcycle;
rdmcycle(&end_mcycle);
uint32_t difference = (uint32_t) (end_mcycle - start_mcycle);
uint64_t freq = ((uint64_t) difference * mtime_freq) / mtime_ticks;
return (uint32_t) freq & 0xFFFFFFFF;
}
void PRCI_use_hfrosc(int div, int trim)
{
// Make sure the HFROSC is running at its default setting
// It is OK to change this even if we are running off of it.
PRCI_REG(PRCI_HFROSCCFG) = (ROSC_DIV(div) | ROSC_TRIM(trim) | ROSC_EN(1));
while ((PRCI_REG(PRCI_HFROSCCFG) & ROSC_RDY(1)) == 0);
PRCI_REG(PRCI_PLLCFG) &= ~PLL_SEL(1);
}
void PRCI_use_pll(int refsel, int bypass,
int r, int f, int q, int finaldiv,
int hfroscdiv, int hfrosctrim)
{
// Ensure that we aren't running off the PLL before we mess with it.
if (PRCI_REG(PRCI_PLLCFG) & PLL_SEL(1)) {
// Make sure the HFROSC is running at its default setting
PRCI_use_hfrosc(4, 16);
}
// Set PLL Source to be HFXOSC if desired.
uint32_t config_value = 0;
config_value |= PLL_REFSEL(refsel);
if (bypass) {
// Bypass
config_value |= PLL_BYPASS(1);
PRCI_REG(PRCI_PLLCFG) = config_value;
// If we don't have an HFXTAL, this doesn't really matter.
// Set our Final output divide to divide-by-1:
PRCI_REG(PRCI_PLLDIV) = (PLL_FINAL_DIV_BY_1(1) | PLL_FINAL_DIV(0));
} else {
// To overclock, use the hfrosc
if (hfrosctrim >= 0 && hfroscdiv >= 0) {
PRCI_use_hfrosc(hfroscdiv, hfrosctrim);
}
// Set DIV Settings for PLL
// (Legal values of f_REF are 6-48MHz)
// Set DIVR to divide-by-2 to get 8MHz frequency
// (legal values of f_R are 6-12 MHz)
config_value |= PLL_BYPASS(1);
config_value |= PLL_R(r);
// Set DIVF to get 512Mhz frequncy
// There is an implied multiply-by-2, 16Mhz.
// So need to write 32-1
// (legal values of f_F are 384-768 MHz)
config_value |= PLL_F(f);
// Set DIVQ to divide-by-2 to get 256 MHz frequency
// (legal values of f_Q are 50-400Mhz)
config_value |= PLL_Q(q);
// Set our Final output divide to divide-by-1:
if (finaldiv == 1){
PRCI_REG(PRCI_PLLDIV) = (PLL_FINAL_DIV_BY_1(1) | PLL_FINAL_DIV(0));
} else {
PRCI_REG(PRCI_PLLDIV) = (PLL_FINAL_DIV(finaldiv-1));
}
PRCI_REG(PRCI_PLLCFG) = config_value;
// Un-Bypass the PLL.
PRCI_REG(PRCI_PLLCFG) &= ~PLL_BYPASS(1);
// Wait for PLL Lock
// Note that the Lock signal can be glitchy.
// Need to wait 100 us
// RTC is running at 32kHz.
// So wait 4 ticks of RTC.
uint32_t now = CLINT_REG(CLINT_MTIME);
while (CLINT_REG(CLINT_MTIME) - now < 4) ;
// Now it is safe to check for PLL Lock
while ((PRCI_REG(PRCI_PLLCFG) & PLL_LOCK(1)) == 0);
}
// Switch over to PLL Clock source
PRCI_REG(PRCI_PLLCFG) |= PLL_SEL(1);
// If we're running off HFXOSC, turn off the HFROSC to
// save power.
if (refsel) {
PRCI_REG(PRCI_HFROSCCFG) &= ~ROSC_EN(1);
}
}
void PRCI_use_default_clocks()
{
// Turn off the LFROSC
AON_REG(AON_LFROSC) &= ~ROSC_EN(1);
// Use HFROSC
PRCI_use_hfrosc(4, 16);
}
void PRCI_use_hfxosc(uint32_t finaldiv)
{
PRCI_use_pll(1, // Use HFXTAL
1, // Bypass = 1
0, // PLL settings don't matter
0, // PLL settings don't matter
0, // PLL settings don't matter
finaldiv,
-1,
-1);
}
// This is a generic function, which
// doesn't span the entire range of HFROSC settings.
// It only adjusts the trim, which can span a hundred MHz or so.
// This function does not check the legality of the PLL settings
// at all, and it is quite possible to configure invalid PLL settings
// this way.
// It returns the actual measured CPU frequency.
uint32_t PRCI_set_hfrosctrim_for_f_cpu(uint32_t f_cpu, PRCI_freq_target target )
{
uint32_t hfrosctrim = 0;
uint32_t hfroscdiv = 4;
uint32_t prev_trim = 0;
// In this function we use PLL settings which
// will give us a 32x multiplier from the output
// of the HFROSC source to the output of the
// PLL. We first measure our HFROSC to get the
// right trim, then finally use it as the PLL source.
// We should really check here that the f_cpu
// requested is something in the limit of the PLL. For
// now that is up to the user.
// This will undershoot for frequencies not divisible by 16.
uint32_t desired_hfrosc_freq = (f_cpu/ 16);
PRCI_use_hfrosc(hfroscdiv, hfrosctrim);
// Ignore the first run (for icache reasons)
uint32_t cpu_freq = PRCI_measure_mcycle_freq(3000, RTC_FREQ);
cpu_freq = PRCI_measure_mcycle_freq(3000, RTC_FREQ);
uint32_t prev_freq = cpu_freq;
while ((cpu_freq < desired_hfrosc_freq) && (hfrosctrim < 0x1F)){
prev_trim = hfrosctrim;
prev_freq = cpu_freq;
hfrosctrim ++;
PRCI_use_hfrosc(hfroscdiv, hfrosctrim);
cpu_freq = PRCI_measure_mcycle_freq(3000, RTC_FREQ);
}
// We couldn't go low enough
if (prev_freq > desired_hfrosc_freq){
PRCI_use_pll(0, 0, 1, 31, 1, 1, hfroscdiv, prev_trim);
cpu_freq = PRCI_measure_mcycle_freq(1000, RTC_FREQ);
return cpu_freq;
}
// We couldn't go high enough
if (cpu_freq < desired_hfrosc_freq){
PRCI_use_pll(0, 0, 1, 31, 1, 1, hfroscdiv, prev_trim);
cpu_freq = PRCI_measure_mcycle_freq(1000, RTC_FREQ);
return cpu_freq;
}
// Check for over/undershoot
switch(target) {
case(PRCI_FREQ_CLOSEST):
if ((desired_hfrosc_freq - prev_freq) < (cpu_freq - desired_hfrosc_freq)) {
PRCI_use_pll(0, 0, 1, 31, 1, 1, hfroscdiv, prev_trim);
} else {
PRCI_use_pll(0, 0, 1, 31, 1, 1, hfroscdiv, hfrosctrim);
}
break;
case(PRCI_FREQ_UNDERSHOOT):
PRCI_use_pll(0, 0, 1, 31, 1, 1, hfroscdiv, prev_trim);
break;
default:
PRCI_use_pll(0, 0, 1, 31, 1, 1, hfroscdiv, hfrosctrim);
}
cpu_freq = PRCI_measure_mcycle_freq(1000, RTC_FREQ);
return cpu_freq;
}
#endif

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// See LICENSE file for license details
#ifndef _FE300PRCI_DRIVER_H_
#define _FE300PRCI_DRIVER_H_
__BEGIN_DECLS
#include <unistd.h>
typedef enum prci_freq_target {
PRCI_FREQ_OVERSHOOT,
PRCI_FREQ_CLOSEST,
PRCI_FREQ_UNDERSHOOT
} PRCI_freq_target;
/* Measure and return the approximate frequency of the
* CPU, as given by measuring the mcycle counter against
* the mtime ticks.
*/
uint32_t PRCI_measure_mcycle_freq(uint32_t mtime_ticks, uint32_t mtime_freq);
/* Safely switch over to the HFROSC using the given div
* and trim settings.
*/
void PRCI_use_hfrosc(int div, int trim);
/* Safely switch over to the 16MHz HFXOSC,
* applying the finaldiv clock divider (1 is the lowest
* legal value).
*/
void PRCI_use_hfxosc(uint32_t finaldiv);
/* Safely switch over to the PLL using the given
* settings.
*
* Note that not all combinations of the inputs are actually
* legal, and this function does not check for their
* legality ("safely" means that this function won't turn off
* or glitch the clock the CPU is actually running off, but
* doesn't protect against you making it too fast or slow.)
*/
void PRCI_use_pll(int refsel, int bypass,
int r, int f, int q, int finaldiv,
int hfroscdiv, int hfrosctrim);
/* Use the default clocks configured at reset.
* This is ~16Mhz HFROSC and turns off the LFROSC
* (on the current FE310 Dev Platforms, an external LFROSC is
* used as it is more power efficient).
*/
void PRCI_use_default_clocks();
/* This routine will adjust the HFROSC trim
* while using HFROSC as the clock source,
* measure the resulting frequency, then
* use it as the PLL clock source,
* in an attempt to get over, under, or close to the
* requested frequency. It returns the actual measured
* frequency.
*
* Note that the requested frequency must be within the
* range supported by the PLL so not all values are
* achievable with this function, and not all
* are guaranteed to actually work. The PLL
* is rated higher than the hardware.
*
* There is no check on the desired f_cpu frequency, it
* is up to the user to specify something reasonable.
*/
uint32_t PRCI_set_hfrosctrim_for_f_cpu(uint32_t f_cpu, PRCI_freq_target target);
__END_DECLS
#endif

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// See LICENSE for license details.
#include "sifive/devices/plic.h"
#include "plic/plic_driver.h"
#include "platform.h"
#include "encoding.h"
#include <string.h>
// Note that there are no assertions or bounds checking on these
// parameter values.
void volatile_memzero(uint8_t * base, unsigned int size)
{
volatile uint8_t * ptr;
for (ptr = base; ptr < (base + size); ptr++){
*ptr = 0;
}
}
void PLIC_init (
plic_instance_t * this_plic,
uintptr_t base_addr,
uint32_t num_sources,
uint32_t num_priorities,
uint32_t target_hartid
)
{
this_plic->base_addr = base_addr;
this_plic->num_sources = num_sources;
this_plic->num_priorities = num_priorities;
this_plic->target_hartid = target_hartid;
// Disable all interrupts (don't assume that these registers are reset).
volatile_memzero((uint8_t*) (this_plic->base_addr +
PLIC_ENABLE_OFFSET +
(this_plic->target_hartid << PLIC_ENABLE_SHIFT_PER_TARGET)),
(num_sources + 8) / 8);
// Set all priorities to 0 (equal priority -- don't assume that these are reset).
volatile_memzero ((uint8_t *)(this_plic->base_addr +
PLIC_PRIORITY_OFFSET),
(num_sources + 1) << PLIC_PRIORITY_SHIFT_PER_SOURCE);
// Set the threshold to 0.
volatile plic_threshold* threshold = (plic_threshold*)
(this_plic->base_addr +
PLIC_THRESHOLD_OFFSET +
(this_plic->target_hartid << PLIC_THRESHOLD_SHIFT_PER_TARGET));
*threshold = 0;
}
void PLIC_set_threshold (plic_instance_t * this_plic,
plic_threshold threshold){
volatile plic_threshold* threshold_ptr = (plic_threshold*) (this_plic->base_addr +
PLIC_THRESHOLD_OFFSET +
(this_plic->target_hartid << PLIC_THRESHOLD_SHIFT_PER_TARGET));
*threshold_ptr = threshold;
}
void PLIC_enable_interrupt (plic_instance_t * this_plic, plic_source source){
volatile uint8_t * current_ptr = (volatile uint8_t *)(this_plic->base_addr +
PLIC_ENABLE_OFFSET +
(this_plic->target_hartid << PLIC_ENABLE_SHIFT_PER_TARGET) +
(source >> 3));
uint8_t current = *current_ptr;
current = current | ( 1 << (source & 0x7));
*current_ptr = current;
}
void PLIC_disable_interrupt (plic_instance_t * this_plic, plic_source source){
volatile uint8_t * current_ptr = (volatile uint8_t *) (this_plic->base_addr +
PLIC_ENABLE_OFFSET +
(this_plic->target_hartid << PLIC_ENABLE_SHIFT_PER_TARGET) +
(source >> 3));
uint8_t current = *current_ptr;
current = current & ~(( 1 << (source & 0x7)));
*current_ptr = current;
}
void PLIC_set_priority (plic_instance_t * this_plic, plic_source source, plic_priority priority){
if (this_plic->num_priorities > 0) {
volatile plic_priority * priority_ptr = (volatile plic_priority *)
(this_plic->base_addr +
PLIC_PRIORITY_OFFSET +
(source << PLIC_PRIORITY_SHIFT_PER_SOURCE));
*priority_ptr = priority;
}
}
plic_source PLIC_claim_interrupt(plic_instance_t * this_plic){
volatile plic_source * claim_addr = (volatile plic_source * )
(this_plic->base_addr +
PLIC_CLAIM_OFFSET +
(this_plic->target_hartid << PLIC_CLAIM_SHIFT_PER_TARGET));
return *claim_addr;
}
void PLIC_complete_interrupt(plic_instance_t * this_plic, plic_source source){
volatile plic_source * claim_addr = (volatile plic_source *) (this_plic->base_addr +
PLIC_CLAIM_OFFSET +
(this_plic->target_hartid << PLIC_CLAIM_SHIFT_PER_TARGET));
*claim_addr = source;
}

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// See LICENSE file for licence details
#ifndef PLIC_DRIVER_H
#define PLIC_DRIVER_H
__BEGIN_DECLS
#include "platform.h"
typedef struct __plic_instance_t
{
uintptr_t base_addr;
uint32_t num_sources;
uint32_t num_priorities;
uint32_t target_hartid;
} plic_instance_t;
typedef uint32_t plic_source;
typedef uint32_t plic_priority;
typedef uint32_t plic_threshold;
void PLIC_init (
plic_instance_t * this_plic,
uintptr_t base_addr,
uint32_t num_sources,
uint32_t num_priorities,
uint32_t target_hartid
);
void PLIC_set_threshold (plic_instance_t * this_plic,
plic_threshold threshold);
void PLIC_enable_interrupt (plic_instance_t * this_plic,
plic_source source);
void PLIC_disable_interrupt (plic_instance_t * this_plic,
plic_source source);
void PLIC_set_priority (plic_instance_t * this_plic,
plic_source source,
plic_priority priority);
plic_source PLIC_claim_interrupt(plic_instance_t * this_plic);
void PLIC_complete_interrupt(plic_instance_t * this_plic,
plic_source source);
__END_DECLS
#endif

66
fpga_spn/bsp/env/common.mk vendored Normal file
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# See LICENSE for license details.
ifndef _SIFIVE_MK_COMMON
_SIFIVE_MK_COMMON := # defined
.PHONY: all
all: $(TARGET)
include $(BSP_BASE)/libwrap/libwrap.mk
ENV_DIR = $(BSP_BASE)/env
PLATFORM_DIR = $(ENV_DIR)/$(BOARD)
ASM_SRCS += $(ENV_DIR)/start.S
ASM_SRCS += $(ENV_DIR)/entry.S
C_SRCS += $(PLATFORM_DIR)/init.c
LINKER_SCRIPT := $(PLATFORM_DIR)/$(LINK_TARGET).lds
INCLUDES += -I$(BSP_BASE)/include
INCLUDES += -I$(BSP_BASE)/drivers/
INCLUDES += -I$(ENV_DIR)
INCLUDES += -I$(PLATFORM_DIR)
TOOL_DIR ?= $(BSP_BASE)/../toolchain/bin
LDFLAGS += -T $(LINKER_SCRIPT) -nostartfiles
LDFLAGS += -L$(ENV_DIR) --specs=nano.specs
ASM_OBJS := $(ASM_SRCS:.S=.o)
C_OBJS := $(C_SRCS:.c=.o)
CXX_OBJS := $(CXX_SRCS:.cpp=.o)
LINK_OBJS += $(ASM_OBJS) $(C_OBJS) $(CXX_OBJS)
LINK_DEPS += $(LINKER_SCRIPT)
CLEAN_OBJS += $(TARGET) $(LINK_OBJS)
CFLAGS += -march=$(RISCV_ARCH)
CFLAGS += -mabi=$(RISCV_ABI)
CFLAGS += -mcmodel=medany
TRIPLET?=riscv64-unknown-elf
CXX=$(TOOL_DIR)/$(TRIPLET)-c++
CC=$(TOOL_DIR)/$(TRIPLET)-gcc
LD=$(TOOL_DIR)/$(TRIPLET)-gcc
AR=$(TOOL_DIR)/$(TRIPLET)-ar
$(TARGET): $(LINK_OBJS) $(LINK_DEPS)
$(LD) $(LINK_OBJS) $(LDFLAGS) $(LIBWRAP) -o $@
$(ASM_OBJS): %.o: %.S $(HEADERS)
$(CC) $(CFLAGS) $(INCLUDES) -c -o $@ $<
$(C_OBJS): %.o: %.c $(HEADERS)
$(CC) $(CFLAGS) $(INCLUDES) -include sys/cdefs.h -c -o $@ $<
$(CXX_OBJS): %.o: %.cpp $(HEADERS)
$(CXX) $(CFLAGS) $(CXXFLAGS) $(INCLUDES) -include sys/cdefs.h -c -o $@ $<
.PHONY: clean
clean:
rm -f $(CLEAN_OBJS) $(LIBWRAP)
endif # _SIFIVE_MK_COMMON

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OUTPUT_ARCH( "riscv" )
ENTRY( _start )
MEMORY
{
flash (rxai!w) : ORIGIN = 0x40400000, LENGTH = 512M
ram (wxa!ri) : ORIGIN = 0x80000000, LENGTH = 64K
}
PHDRS
{
flash PT_LOAD;
ram_init PT_LOAD;
ram PT_NULL;
}
SECTIONS
{
__stack_size = DEFINED(__stack_size) ? __stack_size : 2K;
.init :
{
KEEP (*(SORT_NONE(.init)))
} >flash AT>flash :flash
.text :
{
*(.text.unlikely .text.unlikely.*)
*(.text.startup .text.startup.*)
*(.text .text.*)
*(.gnu.linkonce.t.*)
} >flash AT>flash :flash
.fini :
{
KEEP (*(SORT_NONE(.fini)))
} >flash AT>flash :flash
PROVIDE (__etext = .);
PROVIDE (_etext = .);
PROVIDE (etext = .);
.rodata :
{
*(.rdata)
*(.rodata .rodata.*)
*(.gnu.linkonce.r.*)
} >flash AT>flash :flash
. = ALIGN(4);
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
} >flash AT>flash :flash
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.init_array.*) SORT_BY_INIT_PRIORITY(.ctors.*)))
KEEP (*(.init_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .ctors))
PROVIDE_HIDDEN (__init_array_end = .);
} >flash AT>flash :flash
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.fini_array.*) SORT_BY_INIT_PRIORITY(.dtors.*)))
KEEP (*(.fini_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
} >flash AT>flash :flash
.ctors :
{
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
} >flash AT>flash :flash
.dtors :
{
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
} >flash AT>flash :flash
.lalign :
{
. = ALIGN(4);
PROVIDE( _data_lma = . );
} >flash AT>flash :flash
.dalign :
{
. = ALIGN(4);
PROVIDE( _data = . );
} >ram AT>flash :ram_init
.data :
{
*(.data .data.*)
*(.gnu.linkonce.d.*)
. = ALIGN(8);
PROVIDE( __global_pointer$ = . + 0x800 );
*(.sdata .sdata.*)
*(.gnu.linkonce.s.*)
. = ALIGN(8);
*(.srodata.cst16)
*(.srodata.cst8)
*(.srodata.cst4)
*(.srodata.cst2)
*(.srodata .srodata.*)
} >ram AT>flash :ram_init
. = ALIGN(4);
PROVIDE( _edata = . );
PROVIDE( edata = . );
PROVIDE( _fbss = . );
PROVIDE( __bss_start = . );
.bss :
{
*(.sbss*)
*(.gnu.linkonce.sb.*)
*(.bss .bss.*)
*(.gnu.linkonce.b.*)
*(COMMON)
. = ALIGN(4);
} >ram AT>ram :ram
. = ALIGN(8);
PROVIDE( _end = . );
PROVIDE( end = . );
.stack ORIGIN(ram) + LENGTH(ram) - __stack_size :
{
PROVIDE( _heap_end = . );
. = __stack_size;
PROVIDE( _sp = . );
} >ram AT>ram :ram
}

98
fpga_spn/bsp/env/coreip-e2-arty/init.c vendored Normal file
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@ -0,0 +1,98 @@
//See LICENSE for license details.
#include <stdint.h>
#include <stdio.h>
#include <unistd.h>
#include "platform.h"
#include "encoding.h"
#define CPU_FREQ 32000000
#define XSTR(x) #x
#define STR(x) XSTR(x)
extern int main(int argc, char** argv);
unsigned long get_cpu_freq()
{
return CPU_FREQ;
}
unsigned long get_timer_freq()
{
return get_cpu_freq();
}
uint64_t get_timer_value()
{
#if __riscv_xlen == 32
while (1) {
uint32_t hi = read_csr(mcycleh);
uint32_t lo = read_csr(mcycle);
if (hi == read_csr(mcycleh))
return ((uint64_t)hi << 32) | lo;
}
#else
return read_csr(mcycle);
#endif
}
static void uart_init(size_t baud_rate)
{
UART0_REG(UART_REG_DIV) = (get_cpu_freq() ) / baud_rate - 1;
UART0_REG(UART_REG_TXCTRL) |= UART_TXEN;
}
typedef void (*interrupt_function_ptr_t) (void);
interrupt_function_ptr_t localISR[CLIC_NUM_INTERRUPTS] __attribute__((aligned(64)));
void trap_entry(void) __attribute__((interrupt, aligned(64)));
void trap_entry(void)
{
unsigned long mcause = read_csr(mcause);
unsigned long mepc = read_csr(mepc);
if (mcause & MCAUSE_INT) {
localISR[mcause & MCAUSE_CAUSE] ();
} else {
while(1);
}
}
#ifdef CLIC_DIRECT
#else
void default_handler(void)__attribute__((interrupt));;
#endif
void default_handler(void)
{
puts("default handler\n");
while(1);
}
void _init()
{
#ifndef NO_INIT
uart_init(115200);
puts("core freq at " STR(CPU_FREQ) " Hz\n");
//initialize vector table
int i=0;
while(i<CLIC_NUM_INTERRUPTS) {
localISR[i++] = default_handler;
}
write_csr(mtvt, localISR);
#ifdef CLIC_DIRECT
write_csr(mtvec, ((unsigned long)&trap_entry | MTVEC_CLIC));
#else
write_csr(mtvec, ((unsigned long)&trap_entry | MTVEC_CLIC_VECT));
#endif
#endif
}
void _fini()
{
}

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@ -0,0 +1,31 @@
# JTAG adapter setup
adapter_khz 10000
interface ftdi
ftdi_device_desc "Olimex OpenOCD JTAG ARM-USB-TINY-H"
ftdi_vid_pid 0x15ba 0x002a
ftdi_layout_init 0x0808 0x0a1b
ftdi_layout_signal nSRST -oe 0x0200
#ftdi_layout_signal nTRST -data 0x0100 -oe 0x0100
ftdi_layout_signal LED -data 0x0800
set _CHIPNAME riscv
jtag newtap $_CHIPNAME cpu -irlen 5 -expected-id 0x20000001
set _TARGETNAME $_CHIPNAME.cpu
target create $_TARGETNAME.0 riscv -chain-position $_TARGETNAME
$_TARGETNAME.0 configure -work-area-phys 0x80000000 -work-area-size 10000 -work-area-backup 1
# Un-comment these two flash lines if you have a SPI flash and want to write
# it.
flash bank spi0 fespi 0x40000000 0 0 0 $_TARGETNAME.0 0x20004000
init
if {[ info exists pulse_srst]} {
ftdi_set_signal nSRST 0
ftdi_set_signal nSRST z
}
halt
#flash protect 0 64 last off
echo "Ready for Remote Connections"

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@ -0,0 +1,98 @@
// See LICENSE for license details.
#ifndef _SIFIVE_PLATFORM_H
#define _SIFIVE_PLATFORM_H
// Some things missing from the official encoding.h
#if __riscv_xlen == 32
#define MCAUSE_INT 0x80000000UL
#define MCAUSE_CAUSE 0x000003FFUL
#else
#define MCAUSE_INT 0x8000000000000000UL
#define MCAUSE_CAUSE 0x00000000000003FFUL
#endif
#define MTVEC_DIRECT 0X00
#define MTVEC_VECTORED 0x01
#define MTVEC_CLIC 0x02
#define MTVEC_CLIC_VECT 0X03
#include "sifive/const.h"
#include "sifive/devices/gpio.h"
#include "sifive/devices/clint.h"
#include "sifive/devices/clic.h"
#include "sifive/devices/pwm.h"
#include "sifive/devices/spi.h"
#include "sifive/devices/uart.h"
/****************************************************************************
* Platform definitions
*****************************************************************************/
// Memory map
#define CLINT_CTRL_ADDR _AC(0x02000000,UL)
#define CLIC_HART0_ADDR _AC(0x02800000,UL)
#define GPIO_CTRL_ADDR _AC(0x20002000,UL)
#define PWM0_CTRL_ADDR _AC(0x20005000,UL)
#define RAM_MEM_ADDR _AC(0x80000000,UL)
#define RAM_MEM_SIZE _AC(0x10000,UL)
#define SPI0_CTRL_ADDR _AC(0x20004000,UL)
#define SPI0_MEM_ADDR _AC(0x40000000,UL)
#define SPI0_MEM_SIZE _AC(0x20000000,UL)
#define TESTBENCH_MEM_ADDR _AC(0x20000000,UL)
#define TESTBENCH_MEM_SIZE _AC(0x10000000,UL)
//#define TRAPVEC_TABLE_CTRL_ADDR _AC(0x00001010,UL)
#define UART0_CTRL_ADDR _AC(0x20000000,UL)
// IOF masks
// Interrupt numbers
#define RESERVED_INT_BASE 0
#define UART0_INT_BASE 1
#define EXTERNAL_INT_BASE 2
#define SPI0_INT_BASE 6
#define GPIO_INT_BASE 7
#define PWM0_INT_BASE 23
// Helper functions
#define _REG64(p, i) (*(volatile uint64_t *)((p) + (i)))
#define _REG32(p, i) (*(volatile uint32_t *)((p) + (i)))
#define _REG16(p, i) (*(volatile uint16_t *)((p) + (i)))
#define SET_BITS(reg, mask, value) if ((value) == 0) { (reg) &= ~(mask); } else { (reg) |= (mask); }
#define CLINT_REG(offset) _REG32(CLINT_CTRL_ADDR, offset)
#define CLIC0_REG(offset) _REG32(CLIC_HART0_ADDR, offset)
#define CLIC0_REG8(offset) (*(volatile uint8_t *)((CLIC_HART0_ADDR) + (offset)))
#define GPIO_REG(offset) _REG32(GPIO_CTRL_ADDR, offset)
#define PWM0_REG(offset) _REG32(PWM0_CTRL_ADDR, offset)
#define SPI0_REG(offset) _REG32(SPI0_CTRL_ADDR, offset)
#define UART0_REG(offset) _REG32(UART0_CTRL_ADDR, offset)
#define CLINT_REG(offset) _REG32(CLINT_CTRL_ADDR, offset)
#define CLIC0_REG64(offset) _REG64(CLIC_HART0_ADDR, offset)
#define GPIO_REG64(offset) _REG64(GPIO_CTRL_ADDR, offset)
#define PWM0_REG64(offset) _REG64(PWM0_CTRL_ADDR, offset)
#define SPI0_REG64(offset) _REG64(SPI0_CTRL_ADDR, offset)
#define UART0_REG64(offset) _REG64(UART0_CTRL_ADDR, offset)
// Misc
#define NUM_GPIO 16
#define CLIC_NUM_INTERRUPTS 28 + 16
#ifdef E20
#define CLIC_CONFIG_BITS 2
#else
#define CLIC_CONFIG_BITS 4
#endif
#define HAS_BOARD_BUTTONS
#include "coreplexip-arty.h"
unsigned long get_cpu_freq(void);
unsigned long get_timer_freq(void);
uint64_t get_timer_value(void);
#endif /* _SIFIVE_PLATFORM_H */

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@ -0,0 +1,3 @@
# Describes the CPU on this board to the rest of the SDK.
RISCV_ARCH := rv32imac
RISCV_ABI := ilp32

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@ -0,0 +1,157 @@
OUTPUT_ARCH( "riscv" )
ENTRY( _start )
MEMORY
{
flash (rxai!w) : ORIGIN = 0x80008000, LENGTH = 32K
ram (wxa!ri) : ORIGIN = 0x80000000, LENGTH = 32K
}
PHDRS
{
flash PT_LOAD;
ram_init PT_LOAD;
ram PT_NULL;
}
SECTIONS
{
__stack_size = DEFINED(__stack_size) ? __stack_size : 1K;
.init :
{
KEEP (*(SORT_NONE(.init)))
} >flash AT>flash :flash
.text :
{
*(.text.unlikely .text.unlikely.*)
*(.text.startup .text.startup.*)
*(.text .text.*)
*(.gnu.linkonce.t.*)
} >flash AT>flash :flash
.fini :
{
KEEP (*(SORT_NONE(.fini)))
} >flash AT>flash :flash
PROVIDE (__etext = .);
PROVIDE (_etext = .);
PROVIDE (etext = .);
. = ALIGN(4);
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
} >flash AT>flash :flash
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.init_array.*) SORT_BY_INIT_PRIORITY(.ctors.*)))
KEEP (*(.init_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .ctors))
PROVIDE_HIDDEN (__init_array_end = .);
} >flash AT>flash :flash
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.fini_array.*) SORT_BY_INIT_PRIORITY(.dtors.*)))
KEEP (*(.fini_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
} >flash AT>flash :flash
.ctors :
{
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
} >flash AT>flash :flash
.dtors :
{
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
} >flash AT>flash :flash
.lalign :
{
. = ALIGN(4);
PROVIDE( _data_lma = . );
} >flash AT>flash :flash
.dalign :
{
. = ALIGN(4);
PROVIDE( _data = . );
} >ram AT>flash :ram_init
.data :
{
*(.rdata)
*(.rodata .rodata.*)
*(.gnu.linkonce.r.*)
*(.data .data.*)
*(.gnu.linkonce.d.*)
. = ALIGN(8);
PROVIDE( __global_pointer$ = . + 0x800 );
*(.sdata .sdata.*)
*(.gnu.linkonce.s.*)
. = ALIGN(8);
*(.srodata.cst16)
*(.srodata.cst8)
*(.srodata.cst4)
*(.srodata.cst2)
*(.srodata .srodata.*)
} >ram AT>flash :ram_init
. = ALIGN(4);
PROVIDE( _edata = . );
PROVIDE( edata = . );
PROVIDE( _fbss = . );
PROVIDE( __bss_start = . );
.bss :
{
*(.sbss*)
*(.gnu.linkonce.sb.*)
*(.bss .bss.*)
*(.gnu.linkonce.b.*)
*(COMMON)
. = ALIGN(4);
} >ram AT>ram :ram
. = ALIGN(8);
PROVIDE( _end = . );
PROVIDE( end = . );
.stack ORIGIN(ram) + LENGTH(ram) - __stack_size :
{
PROVIDE( _heap_end = . );
. = __stack_size;
PROVIDE( _sp = . );
} >ram AT>ram :ram
}

161
fpga_spn/bsp/env/coreip-e2-arty/tim.lds vendored Normal file
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@ -0,0 +1,161 @@
OUTPUT_ARCH( "riscv" )
ENTRY( _start )
MEMORY
{
ram (wxa!ri) : ORIGIN = 0x80000000, LENGTH = 64K
}
PHDRS
{
ram PT_LOAD;
ram_init PT_LOAD;
ram PT_NULL;
}
SECTIONS
{
__stack_size = DEFINED(__stack_size) ? __stack_size : 1K;
.init :
{
KEEP (*(SORT_NONE(.init)))
} >ram AT>ram :ram
.text :
{
*(.text.unlikely .text.unlikely.*)
*(.text.startup .text.startup.*)
*(.text .text.*)
*(.gnu.linkonce.t.*)
} >ram AT>ram :ram
.fini :
{
KEEP (*(SORT_NONE(.fini)))
} >ram AT>ram :ram
PROVIDE (__etext = .);
PROVIDE (_etext = .);
PROVIDE (etext = .);
.rodata :
{
*(.rdata)
*(.rodata .rodata.*)
*(.gnu.linkonce.r.*)
} >ram AT>ram :ram
. = ALIGN(4);
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
} >ram AT>ram :ram
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.init_array.*) SORT_BY_INIT_PRIORITY(.ctors.*)))
KEEP (*(.init_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .ctors))
PROVIDE_HIDDEN (__init_array_end = .);
} >ram AT>ram :ram
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.fini_array.*) SORT_BY_INIT_PRIORITY(.dtors.*)))
KEEP (*(.fini_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
} >ram AT>ram :ram
.ctors :
{
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
} >ram AT>ram :ram
.dtors :
{
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
} >ram AT>ram :ram
.lalign :
{
. = ALIGN(4);
PROVIDE( _data_lma = . );
} >ram AT>ram :ram
.dalign :
{
. = ALIGN(4);
PROVIDE( _data = . );
} >ram AT>ram :ram_init
.data :
{
*(.data .data.*)
*(.gnu.linkonce.d.*)
. = ALIGN(8);
PROVIDE( __global_pointer$ = . + 0x800 );
*(.sdata .sdata.*)
*(.gnu.linkonce.s.*)
. = ALIGN(8);
*(.srodata.cst16)
*(.srodata.cst8)
*(.srodata.cst4)
*(.srodata.cst2)
*(.srodata .srodata.*)
} >ram AT>ram :ram_init
. = ALIGN(4);
PROVIDE( _edata = . );
PROVIDE( edata = . );
PROVIDE( _fbss = . );
PROVIDE( __bss_start = . );
.bss :
{
*(.sbss*)
*(.gnu.linkonce.sb.*)
*(.bss .bss.*)
*(.gnu.linkonce.b.*)
*(COMMON)
. = ALIGN(4);
} >ram AT>ram :ram
. = ALIGN(8);
PROVIDE( _end = . );
PROVIDE( end = . );
.stack :
{
. = ALIGN(8);
. += __stack_size;
PROVIDE( _sp = . );
PROVIDE( _heap_end = . );
} >ram AT>ram :ram
}

102
fpga_spn/bsp/env/coreplexip-arty.h vendored Normal file
View File

@ -0,0 +1,102 @@
// 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 */

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@ -0,0 +1,157 @@
OUTPUT_ARCH( "riscv" )
ENTRY( _start )
MEMORY
{
flash (rxai!w) : ORIGIN = 0x40400000, LENGTH = 512M
ram (wxa!ri) : ORIGIN = 0x80000000, LENGTH = 16K
}
PHDRS
{
flash PT_LOAD;
ram_init PT_LOAD;
ram PT_NULL;
}
SECTIONS
{
__stack_size = DEFINED(__stack_size) ? __stack_size : 1K;
.init :
{
KEEP (*(SORT_NONE(.init)))
} >flash AT>flash :flash
.text :
{
*(.text.unlikely .text.unlikely.*)
*(.text.startup .text.startup.*)
*(.text .text.*)
*(.gnu.linkonce.t.*)
} >flash AT>flash :flash
.fini :
{
KEEP (*(SORT_NONE(.fini)))
} >flash AT>flash :flash
PROVIDE (__etext = .);
PROVIDE (_etext = .);
PROVIDE (etext = .);
. = ALIGN(4);
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
} >flash AT>flash :flash
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.init_array.*) SORT_BY_INIT_PRIORITY(.ctors.*)))
KEEP (*(.init_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .ctors))
PROVIDE_HIDDEN (__init_array_end = .);
} >flash AT>flash :flash
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.fini_array.*) SORT_BY_INIT_PRIORITY(.dtors.*)))
KEEP (*(.fini_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
} >flash AT>flash :flash
.ctors :
{
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
} >flash AT>flash :flash
.dtors :
{
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
} >flash AT>flash :flash
.lalign :
{
. = ALIGN(4);
PROVIDE( _data_lma = . );
} >flash AT>flash :flash
.dalign :
{
. = ALIGN(4);
PROVIDE( _data = . );
} >ram AT>flash :ram_init
.data :
{
*(.rdata)
*(.rodata .rodata.*)
*(.gnu.linkonce.r.*)
*(.data .data.*)
*(.gnu.linkonce.d.*)
. = ALIGN(8);
PROVIDE( __global_pointer$ = . + 0x800 );
*(.sdata .sdata.*)
*(.gnu.linkonce.s.*)
. = ALIGN(8);
*(.srodata.cst16)
*(.srodata.cst8)
*(.srodata.cst4)
*(.srodata.cst2)
*(.srodata .srodata.*)
} >ram AT>flash :ram_init
. = ALIGN(4);
PROVIDE( _edata = . );
PROVIDE( edata = . );
PROVIDE( _fbss = . );
PROVIDE( __bss_start = . );
.bss :
{
*(.sbss*)
*(.gnu.linkonce.sb.*)
*(.bss .bss.*)
*(.gnu.linkonce.b.*)
*(COMMON)
. = ALIGN(4);
} >ram AT>ram :ram
. = ALIGN(8);
PROVIDE( _end = . );
PROVIDE( end = . );
.stack ORIGIN(ram) + LENGTH(ram) - __stack_size :
{
PROVIDE( _heap_end = . );
. = __stack_size;
PROVIDE( _sp = . );
} >ram AT>ram :ram
}

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@ -0,0 +1,161 @@
OUTPUT_ARCH( "riscv" )
ENTRY( _start )
MEMORY
{
flash (rxai!w) : ORIGIN = 0x40400000, LENGTH = 512M
ram (wxa!ri) : ORIGIN = 0x80000000, LENGTH = 16K
}
PHDRS
{
flash PT_LOAD;
ram_init PT_LOAD;
ram PT_NULL;
}
SECTIONS
{
__stack_size = DEFINED(__stack_size) ? __stack_size : 2K;
.init :
{
KEEP (*(SORT_NONE(.init)))
} >flash AT>flash :flash
.text :
{
*(.text.unlikely .text.unlikely.*)
*(.text.startup .text.startup.*)
*(.text .text.*)
*(.gnu.linkonce.t.*)
} >flash AT>flash :flash
.fini :
{
KEEP (*(SORT_NONE(.fini)))
} >flash AT>flash :flash
PROVIDE (__etext = .);
PROVIDE (_etext = .);
PROVIDE (etext = .);
.rodata :
{
*(.rdata)
*(.rodata .rodata.*)
*(.gnu.linkonce.r.*)
} >flash AT>flash :flash
. = ALIGN(4);
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
} >flash AT>flash :flash
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.init_array.*) SORT_BY_INIT_PRIORITY(.ctors.*)))
KEEP (*(.init_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .ctors))
PROVIDE_HIDDEN (__init_array_end = .);
} >flash AT>flash :flash
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.fini_array.*) SORT_BY_INIT_PRIORITY(.dtors.*)))
KEEP (*(.fini_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
} >flash AT>flash :flash
.ctors :
{
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
} >flash AT>flash :flash
.dtors :
{
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
} >flash AT>flash :flash
.lalign :
{
. = ALIGN(4);
PROVIDE( _data_lma = . );
} >flash AT>flash :flash
.dalign :
{
. = ALIGN(4);
PROVIDE( _data = . );
} >ram AT>flash :ram_init
.data :
{
*(.data .data.*)
*(.gnu.linkonce.d.*)
. = ALIGN(8);
PROVIDE( __global_pointer$ = . + 0x800 );
*(.sdata .sdata.*)
*(.gnu.linkonce.s.*)
. = ALIGN(8);
*(.srodata.cst16)
*(.srodata.cst8)
*(.srodata.cst4)
*(.srodata.cst2)
*(.srodata .srodata.*)
} >ram AT>flash :ram_init
. = ALIGN(4);
PROVIDE( _edata = . );
PROVIDE( edata = . );
PROVIDE( _fbss = . );
PROVIDE( __bss_start = . );
.bss :
{
*(.sbss*)
*(.gnu.linkonce.sb.*)
*(.bss .bss.*)
*(.gnu.linkonce.b.*)
*(COMMON)
. = ALIGN(4);
} >ram AT>ram :ram
. = ALIGN(8);
PROVIDE( _end = . );
PROVIDE( end = . );
.stack ORIGIN(ram) + LENGTH(ram) - __stack_size :
{
PROVIDE( _heap_end = . );
. = __stack_size;
PROVIDE( _sp = . );
} >ram AT>ram :ram
}

View File

@ -0,0 +1,122 @@
//See LICENSE for license details.
#include <stdint.h>
#include <stdio.h>
#include <unistd.h>
#include "platform.h"
#include "encoding.h"
#define CPU_FREQ 65000000
#define XSTR(x) #x
#define STR(x) XSTR(x)
#ifndef VECT_IRQ
#define TRAP_ENTRY trap_entry
#else
#define TRAP_ENTRY vtrap_entry
#endif
extern int main(int argc, char** argv);
extern void TRAP_ENTRY();
unsigned long get_cpu_freq()
{
return CPU_FREQ;
}
unsigned long get_timer_freq()
{
return get_cpu_freq();
}
uint64_t get_timer_value()
{
#if __riscv_xlen == 32
while (1) {
uint32_t hi = read_csr(mcycleh);
uint32_t lo = read_csr(mcycle);
if (hi == read_csr(mcycleh))
return ((uint64_t)hi << 32) | lo;
}
#else
return read_csr(mcycle);
#endif
}
static void uart_init(size_t baud_rate)
{
UART0_REG(UART_REG_DIV) = (get_cpu_freq() / 2) / baud_rate - 1;
UART0_REG(UART_REG_TXCTRL) |= UART_TXEN;
}
#ifdef USE_PLIC
extern void handle_m_ext_interrupt();
#endif
#ifdef USE_M_TIME
extern void handle_m_time_interrupt();
#endif
#ifdef USE_LOCAL_ISR
typedef void (*my_interrupt_function_ptr_t) (void);
extern my_interrupt_function_ptr_t localISR[];
#endif
#ifndef VECT_IRQ
uintptr_t handle_trap(uintptr_t mcause, uintptr_t epc) __attribute__((noinline));
uintptr_t handle_trap(uintptr_t mcause, uintptr_t epc)
{
if (0){
#ifdef USE_PLIC
// External Machine-Level interrupt from PLIC
} else if ((mcause & MCAUSE_INT) && ((mcause & MCAUSE_CAUSE) == IRQ_M_EXT)) {
handle_m_ext_interrupt();
#endif
#ifdef USE_M_TIME
// External Machine-Level interrupt from PLIC
} else if ((mcause & MCAUSE_INT) && ((mcause & MCAUSE_CAUSE) == IRQ_M_TIMER)){
handle_m_time_interrupt();
#endif
#ifdef USE_LOCAL_ISR
} else if (mcause & MCAUSE_INT) {
localISR[mcause & MCAUSE_CAUSE] ();
#endif
}
else {
write(1, "Unhandled Trap:\n", 16);
_exit(1 + mcause);
}
return epc;
}
#endif
#ifdef USE_CLIC
void trap_entry(void) __attribute__((interrupt("SiFive-CLIC-preemptible"), aligned(64)));
void trap_entry(void)
{
unsigned long mcause = read_csr(mcause);
unsigned long mepc = read_csr(mepc);
handle_trap(mcause, mepc);
}
#endif
void _init()
{
#ifndef NO_INIT
uart_init(115200);
puts("core freq at " STR(CPU_FREQ) " Hz\n");
#ifdef USE_CLIC
write_csr(mtvec, ((unsigned long)&trap_entry | MTVEC_CLIC));
#else
write_csr(mtvec, ((unsigned long)&TRAP_ENTRY | MTVEC_VECTORED));
#endif
#endif
}
void _fini()
{
}

View File

@ -0,0 +1,31 @@
# JTAG adapter setup
adapter_khz 10000
interface ftdi
ftdi_device_desc "Olimex OpenOCD JTAG ARM-USB-TINY-H"
ftdi_vid_pid 0x15ba 0x002a
ftdi_layout_init 0x0808 0x0a1b
ftdi_layout_signal nSRST -oe 0x0200
#ftdi_layout_signal nTRST -data 0x0100 -oe 0x0100
ftdi_layout_signal LED -data 0x0800
set _CHIPNAME riscv
jtag newtap $_CHIPNAME cpu -irlen 5 -expected-id 0x20000001
set _TARGETNAME $_CHIPNAME.cpu
target create $_TARGETNAME.0 riscv -chain-position $_TARGETNAME
$_TARGETNAME.0 configure -work-area-phys 0x80000000 -work-area-size 10000 -work-area-backup 1
# Un-comment these two flash lines if you have a SPI flash and want to write
# it.
flash bank spi0 fespi 0x40000000 0 0 0 $_TARGETNAME.0 0x20004000
init
if {[ info exists pulse_srst]} {
ftdi_set_signal nSRST 0
ftdi_set_signal nSRST z
}
halt
#flash protect 0 64 last off
echo "Ready for Remote Connections"

View File

@ -0,0 +1,100 @@
// See LICENSE for license details.
#ifndef _SIFIVE_PLATFORM_H
#define _SIFIVE_PLATFORM_H
// Some things missing from the official encoding.h
#if __riscv_xlen == 32
#define MCAUSE_INT 0x80000000UL
#define MCAUSE_CAUSE 0x000003FFUL
#else
#define MCAUSE_INT 0x8000000000000000UL
#define MCAUSE_CAUSE 0x00000000000003FFUL
#endif
#ifdef VECT_IRQ
#define MTVEC_VECTORED 0x01
#else
#define MTVEC_VECTORED 0x00
#endif
#define MTVEC_CLIC 0x02
#define IRQ_M_LOCAL 16
#define MIP_MLIP(x) (1 << (IRQ_M_LOCAL + x))
#include "sifive/const.h"
#include "sifive/devices/clint.h"
#include "sifive/devices/gpio.h"
#include "sifive/devices/plic.h"
#include "sifive/devices/pwm.h"
#include "sifive/devices/spi.h"
#include "sifive/devices/uart.h"
/****************************************************************************
* Platform definitions
*****************************************************************************/
// Memory map
#define CLINT_CTRL_ADDR _AC(0x02000000,UL)
#define GPIO_CTRL_ADDR _AC(0x20002000,UL)
#define PLIC_CTRL_ADDR _AC(0x0C000000,UL)
#define PWM0_CTRL_ADDR _AC(0x20005000,UL)
#define RAM_MEM_ADDR _AC(0x80000000,UL)
#define RAM_MEM_SIZE _AC(0x10000,UL)
#define SPI0_CTRL_ADDR _AC(0x20004000,UL)
#define SPI0_MEM_ADDR _AC(0x40000000,UL)
#define SPI0_MEM_SIZE _AC(0x20000000,UL)
#define TESTBENCH_MEM_ADDR _AC(0x20000000,UL)
#define TESTBENCH_MEM_SIZE _AC(0x10000000,UL)
#define TRAPVEC_TABLE_CTRL_ADDR _AC(0x00001010,UL)
#define UART0_CTRL_ADDR _AC(0x20000000,UL)
// IOF masks
// Interrupt numbers
#define RESERVED_INT_BASE 0
#define UART0_INT_BASE 1
#define EXTERNAL_INT_BASE 2
#define SPI0_INT_BASE 6
#define GPIO_INT_BASE 7
#define PWM0_INT_BASE 23
// Helper functions
#define _REG64(p, i) (*(volatile uint64_t *)((p) + (i)))
#define _REG32(p, i) (*(volatile uint32_t *)((p) + (i)))
#define _REG16(p, i) (*(volatile uint16_t *)((p) + (i)))
// Bulk set bits in `reg` to either 0 or 1.
// E.g. SET_BITS(MY_REG, 0x00000007, 0) would generate MY_REG &= ~0x7
// E.g. SET_BITS(MY_REG, 0x00000007, 1) would generate MY_REG |= 0x7
#define SET_BITS(reg, mask, value) if ((value) == 0) { (reg) &= ~(mask); } else { (reg) |= (mask); }
#define CLINT_REG(offset) _REG32(CLINT_CTRL_ADDR, offset)
#define GPIO_REG(offset) _REG32(GPIO_CTRL_ADDR, offset)
#define PLIC_REG(offset) _REG32(PLIC_CTRL_ADDR, offset)
#define PWM0_REG(offset) _REG32(PWM0_CTRL_ADDR, offset)
#define SPI0_REG(offset) _REG32(SPI0_CTRL_ADDR, offset)
#define TRAPVEC_TABLE_REG(offset) _REG32(TRAPVEC_TABLE_CTRL_ADDR, offset)
#define UART0_REG(offset) _REG32(UART0_CTRL_ADDR, offset)
#define CLINT_REG64(offset) _REG64(CLINT_CTRL_ADDR, offset)
#define GPIO_REG64(offset) _REG64(GPIO_CTRL_ADDR, offset)
#define PLIC_REG64(offset) _REG64(PLIC_CTRL_ADDR, offset)
#define PWM0_REG64(offset) _REG64(PWM0_CTRL_ADDR, offset)
#define SPI0_REG64(offset) _REG64(SPI0_CTRL_ADDR, offset)
#define TRAPVEC_TABLE_REG64(offset) _REG64(TRAPVEC_TABLE_CTRL_ADDR, offset)
#define UART0_REG64(offset) _REG64(UART0_CTRL_ADDR, offset)
// Misc
#define NUM_GPIO 16
#define PLIC_NUM_INTERRUPTS 28
#define PLIC_NUM_PRIORITIES 7
#define HAS_BOARD_BUTTONS
#include "coreplexip-arty.h"
unsigned long get_cpu_freq(void);
unsigned long get_timer_freq(void);
uint64_t get_timer_value(void);
#endif /* _SIFIVE_PLATFORM_H */

View File

@ -0,0 +1,161 @@
OUTPUT_ARCH( "riscv" )
ENTRY( _start )
MEMORY
{
ram (wxa!ri) : ORIGIN = 0x80000000, LENGTH = 16K
}
PHDRS
{
ram PT_LOAD;
ram_init PT_LOAD;
ram PT_NULL;
}
SECTIONS
{
__stack_size = DEFINED(__stack_size) ? __stack_size : 1K;
.init :
{
KEEP (*(SORT_NONE(.init)))
} >ram AT>ram :ram
.text :
{
*(.text.unlikely .text.unlikely.*)
*(.text.startup .text.startup.*)
*(.text .text.*)
*(.gnu.linkonce.t.*)
} >ram AT>ram :ram
.fini :
{
KEEP (*(SORT_NONE(.fini)))
} >ram AT>ram :ram
PROVIDE (__etext = .);
PROVIDE (_etext = .);
PROVIDE (etext = .);
.rodata :
{
*(.rdata)
*(.rodata .rodata.*)
*(.gnu.linkonce.r.*)
} >ram AT>ram :ram
. = ALIGN(4);
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
} >ram AT>ram :ram
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.init_array.*) SORT_BY_INIT_PRIORITY(.ctors.*)))
KEEP (*(.init_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .ctors))
PROVIDE_HIDDEN (__init_array_end = .);
} >ram AT>ram :ram
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.fini_array.*) SORT_BY_INIT_PRIORITY(.dtors.*)))
KEEP (*(.fini_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
} >ram AT>ram :ram
.ctors :
{
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
} >ram AT>ram :ram
.dtors :
{
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
} >ram AT>ram :ram
.lalign :
{
. = ALIGN(4);
PROVIDE( _data_lma = . );
} >ram AT>ram :ram
.dalign :
{
. = ALIGN(4);
PROVIDE( _data = . );
} >ram AT>ram :ram_init
.data :
{
*(.data .data.*)
*(.gnu.linkonce.d.*)
. = ALIGN(8);
PROVIDE( __global_pointer$ = . + 0x800 );
*(.sdata .sdata.*)
*(.gnu.linkonce.s.*)
. = ALIGN(8);
*(.srodata.cst16)
*(.srodata.cst8)
*(.srodata.cst4)
*(.srodata.cst2)
*(.srodata .srodata.*)
} >ram AT>ram :ram_init
. = ALIGN(4);
PROVIDE( _edata = . );
PROVIDE( edata = . );
PROVIDE( _fbss = . );
PROVIDE( __bss_start = . );
.bss :
{
*(.sbss*)
*(.gnu.linkonce.sb.*)
*(.bss .bss.*)
*(.gnu.linkonce.b.*)
*(COMMON)
. = ALIGN(4);
} >ram AT>ram :ram
. = ALIGN(8);
PROVIDE( _end = . );
PROVIDE( end = . );
.stack :
{
. = ALIGN(8);
. += __stack_size;
PROVIDE( _sp = . );
PROVIDE( _heap_end = . );
} >ram AT>ram :ram
}

View File

@ -0,0 +1,3 @@
# Describes the CPU on this board to the rest of the SDK.
RISCV_ARCH := rv32imac
RISCV_ABI := ilp32

View File

@ -0,0 +1,157 @@
OUTPUT_ARCH( "riscv" )
ENTRY( _start )
MEMORY
{
flash (rxai!w) : ORIGIN = 0x40400000, LENGTH = 512M
ram (wxa!ri) : ORIGIN = 0x80000000, LENGTH = 16K
}
PHDRS
{
flash PT_LOAD;
ram_init PT_LOAD;
ram PT_NULL;
}
SECTIONS
{
__stack_size = DEFINED(__stack_size) ? __stack_size : 1K;
.init :
{
KEEP (*(SORT_NONE(.init)))
} >flash AT>flash :flash
.text :
{
*(.text.unlikely .text.unlikely.*)
*(.text.startup .text.startup.*)
*(.text .text.*)
*(.gnu.linkonce.t.*)
} >flash AT>flash :flash
.fini :
{
KEEP (*(SORT_NONE(.fini)))
} >flash AT>flash :flash
PROVIDE (__etext = .);
PROVIDE (_etext = .);
PROVIDE (etext = .);
. = ALIGN(4);
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
} >flash AT>flash :flash
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.init_array.*) SORT_BY_INIT_PRIORITY(.ctors.*)))
KEEP (*(.init_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .ctors))
PROVIDE_HIDDEN (__init_array_end = .);
} >flash AT>flash :flash
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.fini_array.*) SORT_BY_INIT_PRIORITY(.dtors.*)))
KEEP (*(.fini_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
} >flash AT>flash :flash
.ctors :
{
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
} >flash AT>flash :flash
.dtors :
{
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
} >flash AT>flash :flash
.lalign :
{
. = ALIGN(4);
PROVIDE( _data_lma = . );
} >flash AT>flash :flash
.dalign :
{
. = ALIGN(4);
PROVIDE( _data = . );
} >ram AT>flash :ram_init
.data :
{
*(.rdata)
*(.rodata .rodata.*)
*(.gnu.linkonce.r.*)
*(.data .data.*)
*(.gnu.linkonce.d.*)
. = ALIGN(8);
PROVIDE( __global_pointer$ = . + 0x800 );
*(.sdata .sdata.*)
*(.gnu.linkonce.s.*)
. = ALIGN(8);
*(.srodata.cst16)
*(.srodata.cst8)
*(.srodata.cst4)
*(.srodata.cst2)
*(.srodata .srodata.*)
} >ram AT>flash :ram_init
. = ALIGN(4);
PROVIDE( _edata = . );
PROVIDE( edata = . );
PROVIDE( _fbss = . );
PROVIDE( __bss_start = . );
.bss :
{
*(.sbss*)
*(.gnu.linkonce.sb.*)
*(.bss .bss.*)
*(.gnu.linkonce.b.*)
*(COMMON)
. = ALIGN(4);
} >ram AT>ram :ram
. = ALIGN(8);
PROVIDE( _end = . );
PROVIDE( end = . );
.stack ORIGIN(ram) + LENGTH(ram) - __stack_size :
{
PROVIDE( _heap_end = . );
. = __stack_size;
PROVIDE( _sp = . );
} >ram AT>ram :ram
}

View File

@ -0,0 +1,161 @@
OUTPUT_ARCH( "riscv" )
ENTRY( _start )
MEMORY
{
flash (rxai!w) : ORIGIN = 0x40400000, LENGTH = 512M
ram (wxa!ri) : ORIGIN = 0x80000000, LENGTH = 16K
}
PHDRS
{
flash PT_LOAD;
ram_init PT_LOAD;
ram PT_NULL;
}
SECTIONS
{
__stack_size = DEFINED(__stack_size) ? __stack_size : 2K;
.init :
{
KEEP (*(SORT_NONE(.init)))
} >flash AT>flash :flash
.text :
{
*(.text.unlikely .text.unlikely.*)
*(.text.startup .text.startup.*)
*(.text .text.*)
*(.gnu.linkonce.t.*)
} >flash AT>flash :flash
.fini :
{
KEEP (*(SORT_NONE(.fini)))
} >flash AT>flash :flash
PROVIDE (__etext = .);
PROVIDE (_etext = .);
PROVIDE (etext = .);
.rodata :
{
*(.rdata)
*(.rodata .rodata.*)
*(.gnu.linkonce.r.*)
} >flash AT>flash :flash
. = ALIGN(4);
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
} >flash AT>flash :flash
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.init_array.*) SORT_BY_INIT_PRIORITY(.ctors.*)))
KEEP (*(.init_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .ctors))
PROVIDE_HIDDEN (__init_array_end = .);
} >flash AT>flash :flash
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.fini_array.*) SORT_BY_INIT_PRIORITY(.dtors.*)))
KEEP (*(.fini_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
} >flash AT>flash :flash
.ctors :
{
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
} >flash AT>flash :flash
.dtors :
{
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
} >flash AT>flash :flash
.lalign :
{
. = ALIGN(4);
PROVIDE( _data_lma = . );
} >flash AT>flash :flash
.dalign :
{
. = ALIGN(4);
PROVIDE( _data = . );
} >ram AT>flash :ram_init
.data :
{
*(.data .data.*)
*(.gnu.linkonce.d.*)
. = ALIGN(8);
PROVIDE( __global_pointer$ = . + 0x800 );
*(.sdata .sdata.*)
*(.gnu.linkonce.s.*)
. = ALIGN(8);
*(.srodata.cst16)
*(.srodata.cst8)
*(.srodata.cst4)
*(.srodata.cst2)
*(.srodata .srodata.*)
} >ram AT>flash :ram_init
. = ALIGN(4);
PROVIDE( _edata = . );
PROVIDE( edata = . );
PROVIDE( _fbss = . );
PROVIDE( __bss_start = . );
.bss :
{
*(.sbss*)
*(.gnu.linkonce.sb.*)
*(.bss .bss.*)
*(.gnu.linkonce.b.*)
*(COMMON)
. = ALIGN(4);
} >ram AT>ram :ram
. = ALIGN(8);
PROVIDE( _end = . );
PROVIDE( end = . );
.stack ORIGIN(ram) + LENGTH(ram) - __stack_size :
{
PROVIDE( _heap_end = . );
. = __stack_size;
PROVIDE( _sp = . );
} >ram AT>ram :ram
}

View File

@ -0,0 +1,122 @@
//See LICENSE for license details.
#include <stdint.h>
#include <stdio.h>
#include <unistd.h>
#include "platform.h"
#include "encoding.h"
#define CPU_FREQ 65000000
#define XSTR(x) #x
#define STR(x) XSTR(x)
#ifndef VECT_IRQ
#define TRAP_ENTRY trap_entry
#else
#define TRAP_ENTRY vtrap_entry
#endif
extern int main(int argc, char** argv);
extern void TRAP_ENTRY();
unsigned long get_cpu_freq()
{
return CPU_FREQ;
}
unsigned long get_timer_freq()
{
return get_cpu_freq();
}
uint64_t get_timer_value()
{
#if __riscv_xlen == 32
while (1) {
uint32_t hi = read_csr(mcycleh);
uint32_t lo = read_csr(mcycle);
if (hi == read_csr(mcycleh))
return ((uint64_t)hi << 32) | lo;
}
#else
return read_csr(mcycle);
#endif
}
static void uart_init(size_t baud_rate)
{
UART0_REG(UART_REG_DIV) = (get_cpu_freq() / 2) / baud_rate - 1;
UART0_REG(UART_REG_TXCTRL) |= UART_TXEN;
}
#ifdef USE_PLIC
extern void handle_m_ext_interrupt();
#endif
#ifdef USE_M_TIME
extern void handle_m_time_interrupt();
#endif
#ifdef USE_LOCAL_ISR
typedef void (*my_interrupt_function_ptr_t) (void);
extern my_interrupt_function_ptr_t localISR[];
#endif
#ifndef VECT_IRQ
uintptr_t handle_trap(uintptr_t mcause, uintptr_t epc) __attribute__((noinline));
uintptr_t handle_trap(uintptr_t mcause, uintptr_t epc)
{
if (0){
#ifdef USE_PLIC
// External Machine-Level interrupt from PLIC
} else if ((mcause & MCAUSE_INT) && ((mcause & MCAUSE_CAUSE) == IRQ_M_EXT)) {
handle_m_ext_interrupt();
#endif
#ifdef USE_M_TIME
// External Machine-Level interrupt from PLIC
} else if ((mcause & MCAUSE_INT) && ((mcause & MCAUSE_CAUSE) == IRQ_M_TIMER)){
handle_m_time_interrupt();
#endif
#ifdef USE_LOCAL_ISR
} else if (mcause & MCAUSE_INT) {
localISR[mcause & MCAUSE_CAUSE] ();
#endif
}
else {
write(1, "Unhandled Trap:\n", 16);
_exit(1 + mcause);
}
return epc;
}
#endif
#ifdef USE_CLIC
void trap_entry(void) __attribute__((interrupt("SiFive-CLIC-preemptible"), aligned(64)));
void trap_entry(void)
{
unsigned long mcause = read_csr(mcause);
unsigned long mepc = read_csr(mepc);
handle_trap(mcause, mepc);
}
#endif
void _init()
{
#ifndef NO_INIT
uart_init(115200);
puts("core freq at " STR(CPU_FREQ) " Hz\n");
#ifdef USE_CLIC
write_csr(mtvec, ((unsigned long)&trap_entry | MTVEC_CLIC));
#else
write_csr(mtvec, ((unsigned long)&TRAP_ENTRY | MTVEC_VECTORED));
#endif
#endif
}
void _fini()
{
}

View File

@ -0,0 +1,31 @@
# JTAG adapter setup
adapter_khz 10000
interface ftdi
ftdi_device_desc "Olimex OpenOCD JTAG ARM-USB-TINY-H"
ftdi_vid_pid 0x15ba 0x002a
ftdi_layout_init 0x0808 0x0a1b
ftdi_layout_signal nSRST -oe 0x0200
#ftdi_layout_signal nTRST -data 0x0100 -oe 0x0100
ftdi_layout_signal LED -data 0x0800
set _CHIPNAME riscv
jtag newtap $_CHIPNAME cpu -irlen 5 -expected-id 0x20000001
set _TARGETNAME $_CHIPNAME.cpu
target create $_TARGETNAME.0 riscv -chain-position $_TARGETNAME
$_TARGETNAME.0 configure -work-area-phys 0x80000000 -work-area-size 10000 -work-area-backup 1
# Un-comment these two flash lines if you have a SPI flash and want to write
# it.
flash bank spi0 fespi 0x40000000 0 0 0 $_TARGETNAME.0 0x20004000
init
if {[ info exists pulse_srst]} {
ftdi_set_signal nSRST 0
ftdi_set_signal nSRST z
}
halt
#flash protect 0 64 last off
echo "Ready for Remote Connections"

View File

@ -0,0 +1,100 @@
// See LICENSE for license details.
#ifndef _SIFIVE_PLATFORM_H
#define _SIFIVE_PLATFORM_H
// Some things missing from the official encoding.h
#if __riscv_xlen == 32
#define MCAUSE_INT 0x80000000UL
#define MCAUSE_CAUSE 0x000003FFUL
#else
#define MCAUSE_INT 0x8000000000000000UL
#define MCAUSE_CAUSE 0x00000000000003FFUL
#endif
#ifdef VECT_IRQ
#define MTVEC_VECTORED 0x01
#else
#define MTVEC_VECTORED 0x00
#endif
#define MTVEC_CLIC 0x02
#define IRQ_M_LOCAL 16
#define MIP_MLIP(x) (1 << (IRQ_M_LOCAL + x))
#include "sifive/const.h"
#include "sifive/devices/clint.h"
#include "sifive/devices/gpio.h"
#include "sifive/devices/plic.h"
#include "sifive/devices/pwm.h"
#include "sifive/devices/spi.h"
#include "sifive/devices/uart.h"
/****************************************************************************
* Platform definitions
*****************************************************************************/
// Memory map
#define CLINT_CTRL_ADDR _AC(0x02000000,UL)
#define GPIO_CTRL_ADDR _AC(0x20002000,UL)
#define PLIC_CTRL_ADDR _AC(0x0C000000,UL)
#define PWM0_CTRL_ADDR _AC(0x20005000,UL)
#define RAM_MEM_ADDR _AC(0x80000000,UL)
#define RAM_MEM_SIZE _AC(0x10000,UL)
#define SPI0_CTRL_ADDR _AC(0x20004000,UL)
#define SPI0_MEM_ADDR _AC(0x40000000,UL)
#define SPI0_MEM_SIZE _AC(0x20000000,UL)
#define TESTBENCH_MEM_ADDR _AC(0x20000000,UL)
#define TESTBENCH_MEM_SIZE _AC(0x10000000,UL)
#define TRAPVEC_TABLE_CTRL_ADDR _AC(0x00001010,UL)
#define UART0_CTRL_ADDR _AC(0x20000000,UL)
// IOF masks
// Interrupt numbers
#define RESERVED_INT_BASE 0
#define UART0_INT_BASE 1
#define EXTERNAL_INT_BASE 2
#define SPI0_INT_BASE 6
#define GPIO_INT_BASE 7
#define PWM0_INT_BASE 23
// Helper functions
#define _REG64(p, i) (*(volatile uint64_t *)((p) + (i)))
#define _REG32(p, i) (*(volatile uint32_t *)((p) + (i)))
#define _REG16(p, i) (*(volatile uint16_t *)((p) + (i)))
// Bulk set bits in `reg` to either 0 or 1.
// E.g. SET_BITS(MY_REG, 0x00000007, 0) would generate MY_REG &= ~0x7
// E.g. SET_BITS(MY_REG, 0x00000007, 1) would generate MY_REG |= 0x7
#define SET_BITS(reg, mask, value) if ((value) == 0) { (reg) &= ~(mask); } else { (reg) |= (mask); }
#define CLINT_REG(offset) _REG32(CLINT_CTRL_ADDR, offset)
#define GPIO_REG(offset) _REG32(GPIO_CTRL_ADDR, offset)
#define PLIC_REG(offset) _REG32(PLIC_CTRL_ADDR, offset)
#define PWM0_REG(offset) _REG32(PWM0_CTRL_ADDR, offset)
#define SPI0_REG(offset) _REG32(SPI0_CTRL_ADDR, offset)
#define TRAPVEC_TABLE_REG(offset) _REG32(TRAPVEC_TABLE_CTRL_ADDR, offset)
#define UART0_REG(offset) _REG32(UART0_CTRL_ADDR, offset)
#define CLINT_REG64(offset) _REG64(CLINT_CTRL_ADDR, offset)
#define GPIO_REG64(offset) _REG64(GPIO_CTRL_ADDR, offset)
#define PLIC_REG64(offset) _REG64(PLIC_CTRL_ADDR, offset)
#define PWM0_REG64(offset) _REG64(PWM0_CTRL_ADDR, offset)
#define SPI0_REG64(offset) _REG64(SPI0_CTRL_ADDR, offset)
#define TRAPVEC_TABLE_REG64(offset) _REG64(TRAPVEC_TABLE_CTRL_ADDR, offset)
#define UART0_REG64(offset) _REG64(UART0_CTRL_ADDR, offset)
// Misc
#define NUM_GPIO 16
#define PLIC_NUM_INTERRUPTS 28
#define PLIC_NUM_PRIORITIES 7
#define HAS_BOARD_BUTTONS
#include "coreplexip-arty.h"
unsigned long get_cpu_freq(void);
unsigned long get_timer_freq(void);
uint64_t get_timer_value(void);
#endif /* _SIFIVE_PLATFORM_H */

View File

@ -0,0 +1,161 @@
OUTPUT_ARCH( "riscv" )
ENTRY( _start )
MEMORY
{
ram (wxa!ri) : ORIGIN = 0x80000000, LENGTH = 16K
}
PHDRS
{
ram PT_LOAD;
ram_init PT_LOAD;
ram PT_NULL;
}
SECTIONS
{
__stack_size = DEFINED(__stack_size) ? __stack_size : 1K;
.init :
{
KEEP (*(SORT_NONE(.init)))
} >ram AT>ram :ram
.text :
{
*(.text.unlikely .text.unlikely.*)
*(.text.startup .text.startup.*)
*(.text .text.*)
*(.gnu.linkonce.t.*)
} >ram AT>ram :ram
.fini :
{
KEEP (*(SORT_NONE(.fini)))
} >ram AT>ram :ram
PROVIDE (__etext = .);
PROVIDE (_etext = .);
PROVIDE (etext = .);
.rodata :
{
*(.rdata)
*(.rodata .rodata.*)
*(.gnu.linkonce.r.*)
} >ram AT>ram :ram
. = ALIGN(4);
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
} >ram AT>ram :ram
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.init_array.*) SORT_BY_INIT_PRIORITY(.ctors.*)))
KEEP (*(.init_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .ctors))
PROVIDE_HIDDEN (__init_array_end = .);
} >ram AT>ram :ram
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.fini_array.*) SORT_BY_INIT_PRIORITY(.dtors.*)))
KEEP (*(.fini_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
} >ram AT>ram :ram
.ctors :
{
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
} >ram AT>ram :ram
.dtors :
{
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
} >ram AT>ram :ram
.lalign :
{
. = ALIGN(4);
PROVIDE( _data_lma = . );
} >ram AT>ram :ram
.dalign :
{
. = ALIGN(4);
PROVIDE( _data = . );
} >ram AT>ram :ram_init
.data :
{
*(.data .data.*)
*(.gnu.linkonce.d.*)
. = ALIGN(8);
PROVIDE( __global_pointer$ = . + 0x800 );
*(.sdata .sdata.*)
*(.gnu.linkonce.s.*)
. = ALIGN(8);
*(.srodata.cst16)
*(.srodata.cst8)
*(.srodata.cst4)
*(.srodata.cst2)
*(.srodata .srodata.*)
} >ram AT>ram :ram_init
. = ALIGN(4);
PROVIDE( _edata = . );
PROVIDE( edata = . );
PROVIDE( _fbss = . );
PROVIDE( __bss_start = . );
.bss :
{
*(.sbss*)
*(.gnu.linkonce.sb.*)
*(.bss .bss.*)
*(.gnu.linkonce.b.*)
*(COMMON)
. = ALIGN(4);
} >ram AT>ram :ram
. = ALIGN(8);
PROVIDE( _end = . );
PROVIDE( end = . );
.stack :
{
. = ALIGN(8);
. += __stack_size;
PROVIDE( _sp = . );
PROVIDE( _heap_end = . );
} >ram AT>ram :ram
}

View File

@ -0,0 +1,3 @@
# Describes the CPU on this board to the rest of the SDK.
RISCV_ARCH := rv64imac
RISCV_ABI := lp64

1313
fpga_spn/bsp/env/encoding.h vendored Normal file

File diff suppressed because it is too large Load Diff

98
fpga_spn/bsp/env/entry.S vendored Normal file
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// See LICENSE for license details
#ifndef ENTRY_S
#define ENTRY_S
#include "encoding.h"
#include "sifive/bits.h"
.section .text.entry
.align 2
.weak trap_entry
.global trap_entry
trap_entry:
addi sp, sp, -32*REGBYTES
STORE x1, 1*REGBYTES(sp)
STORE x2, 2*REGBYTES(sp)
STORE x3, 3*REGBYTES(sp)
STORE x4, 4*REGBYTES(sp)
STORE x5, 5*REGBYTES(sp)
STORE x6, 6*REGBYTES(sp)
STORE x7, 7*REGBYTES(sp)
STORE x8, 8*REGBYTES(sp)
STORE x9, 9*REGBYTES(sp)
STORE x10, 10*REGBYTES(sp)
STORE x11, 11*REGBYTES(sp)
STORE x12, 12*REGBYTES(sp)
STORE x13, 13*REGBYTES(sp)
STORE x14, 14*REGBYTES(sp)
STORE x15, 15*REGBYTES(sp)
STORE x16, 16*REGBYTES(sp)
STORE x17, 17*REGBYTES(sp)
STORE x18, 18*REGBYTES(sp)
STORE x19, 19*REGBYTES(sp)
STORE x20, 20*REGBYTES(sp)
STORE x21, 21*REGBYTES(sp)
STORE x22, 22*REGBYTES(sp)
STORE x23, 23*REGBYTES(sp)
STORE x24, 24*REGBYTES(sp)
STORE x25, 25*REGBYTES(sp)
STORE x26, 26*REGBYTES(sp)
STORE x27, 27*REGBYTES(sp)
STORE x28, 28*REGBYTES(sp)
STORE x29, 29*REGBYTES(sp)
STORE x30, 30*REGBYTES(sp)
STORE x31, 31*REGBYTES(sp)
csrr a0, mcause
csrr a1, mepc
mv a2, sp
call handle_trap
csrw mepc, a0
# Remain in M-mode after mret
li t0, MSTATUS_MPP
csrs mstatus, t0
LOAD x1, 1*REGBYTES(sp)
LOAD x2, 2*REGBYTES(sp)
LOAD x3, 3*REGBYTES(sp)
LOAD x4, 4*REGBYTES(sp)
LOAD x5, 5*REGBYTES(sp)
LOAD x6, 6*REGBYTES(sp)
LOAD x7, 7*REGBYTES(sp)
LOAD x8, 8*REGBYTES(sp)
LOAD x9, 9*REGBYTES(sp)
LOAD x10, 10*REGBYTES(sp)
LOAD x11, 11*REGBYTES(sp)
LOAD x12, 12*REGBYTES(sp)
LOAD x13, 13*REGBYTES(sp)
LOAD x14, 14*REGBYTES(sp)
LOAD x15, 15*REGBYTES(sp)
LOAD x16, 16*REGBYTES(sp)
LOAD x17, 17*REGBYTES(sp)
LOAD x18, 18*REGBYTES(sp)
LOAD x19, 19*REGBYTES(sp)
LOAD x20, 20*REGBYTES(sp)
LOAD x21, 21*REGBYTES(sp)
LOAD x22, 22*REGBYTES(sp)
LOAD x23, 23*REGBYTES(sp)
LOAD x24, 24*REGBYTES(sp)
LOAD x25, 25*REGBYTES(sp)
LOAD x26, 26*REGBYTES(sp)
LOAD x27, 27*REGBYTES(sp)
LOAD x28, 28*REGBYTES(sp)
LOAD x29, 29*REGBYTES(sp)
LOAD x30, 30*REGBYTES(sp)
LOAD x31, 31*REGBYTES(sp)
addi sp, sp, 32*REGBYTES
mret
.weak handle_trap
handle_trap:
1:
j 1b
#endif

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OUTPUT_ARCH( "riscv" )
ENTRY( _start )
MEMORY
{
flash (rxai!w) : ORIGIN = 0x20400000, LENGTH = 512M
ram (wxa!ri) : ORIGIN = 0x80000000, LENGTH = 16K
}
PHDRS
{
flash PT_LOAD;
ram_init PT_LOAD;
ram PT_NULL;
}
SECTIONS
{
__stack_size = DEFINED(__stack_size) ? __stack_size : 2K;
.init :
{
KEEP (*(SORT_NONE(.init)))
} >flash AT>flash :flash
.text :
{
*(.text.unlikely .text.unlikely.*)
*(.text.startup .text.startup.*)
*(.text .text.*)
*(.gnu.linkonce.t.*)
} >flash AT>flash :flash
.fini :
{
KEEP (*(SORT_NONE(.fini)))
} >flash AT>flash :flash
PROVIDE (__etext = .);
PROVIDE (_etext = .);
PROVIDE (etext = .);
.rodata :
{
*(.rdata)
*(.rodata .rodata.*)
*(.gnu.linkonce.r.*)
} >flash AT>flash :flash
. = ALIGN(4);
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
} >flash AT>flash :flash
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.init_array.*) SORT_BY_INIT_PRIORITY(.ctors.*)))
KEEP (*(.init_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .ctors))
PROVIDE_HIDDEN (__init_array_end = .);
} >flash AT>flash :flash
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.fini_array.*) SORT_BY_INIT_PRIORITY(.dtors.*)))
KEEP (*(.fini_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
} >flash AT>flash :flash
.ctors :
{
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
} >flash AT>flash :flash
.dtors :
{
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
} >flash AT>flash :flash
.lalign :
{
. = ALIGN(4);
PROVIDE( _data_lma = . );
} >flash AT>flash :flash
.dalign :
{
. = ALIGN(4);
PROVIDE( _data = . );
} >ram AT>flash :ram_init
.data :
{
*(.data .data.*)
*(.gnu.linkonce.d.*)
. = ALIGN(8);
PROVIDE( __global_pointer$ = . + 0x800 );
*(.sdata .sdata.*)
*(.gnu.linkonce.s.*)
. = ALIGN(8);
*(.srodata.cst16)
*(.srodata.cst8)
*(.srodata.cst4)
*(.srodata.cst2)
*(.srodata .srodata.*)
} >ram AT>flash :ram_init
. = ALIGN(4);
PROVIDE( _edata = . );
PROVIDE( edata = . );
PROVIDE( _fbss = . );
PROVIDE( __bss_start = . );
.bss :
{
*(.sbss*)
*(.gnu.linkonce.sb.*)
*(.bss .bss.*)
*(.gnu.linkonce.b.*)
*(COMMON)
. = ALIGN(4);
} >ram AT>ram :ram
. = ALIGN(8);
PROVIDE( _end = . );
PROVIDE( end = . );
.stack ORIGIN(ram) + LENGTH(ram) - __stack_size :
{
PROVIDE( _heap_end = . );
. = __stack_size;
PROVIDE( _sp = . );
} >ram AT>ram :ram
}

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//See LICENSE for license details.
#include <stdint.h>
#include <stdio.h>
#include <unistd.h>
#include "platform.h"
#include "encoding.h"
extern int main(int argc, char** argv);
extern void trap_entry();
static unsigned long get_cpu_freq()
{
return 65000000;
}
unsigned long get_timer_freq()
{
return get_cpu_freq();
}
uint64_t get_timer_value()
{
#if __riscv_xlen == 32
while (1) {
uint32_t hi = read_csr(mcycleh);
uint32_t lo = read_csr(mcycle);
if (hi == read_csr(mcycleh))
return ((uint64_t)hi << 32) | lo;
}
#else
return read_csr(mcycle);
#endif
}
static void uart_init(size_t baud_rate)
{
GPIO_REG(GPIO_IOF_SEL) &= ~IOF0_UART0_MASK;
GPIO_REG(GPIO_IOF_EN) |= IOF0_UART0_MASK;
UART0_REG(UART_REG_DIV) = get_cpu_freq() / baud_rate - 1;
UART0_REG(UART_REG_TXCTRL) |= UART_TXEN;
}
#ifdef USE_PLIC
extern void handle_m_ext_interrupt();
#endif
#ifdef USE_M_TIME
extern void handle_m_time_interrupt();
#endif
uintptr_t handle_trap(uintptr_t mcause, uintptr_t epc)
{
if (0){
#ifdef USE_PLIC
// External Machine-Level interrupt from PLIC
} else if ((mcause & MCAUSE_INT) && ((mcause & MCAUSE_CAUSE) == IRQ_M_EXT)) {
handle_m_ext_interrupt();
#endif
#ifdef USE_M_TIME
// External Machine-Level interrupt from PLIC
} else if ((mcause & MCAUSE_INT) && ((mcause & MCAUSE_CAUSE) == IRQ_M_TIMER)){
handle_m_time_interrupt();
#endif
}
else {
write(1, "Unhandled Trap:\n", 16);
_exit(1 + mcause);
}
return epc;
}
void _init()
{
#ifndef NO_INIT
uart_init(115200);
printf("core freq at %d Hz\n", get_cpu_freq());
write_csr(mtvec, &trap_entry);
#endif
}
void _fini()
{
}

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adapter_khz 10000
#source [find interface/ftdi/olimex-arm-usb-tiny-h.cfg]
interface ftdi
ftdi_device_desc "Olimex OpenOCD JTAG ARM-USB-TINY-H"
ftdi_vid_pid 0x15ba 0x002a
ftdi_layout_init 0x0808 0x0a1b
ftdi_layout_signal nSRST -oe 0x0200
ftdi_layout_signal nTRST -data 0x0100 -oe 0x0100
ftdi_layout_signal LED -data 0x0800
#
set _CHIPNAME riscv
jtag newtap $_CHIPNAME cpu -irlen 5 -expected-id 0x10e31913
set _TARGETNAME $_CHIPNAME.cpu
target create $_TARGETNAME riscv -chain-position $_TARGETNAME
$_TARGETNAME configure -work-area-phys 0x80000000 -work-area-size 10000 -work-area-backup 1
flash bank my_first_flash fespi 0x20000000 0 0 0 $_TARGETNAME
init
#reset
if {[ info exists pulse_srst]} {
ftdi_set_signal nSRST 0
ftdi_set_signal nSRST z
}
halt
#flash protect 0 64 last off

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// See LICENSE for license details.
#ifndef _SIFIVE_PLATFORM_H
#define _SIFIVE_PLATFORM_H
// Some things missing from the official encoding.h
#define MCAUSE_INT 0x80000000
#define MCAUSE_CAUSE 0x7FFFFFFF
#include "sifive/const.h"
#include "sifive/devices/aon.h"
#include "sifive/devices/clint.h"
#include "sifive/devices/gpio.h"
#include "sifive/devices/plic.h"
#include "sifive/devices/pwm.h"
#include "sifive/devices/spi.h"
#include "sifive/devices/uart.h"
/****************************************************************************
* Platform definitions
*****************************************************************************/
#define TRAPVEC_TABLE_CTRL_ADDR _AC(0x00001010,UL)
#define CLINT_CTRL_ADDR _AC(0x02000000,UL)
#define PLIC_CTRL_ADDR _AC(0x0C000000,UL)
#define AON_CTRL_ADDR _AC(0x10000000,UL)
#define GPIO_CTRL_ADDR _AC(0x10012000,UL)
#define UART0_CTRL_ADDR _AC(0x10013000,UL)
#define SPI0_CTRL_ADDR _AC(0x10014000,UL)
#define PWM0_CTRL_ADDR _AC(0x10015000,UL)
#define UART1_CTRL_ADDR _AC(0x10023000,UL)
#define SPI1_CTRL_ADDR _AC(0x10024000,UL)
#define PWM1_CTRL_ADDR _AC(0x10025000,UL)
#define SPI2_CTRL_ADDR _AC(0x10034000,UL)
#define PWM2_CTRL_ADDR _AC(0x10035000,UL)
#define SPI0_MMAP_ADDR _AC(0x20000000,UL)
#define MEM_CTRL_ADDR _AC(0x80000000,UL)
// IOF Mappings
#define IOF0_SPI1_MASK _AC(0x000007FC,UL)
#define SPI11_NUM_SS (4)
#define IOF_SPI1_SS0 (2u)
#define IOF_SPI1_SS1 (8u)
#define IOF_SPI1_SS2 (9u)
#define IOF_SPI1_SS3 (10u)
#define IOF_SPI1_MOSI (3u)
#define IOF_SPI1_MISO (4u)
#define IOF_SPI1_SCK (5u)
#define IOF_SPI1_DQ0 (3u)
#define IOF_SPI1_DQ1 (4u)
#define IOF_SPI1_DQ2 (6u)
#define IOF_SPI1_DQ3 (7u)
#define IOF0_SPI2_MASK _AC(0xFC000000,UL)
#define SPI2_NUM_SS (1)
#define IOF_SPI2_SS0 (26u)
#define IOF_SPI2_MOSI (27u)
#define IOF_SPI2_MISO (28u)
#define IOF_SPI2_SCK (29u)
#define IOF_SPI2_DQ0 (27u)
#define IOF_SPI2_DQ1 (28u)
#define IOF_SPI2_DQ2 (30u)
#define IOF_SPI2_DQ3 (31u)
#define IOF0_UART0_MASK _AC(0x00030000, UL)
#define IOF_UART0_RX (16u)
#define IOF_UART0_TX (17u)
#define IOF0_UART1_MASK _AC(0x03000000, UL)
#define IOF_UART1_RX (24u)
#define IOF_UART1_TX (25u)
#define IOF1_PWM0_MASK _AC(0x0000000F, UL)
#define IOF1_PWM1_MASK _AC(0x00780000, UL)
#define IOF1_PWM2_MASK _AC(0x00003C00, UL)
// Interrupt Numbers
#define INT_RESERVED 0
#define INT_WDOGCMP 1
#define INT_RTCCMP 2
#define INT_UART0_BASE 3
#define INT_UART1_BASE 4
#define INT_SPI0_BASE 5
#define INT_SPI1_BASE 6
#define INT_SPI2_BASE 7
#define INT_GPIO_BASE 8
#define INT_PWM0_BASE 40
#define INT_PWM1_BASE 44
#define INT_PWM2_BASE 48
// Helper functions
#define _REG32(p, i) (*(volatile uint32_t *) ((p) + (i)))
#define _REG32P(p, i) ((volatile uint32_t *) ((p) + (i)))
#define AON_REG(offset) _REG32(AON_CTRL_ADDR, offset)
#define CLINT_REG(offset) _REG32(CLINT_CTRL_ADDR, offset)
#define GPIO_REG(offset) _REG32(GPIO_CTRL_ADDR, offset)
#define OTP_REG(offset) _REG32(OTP_CTRL_ADDR, offset)
#define PLIC_REG(offset) _REG32(PLIC_CTRL_ADDR, offset)
#define PWM0_REG(offset) _REG32(PWM0_CTRL_ADDR, offset)
#define PWM1_REG(offset) _REG32(PWM1_CTRL_ADDR, offset)
#define PWM2_REG(offset) _REG32(PWM2_CTRL_ADDR, offset)
#define SPI0_REG(offset) _REG32(SPI0_CTRL_ADDR, offset)
#define SPI1_REG(offset) _REG32(SPI1_CTRL_ADDR, offset)
#define SPI2_REG(offset) _REG32(SPI2_CTRL_ADDR, offset)
#define UART0_REG(offset) _REG32(UART0_CTRL_ADDR, offset)
#define UART1_REG(offset) _REG32(UART1_CTRL_ADDR, offset)
// Misc
#include <stdint.h>
#define NUM_GPIO 32
#define PLIC_NUM_INTERRUPTS 52
#define PLIC_NUM_PRIORITIES 7
#define HAS_BOARD_BUTTONS
#include "hifive1.h"
unsigned long get_timer_freq(void);
uint64_t get_timer_value(void);
#endif /* _SIFIVE_PLATFORM_H */

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# Describes the CPU on this board to the rest of the SDK.
RISCV_ARCH := rv32imac
RISCV_ABI := ilp32

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OUTPUT_ARCH( "riscv" )
ENTRY( _start )
MEMORY
{
flash (rxai!w) : ORIGIN = 0x20400000, LENGTH = 512M
ram (wxa!ri) : ORIGIN = 0x80000000, LENGTH = 16K
}
PHDRS
{
flash PT_LOAD;
ram_init PT_LOAD;
ram PT_NULL;
}
SECTIONS
{
__stack_size = DEFINED(__stack_size) ? __stack_size : 2K;
.init :
{
KEEP (*(SORT_NONE(.init)))
} >flash AT>flash :flash
.text :
{
*(.text.unlikely .text.unlikely.*)
*(.text.startup .text.startup.*)
*(.text .text.*)
*(.gnu.linkonce.t.*)
} >flash AT>flash :flash
.fini :
{
KEEP (*(SORT_NONE(.fini)))
} >flash AT>flash :flash
PROVIDE (__etext = .);
PROVIDE (_etext = .);
PROVIDE (etext = .);
. = ALIGN(4);
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
} >flash AT>flash :flash
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.init_array.*) SORT_BY_INIT_PRIORITY(.ctors.*)))
KEEP (*(.init_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .ctors))
PROVIDE_HIDDEN (__init_array_end = .);
} >flash AT>flash :flash
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.fini_array.*) SORT_BY_INIT_PRIORITY(.dtors.*)))
KEEP (*(.fini_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
} >flash AT>flash :flash
.ctors :
{
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
} >flash AT>flash :flash
.dtors :
{
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
} >flash AT>flash :flash
.lalign :
{
. = ALIGN(4);
PROVIDE( _data_lma = . );
} >flash AT>flash :flash
.dalign :
{
. = ALIGN(4);
PROVIDE( _data = . );
} >ram AT>flash :ram_init
.data :
{
*(.rdata)
*(.rodata .rodata.*)
*(.gnu.linkonce.r.*)
*(.data .data.*)
*(.gnu.linkonce.d.*)
. = ALIGN(8);
PROVIDE( __global_pointer$ = . + 0x800 );
*(.sdata .sdata.*)
*(.gnu.linkonce.s.*)
. = ALIGN(8);
*(.srodata.cst16)
*(.srodata.cst8)
*(.srodata.cst4)
*(.srodata.cst2)
*(.srodata .srodata.*)
} >ram AT>flash :ram_init
. = ALIGN(4);
PROVIDE( _edata = . );
PROVIDE( edata = . );
PROVIDE( _fbss = . );
PROVIDE( __bss_start = . );
.bss :
{
*(.sbss*)
*(.gnu.linkonce.sb.*)
*(.bss .bss.*)
*(.gnu.linkonce.b.*)
*(COMMON)
. = ALIGN(4);
} >ram AT>ram :ram
. = ALIGN(8);
PROVIDE( _end = . );
PROVIDE( end = . );
.stack ORIGIN(ram) + LENGTH(ram) - __stack_size :
{
PROVIDE( _heap_end = . );
. = __stack_size;
PROVIDE( _sp = . );
} >ram AT>ram :ram
}

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@ -0,0 +1,166 @@
OUTPUT_ARCH( "riscv" )
ENTRY( _start )
MEMORY
{
flash (rxai!w) : ORIGIN = 0x20400000, LENGTH = 512M
ram (wxa!ri) : ORIGIN = 0x80000000, LENGTH = 512K
}
PHDRS
{
flash PT_LOAD;
ram_init PT_LOAD;
ram PT_NULL;
}
SECTIONS
{
__stack_size = DEFINED(__stack_size) ? __stack_size : 2K;
.init :
{
KEEP (*(SORT_NONE(.init)))
} >flash AT>flash :flash
.text :
{
*(.text.unlikely .text.unlikely.*)
*(.text.startup .text.startup.*)
*(.text .text.*)
*(.gnu.linkonce.t.*)
} >flash AT>flash :flash
.fini :
{
KEEP (*(SORT_NONE(.fini)))
} >flash AT>flash :flash
PROVIDE (__etext = .);
PROVIDE (_etext = .);
PROVIDE (etext = .);
.rodata :
{
*(.rdata)
*(.rodata .rodata.*)
*(.gnu.linkonce.r.*)
} >flash AT>flash :flash
. = ALIGN(4);
.preinit_array :
{
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP (*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
} >flash AT>flash :flash
.init_array :
{
PROVIDE_HIDDEN (__init_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.init_array.*) SORT_BY_INIT_PRIORITY(.ctors.*)))
KEEP (*(.init_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .ctors))
PROVIDE_HIDDEN (__init_array_end = .);
} >flash AT>flash :flash
.fini_array :
{
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP (*(SORT_BY_INIT_PRIORITY(.fini_array.*) SORT_BY_INIT_PRIORITY(.dtors.*)))
KEEP (*(.fini_array EXCLUDE_FILE (*crtbegin.o *crtbegin?.o *crtend.o *crtend?.o ) .dtors))
PROVIDE_HIDDEN (__fini_array_end = .);
} >flash AT>flash :flash
.ctors :
{
/* gcc uses crtbegin.o to find the start of
the constructors, so we make sure it is
first. Because this is a wildcard, it
doesn't matter if the user does not
actually link against crtbegin.o; the
linker won't look for a file to match a
wildcard. The wildcard also means that it
doesn't matter which directory crtbegin.o
is in. */
KEEP (*crtbegin.o(.ctors))
KEEP (*crtbegin?.o(.ctors))
/* We don't want to include the .ctor section from
the crtend.o file until after the sorted ctors.
The .ctor section from the crtend file contains the
end of ctors marker and it must be last */
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .ctors))
KEEP (*(SORT(.ctors.*)))
KEEP (*(.ctors))
} >flash AT>flash :flash
.dtors :
{
KEEP (*crtbegin.o(.dtors))
KEEP (*crtbegin?.o(.dtors))
KEEP (*(EXCLUDE_FILE (*crtend.o *crtend?.o ) .dtors))
KEEP (*(SORT(.dtors.*)))
KEEP (*(.dtors))
} >flash AT>flash :flash
.except :
{
*(.gcc_except_table.*)
} >flash AT>flash :flash
.lalign :
{
. = ALIGN(4);
PROVIDE( _data_lma = . );
} >flash AT>flash :flash
.dalign :
{
. = ALIGN(4);
PROVIDE( _data = . );
} >ram AT>flash :ram_init
.data :
{
*(.data .data.*)
*(.gnu.linkonce.d.*)
. = ALIGN(8);
PROVIDE( __global_pointer$ = . + 0x800 );
*(.sdata .sdata.*)
*(.gnu.linkonce.s.*)
. = ALIGN(8);
*(.srodata.cst16)
*(.srodata.cst8)
*(.srodata.cst4)
*(.srodata.cst2)
*(.srodata .srodata.*)
} >ram AT>flash :ram_init
. = ALIGN(4);
PROVIDE( _edata = . );
PROVIDE( edata = . );
PROVIDE( _fbss = . );
PROVIDE( __bss_start = . );
.bss :
{
*(.sbss*)
*(.gnu.linkonce.sb.*)
*(.bss .bss.*)
*(.gnu.linkonce.b.*)
*(COMMON)
. = ALIGN(4);
} >ram AT>ram :ram
. = ALIGN(8);
PROVIDE( _end = . );
PROVIDE( end = . );
.stack ORIGIN(ram) + LENGTH(ram) - __stack_size :
{
PROVIDE( _heap_end = . );
. = __stack_size;
PROVIDE( _sp = . );
} >ram AT>ram :ram
}

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@ -0,0 +1,238 @@
#include <stdint.h>
#include <stdio.h>
#include <unistd.h>
#include "platform.h"
#include "encoding.h"
extern int main(int argc, char** argv);
extern void trap_entry();
static unsigned long mtime_lo(void)
{
return *(volatile unsigned long *)(CLINT_CTRL_ADDR + CLINT_MTIME);
}
#ifdef __riscv32
static uint32_t mtime_hi(void)
{
return *(volatile uint32_t *)(CLINT_CTRL_ADDR + CLINT_MTIME + 4);
}
uint64_t get_timer_value()
{
while (1) {
uint32_t hi = mtime_hi();
uint32_t lo = mtime_lo();
if (hi == mtime_hi())
return ((uint64_t)hi << 32) | lo;
}
}
#else /* __riscv32 */
uint64_t get_timer_value()
{
return mtime_lo();
}
#endif
unsigned long get_timer_freq()
{
return 32768;
}
static void use_hfrosc(int div, int trim)
{
// Make sure the HFROSC is running at its default setting
PRCI_REG(PRCI_HFROSCCFG) = (ROSC_DIV(div) | ROSC_TRIM(trim) | ROSC_EN(1));
while ((PRCI_REG(PRCI_HFROSCCFG) & ROSC_RDY(1)) == 0) ;
PRCI_REG(PRCI_PLLCFG) &= ~PLL_SEL(1);
}
static void use_pll(int refsel, int bypass, int r, int f, int q)
{
// Ensure that we aren't running off the PLL before we mess with it.
if (PRCI_REG(PRCI_PLLCFG) & PLL_SEL(1)) {
// Make sure the HFROSC is running at its default setting
use_hfrosc(4, 16);
}
// Set PLL Source to be HFXOSC if available.
uint32_t config_value = 0;
config_value |= PLL_REFSEL(refsel);
if (bypass) {
// Bypass
config_value |= PLL_BYPASS(1);
PRCI_REG(PRCI_PLLCFG) = config_value;
// If we don't have an HFXTAL, this doesn't really matter.
// Set our Final output divide to divide-by-1:
PRCI_REG(PRCI_PLLDIV) = (PLL_FINAL_DIV_BY_1(1) | PLL_FINAL_DIV(0));
} else {
// In case we are executing from QSPI,
// (which is quite likely) we need to
// set the QSPI clock divider appropriately
// before boosting the clock frequency.
// Div = f_sck/2
SPI0_REG(SPI_REG_SCKDIV) = 8;
// Set DIV Settings for PLL
// Both HFROSC and HFXOSC are modeled as ideal
// 16MHz sources (assuming dividers are set properly for
// HFROSC).
// (Legal values of f_REF are 6-48MHz)
// Set DIVR to divide-by-2 to get 8MHz frequency
// (legal values of f_R are 6-12 MHz)
config_value |= PLL_BYPASS(1);
config_value |= PLL_R(r);
// Set DIVF to get 512Mhz frequncy
// There is an implied multiply-by-2, 16Mhz.
// So need to write 32-1
// (legal values of f_F are 384-768 MHz)
config_value |= PLL_F(f);
// Set DIVQ to divide-by-2 to get 256 MHz frequency
// (legal values of f_Q are 50-400Mhz)
config_value |= PLL_Q(q);
// Set our Final output divide to divide-by-1:
PRCI_REG(PRCI_PLLDIV) = (PLL_FINAL_DIV_BY_1(1) | PLL_FINAL_DIV(0));
PRCI_REG(PRCI_PLLCFG) = config_value;
// Un-Bypass the PLL.
PRCI_REG(PRCI_PLLCFG) &= ~PLL_BYPASS(1);
// Wait for PLL Lock
// Note that the Lock signal can be glitchy.
// Need to wait 100 us
// RTC is running at 32kHz.
// So wait 4 ticks of RTC.
uint32_t now = mtime_lo();
while (mtime_lo() - now < 4) ;
// Now it is safe to check for PLL Lock
while ((PRCI_REG(PRCI_PLLCFG) & PLL_LOCK(1)) == 0) ;
}
// Switch over to PLL Clock source
PRCI_REG(PRCI_PLLCFG) |= PLL_SEL(1);
}
static void use_default_clocks()
{
// Turn off the LFROSC
AON_REG(AON_LFROSC) &= ~ROSC_EN(1);
// Use HFROSC
use_hfrosc(4, 16);
}
static unsigned long __attribute__((noinline)) measure_cpu_freq(size_t n)
{
unsigned long start_mtime, delta_mtime;
unsigned long mtime_freq = get_timer_freq();
// Don't start measuruing until we see an mtime tick
unsigned long tmp = mtime_lo();
do {
start_mtime = mtime_lo();
} while (start_mtime == tmp);
unsigned long start_mcycle = read_csr(mcycle);
do {
delta_mtime = mtime_lo() - start_mtime;
} while (delta_mtime < n);
unsigned long delta_mcycle = read_csr(mcycle) - start_mcycle;
return (delta_mcycle / delta_mtime) * mtime_freq
+ ((delta_mcycle % delta_mtime) * mtime_freq) / delta_mtime;
}
unsigned long get_cpu_freq()
{
static uint32_t cpu_freq;
if (!cpu_freq) {
// warm up I$
measure_cpu_freq(1);
// measure for real
cpu_freq = measure_cpu_freq(10);
}
return cpu_freq;
}
static void uart_init(size_t baud_rate)
{
GPIO_REG(GPIO_IOF_SEL) &= ~IOF0_UART0_MASK;
GPIO_REG(GPIO_IOF_EN) |= IOF0_UART0_MASK;
UART0_REG(UART_REG_DIV) = get_cpu_freq() / baud_rate - 1;
UART0_REG(UART_REG_TXCTRL) |= UART_TXEN;
}
#ifdef USE_PLIC
extern void handle_m_ext_interrupt();
#endif
#ifdef USE_M_TIME
extern void handle_m_time_interrupt();
#endif
uintptr_t handle_trap(uintptr_t mcause, uintptr_t epc)
{
if (0){
#ifdef USE_PLIC
// External Machine-Level interrupt from PLIC
} else if ((mcause & MCAUSE_INT) && ((mcause & MCAUSE_CAUSE) == IRQ_M_EXT)) {
handle_m_ext_interrupt();
#endif
#ifdef USE_M_TIME
// External Machine-Level interrupt from PLIC
} else if ((mcause & MCAUSE_INT) && ((mcause & MCAUSE_CAUSE) == IRQ_M_TIMER)){
handle_m_time_interrupt();
#endif
}
else {
write(1, "trap\n", 5);
_exit(1 + mcause);
}
return epc;
}
void _init()
{
#ifndef NO_INIT
use_default_clocks();
use_pll(0, 0, 1, 31, 1);
uart_init(115200);
printf("core freq at %d Hz\n", get_cpu_freq());
write_csr(mtvec, &trap_entry);
if (read_csr(misa) & (1 << ('F' - 'A'))) { // if F extension is present
write_csr(mstatus, MSTATUS_FS); // allow FPU instructions without trapping
write_csr(fcsr, 0); // initialize rounding mode, undefined at reset
}
#endif
}
void _fini()
{
}

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adapter_khz 10000
interface ftdi
ftdi_device_desc "Dual RS232-HS"
ftdi_vid_pid 0x0403 0x6010
ftdi_layout_init 0x0008 0x001b
ftdi_layout_signal nSRST -oe 0x0020 -data 0x0020
#Reset Stretcher logic on FE310 is ~1 second long
#This doesn't apply if you use
# ftdi_set_signal, but still good to document
#adapter_nsrst_delay 1500
set _CHIPNAME riscv
jtag newtap $_CHIPNAME cpu -irlen 5 -expected-id 0x10e31913
set _TARGETNAME $_CHIPNAME.cpu
target create $_TARGETNAME riscv -chain-position $_TARGETNAME
$_TARGETNAME configure -work-area-phys 0x80000000 -work-area-size 10000 -work-area-backup 1
flash bank onboard_spi_flash fespi 0x20000000 0 0 0 $_TARGETNAME
init
#reset -- This type of reset is not implemented yet
if {[ info exists pulse_srst]} {
ftdi_set_signal nSRST 0
ftdi_set_signal nSRST z
#Wait for the reset stretcher
#It will work without this, but
#will incur lots of delays for later commands.
sleep 1500
}
halt
#flash protect 0 64 last off

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// See LICENSE for license details.
#ifndef _SIFIVE_PLATFORM_H
#define _SIFIVE_PLATFORM_H
// Some things missing from the official encoding.h
#define MCAUSE_INT 0x80000000
#define MCAUSE_CAUSE 0x7FFFFFFF
#include "sifive/const.h"
#include "sifive/devices/aon.h"
#include "sifive/devices/clint.h"
#include "sifive/devices/gpio.h"
#include "sifive/devices/otp.h"
#include "sifive/devices/plic.h"
#include "sifive/devices/prci.h"
#include "sifive/devices/pwm.h"
#include "sifive/devices/spi.h"
#include "sifive/devices/uart.h"
/****************************************************************************
* Platform definitions
*****************************************************************************/
// Memory map
#define MASKROM_MEM_ADDR _AC(0x00001000,UL)
#define TRAPVEC_TABLE_CTRL_ADDR _AC(0x00001010,UL)
#define OTP_MEM_ADDR _AC(0x00020000,UL)
#define CLINT_CTRL_ADDR _AC(0x02000000,UL)
#define PLIC_CTRL_ADDR _AC(0x0C000000,UL)
#define AON_CTRL_ADDR _AC(0x10000000,UL)
#define PRCI_CTRL_ADDR _AC(0x10008000,UL)
#define OTP_CTRL_ADDR _AC(0x10010000,UL)
#define GPIO_CTRL_ADDR _AC(0x10012000,UL)
#define UART0_CTRL_ADDR _AC(0x10013000,UL)
#define SPI0_CTRL_ADDR _AC(0x10014000,UL)
#define PWM0_CTRL_ADDR _AC(0x10015000,UL)
#define UART1_CTRL_ADDR _AC(0x10023000,UL)
#define SPI1_CTRL_ADDR _AC(0x10024000,UL)
#define PWM1_CTRL_ADDR _AC(0x10025000,UL)
#define SPI2_CTRL_ADDR _AC(0x10034000,UL)
#define PWM2_CTRL_ADDR _AC(0x10035000,UL)
#define SPI0_MEM_ADDR _AC(0x20000000,UL)
#define MEM_CTRL_ADDR _AC(0x80000000,UL)
// IOF masks
#define IOF0_SPI1_MASK _AC(0x000007FC,UL)
#define SPI11_NUM_SS (4)
#define IOF_SPI1_SS0 (2u)
#define IOF_SPI1_SS1 (8u)
#define IOF_SPI1_SS2 (9u)
#define IOF_SPI1_SS3 (10u)
#define IOF_SPI1_MOSI (3u)
#define IOF_SPI1_MISO (4u)
#define IOF_SPI1_SCK (5u)
#define IOF_SPI1_DQ0 (3u)
#define IOF_SPI1_DQ1 (4u)
#define IOF_SPI1_DQ2 (6u)
#define IOF_SPI1_DQ3 (7u)
#define IOF0_SPI2_MASK _AC(0xFC000000,UL)
#define SPI2_NUM_SS (1)
#define IOF_SPI2_SS0 (26u)
#define IOF_SPI2_MOSI (27u)
#define IOF_SPI2_MISO (28u)
#define IOF_SPI2_SCK (29u)
#define IOF_SPI2_DQ0 (27u)
#define IOF_SPI2_DQ1 (28u)
#define IOF_SPI2_DQ2 (30u)
#define IOF_SPI2_DQ3 (31u)
//#define IOF0_I2C_MASK _AC(0x00003000,UL)
#define IOF0_UART0_MASK _AC(0x00030000, UL)
#define IOF_UART0_RX (16u)
#define IOF_UART0_TX (17u)
#define IOF0_UART1_MASK _AC(0x03000000, UL)
#define IOF_UART1_RX (24u)
#define IOF_UART1_TX (25u)
#define IOF1_PWM0_MASK _AC(0x0000000F, UL)
#define IOF1_PWM1_MASK _AC(0x00780000, UL)
#define IOF1_PWM2_MASK _AC(0x00003C00, UL)
// Interrupt numbers
#define INT_RESERVED 0
#define INT_WDOGCMP 1
#define INT_RTCCMP 2
#define INT_UART0_BASE 3
#define INT_UART1_BASE 4
#define INT_SPI0_BASE 5
#define INT_SPI1_BASE 6
#define INT_SPI2_BASE 7
#define INT_GPIO_BASE 8
#define INT_PWM0_BASE 40
#define INT_PWM1_BASE 44
#define INT_PWM2_BASE 48
// Helper functions
#define _REG32(p, i) (*(volatile uint32_t *) ((p) + (i)))
#define _REG32P(p, i) ((volatile uint32_t *) ((p) + (i)))
#define AON_REG(offset) _REG32(AON_CTRL_ADDR, offset)
#define CLINT_REG(offset) _REG32(CLINT_CTRL_ADDR, offset)
#define GPIO_REG(offset) _REG32(GPIO_CTRL_ADDR, offset)
#define OTP_REG(offset) _REG32(OTP_CTRL_ADDR, offset)
#define PLIC_REG(offset) _REG32(PLIC_CTRL_ADDR, offset)
#define PRCI_REG(offset) _REG32(PRCI_CTRL_ADDR, offset)
#define PWM0_REG(offset) _REG32(PWM0_CTRL_ADDR, offset)
#define PWM1_REG(offset) _REG32(PWM1_CTRL_ADDR, offset)
#define PWM2_REG(offset) _REG32(PWM2_CTRL_ADDR, offset)
#define SPI0_REG(offset) _REG32(SPI0_CTRL_ADDR, offset)
#define SPI1_REG(offset) _REG32(SPI1_CTRL_ADDR, offset)
#define SPI2_REG(offset) _REG32(SPI2_CTRL_ADDR, offset)
#define UART0_REG(offset) _REG32(UART0_CTRL_ADDR, offset)
#define UART1_REG(offset) _REG32(UART1_CTRL_ADDR, offset)
// Misc
#include <stdint.h>
#define NUM_GPIO 32
#define PLIC_NUM_INTERRUPTS 52
#define PLIC_NUM_PRIORITIES 7
#include "hifive1.h"
unsigned long get_cpu_freq(void);
unsigned long get_timer_freq(void);
uint64_t get_timer_value(void);
#endif /* _SIFIVE_PLATFORM_H */

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# Describes the CPU on this board to the rest of the SDK.
RISCV_ARCH := rv32imac
RISCV_ABI := ilp32

81
fpga_spn/bsp/env/hifive1.h vendored Normal file
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// See LICENSE for license details.
#ifndef _SIFIVE_HIFIVE1_H
#define _SIFIVE_HIFIVE1_H
#include <stdint.h>
/****************************************************************************
* GPIO Connections
*****************************************************************************/
// These are the GPIO bit offsets for the RGB LED on HiFive1 Board.
// These are also mapped to RGB LEDs on the Freedom E300 Arty
// FPGA
// Dev Kit.
#define RED_LED_OFFSET 22
#define GREEN_LED_OFFSET 19
#define BLUE_LED_OFFSET 21
// These are the GPIO bit offsets for the differen digital pins
// on the headers for both the HiFive1 Board and the Freedom E300 Arty FPGA Dev Kit.
#define PIN_0_OFFSET 16
#define PIN_1_OFFSET 17
#define PIN_2_OFFSET 18
#define PIN_3_OFFSET 19
#define PIN_4_OFFSET 20
#define PIN_5_OFFSET 21
#define PIN_6_OFFSET 22
#define PIN_7_OFFSET 23
#define PIN_8_OFFSET 0
#define PIN_9_OFFSET 1
#define PIN_10_OFFSET 2
#define PIN_11_OFFSET 3
#define PIN_12_OFFSET 4
#define PIN_13_OFFSET 5
//#define PIN_14_OFFSET 8 //This pin is not connected on either board.
#define PIN_15_OFFSET 9
#define PIN_16_OFFSET 10
#define PIN_17_OFFSET 11
#define PIN_18_OFFSET 12
#define PIN_19_OFFSET 13
// These are *PIN* numbers, not
// GPIO Offset Numbers.
#define PIN_SPI1_SCK (13u)
#define PIN_SPI1_MISO (12u)
#define PIN_SPI1_MOSI (11u)
#define PIN_SPI1_SS0 (10u)
#define PIN_SPI1_SS1 (14u)
#define PIN_SPI1_SS2 (15u)
#define PIN_SPI1_SS3 (16u)
#define SS_PIN_TO_CS_ID(x) \
((x==PIN_SPI1_SS0 ? 0 : \
(x==PIN_SPI1_SS1 ? 1 : \
(x==PIN_SPI1_SS2 ? 2 : \
(x==PIN_SPI1_SS3 ? 3 : \
-1)))))
// These buttons are present only on the Freedom E300 Arty Dev Kit.
#ifdef HAS_BOARD_BUTTONS
#define BUTTON_0_OFFSET 15
#define BUTTON_1_OFFSET 30
#define BUTTON_2_OFFSET 31
#define INT_DEVICE_BUTTON_0 (INT_GPIO_BASE + BUTTON_0_OFFSET)
#define INT_DEVICE_BUTTON_1 (INT_GPIO_BASE + BUTTON_1_OFFSET)
#define INT_DEVICE_BUTTON_2 (INT_GPIO_BASE + BUTTON_2_OFFSET)
#endif
#define HAS_HFXOSC 1
#define HAS_LFROSC_BYPASS 1
#define RTC_FREQ 32768
void write_hex(int fd, unsigned long int hex);
#endif /* _SIFIVE_HIFIVE1_H */

111
fpga_spn/bsp/env/start.S vendored Normal file
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// See LICENSE for license details.
#include <sifive/smp.h>
/* This is defined in sifive/platform.h, but that can't be included from
* assembly. */
#define CLINT_CTRL_ADDR 0x02000000
.section .init
.globl _start
.type _start,@function
_start:
.cfi_startproc
.cfi_undefined ra
.option push
.option norelax
la gp, __global_pointer$
.option pop
la sp, _sp
#if defined(ENABLE_SMP)
smp_pause(t0, t1)
#endif
/* Load data section */
la a0, _data_lma
la a1, _data
la a2, _edata
bgeu a1, a2, 2f
1:
lw t0, (a0)
sw t0, (a1)
addi a0, a0, 4
addi a1, a1, 4
bltu a1, a2, 1b
2:
/* Clear bss section */
la a0, __bss_start
la a1, _end
bgeu a0, a1, 2f
1:
sw zero, (a0)
addi a0, a0, 4
bltu a0, a1, 1b
2:
/* Call global constructors */
la a0, __libc_fini_array
call atexit
call __libc_init_array
#ifndef __riscv_float_abi_soft
/* Enable FPU */
li t0, MSTATUS_FS
csrs mstatus, t0
csrr t1, mstatus
and t1, t1, t0
beqz t1, 1f
fssr x0
1:
#endif
#if defined(ENABLE_SMP)
smp_resume(t0, t1)
csrr a0, mhartid
bnez a0, 2f
#endif
auipc ra, 0
addi sp, sp, -16
#if __riscv_xlen == 32
sw ra, 8(sp)
#else
sd ra, 8(sp)
#endif
/* argc = argv = 0 */
li a0, 0
li a1, 0
call main
tail exit
1:
j 1b
#if defined(ENABLE_SMP)
2:
la t0, trap_entry
csrw mtvec, t0
csrr a0, mhartid
la t1, _sp
slli t0, a0, 10
sub sp, t1, t0
auipc ra, 0
addi sp, sp, -16
#if __riscv_xlen == 32
sw ra, 8(sp)
#else
sd ra, 8(sp)
#endif
call secondary_main
tail exit
1:
j 1b
#endif
.cfi_endproc

288
fpga_spn/bsp/env/ventry.S vendored Normal file
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// See LICENSE for license details
#ifndef VENTRY_S
#define VENTRY_S
#include "encoding.h"
#include "sifive/bits.h"
#only save caller registers
.macro TRAP_ENTRY
addi sp, sp, -16*REGBYTES
STORE x1, 0*REGBYTES(sp)
STORE x5, 1*REGBYTES(sp)
STORE x6, 2*REGBYTES(sp)
STORE x7, 3*REGBYTES(sp)
STORE x10, 4*REGBYTES(sp)
STORE x11, 5*REGBYTES(sp)
STORE x12, 6*REGBYTES(sp)
STORE x13, 7*REGBYTES(sp)
STORE x14, 8*REGBYTES(sp)
STORE x15, 9*REGBYTES(sp)
STORE x16, 10*REGBYTES(sp)
STORE x17, 11*REGBYTES(sp)
STORE x28, 12*REGBYTES(sp)
STORE x29, 13*REGBYTES(sp)
STORE x30, 14*REGBYTES(sp)
STORE x31, 15*REGBYTES(sp)
.endm
#restore caller registers
.macro TRAP_EXIT
# Remain in M-mode after mret
li t0, MSTATUS_MPP
csrs mstatus, t0
LOAD x1, 0*REGBYTES(sp)
LOAD x5, 1*REGBYTES(sp)
LOAD x6, 2*REGBYTES(sp)
LOAD x7, 3*REGBYTES(sp)
LOAD x10, 4*REGBYTES(sp)
LOAD x11, 5*REGBYTES(sp)
LOAD x12, 6*REGBYTES(sp)
LOAD x13, 7*REGBYTES(sp)
LOAD x14, 8*REGBYTES(sp)
LOAD x15, 9*REGBYTES(sp)
LOAD x16, 10*REGBYTES(sp)
LOAD x17, 11*REGBYTES(sp)
LOAD x28, 12*REGBYTES(sp)
LOAD x29, 13*REGBYTES(sp)
LOAD x30, 14*REGBYTES(sp)
LOAD x31, 15*REGBYTES(sp)
addi sp, sp, 16*REGBYTES
mret
.endm
#Vector table for E31/E51
.section .text.entry
.align 8
.global vtrap_entry
vtrap_entry:
j sync_trap
.align 2
j reserved
.align 2
j reserved
.align 2
j vmsi_Handler
.align 2
j reserved
.align 2
j reserved
.align 2
j reserved
.align 2
j vmti_Handler
.align 2
j reserved
.align 2
j reserved
.align 2
j reserved
.align 2
j vmei_Handler
.align 2
j reserved
.align 2
j reserved
.align 2
j reserved
.align 2
j reserved
.align 2
j vlip_Handler0
.align 2
j vlip_Handler1
.align 2
j vlip_Handler2
.align 2
j vlip_Handler3
.align 2
j vlip_Handler4
.align 2
j vlip_Handler5
.align 2
j vlip_Handler6
.align 2
j vlip_Handler7
.align 2
j vlip_Handler8
.align 2
j vlip_Handler9
.align 2
j vlip_Handler10
.align 2
j vlip_Handler11
.align 2
j vlip_Handler12
.align 2
j vlip_Handler13
.align 2
j vlip_Handler14
.align 2
j vlip_Handler15
#synchronous trap
sync_trap:
TRAP_ENTRY
jal handle_sync_trap
TRAP_EXIT
#Machine Software Interrupt
vmsi_Handler:
TRAP_ENTRY
jal reserved
TRAP_EXIT
#Machine Timer Interrupt
vmti_Handler:
TRAP_ENTRY
jal handle_m_time_interrupt
TRAP_EXIT
#Machine External Interrupt
vmei_Handler:
TRAP_ENTRY
jal handle_m_external_interrupt
TRAP_EXIT
#LIP0
vlip_Handler0:
TRAP_ENTRY
jal handle_local_interrupt0
TRAP_EXIT
#LIP1
vlip_Handler1:
TRAP_ENTRY
jal handle_local_interrupt1
TRAP_EXIT
#LIP2
vlip_Handler2:
TRAP_ENTRY
jal handle_local_interrupt2
TRAP_EXIT
#LIP3
vlip_Handler3:
TRAP_ENTRY
jal handle_local_interrupt3
TRAP_EXIT
#LIP4
vlip_Handler4:
TRAP_ENTRY
jal handle_local_interrupt4
TRAP_EXIT
#LIP5
vlip_Handler5:
TRAP_ENTRY
jal handle_local_interrupt5
TRAP_EXIT
#LIP6
vlip_Handler6:
TRAP_ENTRY
jal handle_local_interrupt6
TRAP_EXIT
#LIP7
vlip_Handler7:
TRAP_ENTRY
jal handle_local_interrupt7
TRAP_EXIT
#LIP8
vlip_Handler8:
TRAP_ENTRY
jal handle_local_interrupt8
TRAP_EXIT
#LIP9
vlip_Handler9:
TRAP_ENTRY
jal handle_local_interrupt9
TRAP_EXIT
#LIP10
vlip_Handler10:
TRAP_ENTRY
jal handle_local_interrupt10
TRAP_EXIT
#LIP11
vlip_Handler11:
TRAP_ENTRY
jal handle_local_interrupt11
TRAP_EXIT
#LIP12
vlip_Handler12:
TRAP_ENTRY
jal handle_local_interrupt12
TRAP_EXIT
#LIP13
vlip_Handler13:
TRAP_ENTRY
jal handle_local_interrupt13
TRAP_EXIT
#LIP14
vlip_Handler14:
TRAP_ENTRY
jal handle_local_interrupt14
TRAP_EXIT
#LIP15
vlip_Handler15:
TRAP_ENTRY
jal handle_local_interrupt15
TRAP_EXIT
#unimplemented ISRs trap here
.weak reserved
reserved:
.weak handle_local_interrupt0
handle_local_interrupt0:
.weak handle_local_interrupt1
handle_local_interrupt1:
.weak handle_local_interrupt2
handle_local_interrupt2:
.weak handle_local_interrupt3
handle_local_interrupt3:
.weak handle_local_interrupt4
handle_local_interrupt4:
.weak handle_local_interrupt5
handle_local_interrupt5:
.weak handle_local_interrupt6
handle_local_interrupt6:
.weak handle_local_interrupt7
handle_local_interrupt7:
.weak handle_local_interrupt8
handle_local_interrupt8:
.weak handle_local_interrupt9
handle_local_interrupt9:
.weak handle_local_interrupt10
handle_local_interrupt10:
.weak handle_local_interrupt11
handle_local_interrupt11:
.weak handle_local_interrupt12
handle_local_interrupt12:
.weak handle_local_interrupt13
handle_local_interrupt13:
.weak handle_local_interrupt14
handle_local_interrupt14:
.weak handle_local_interrupt15
handle_local_interrupt15:
1:
j 1b
#endif

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// See LICENSE for license details.
#ifndef _RISCV_BITS_H
#define _RISCV_BITS_H
#define likely(x) __builtin_expect((x), 1)
#define unlikely(x) __builtin_expect((x), 0)
#define ROUNDUP(a, b) ((((a)-1)/(b)+1)*(b))
#define ROUNDDOWN(a, b) ((a)/(b)*(b))
#define MAX(a, b) ((a) > (b) ? (a) : (b))
#define MIN(a, b) ((a) < (b) ? (a) : (b))
#define CLAMP(a, lo, hi) MIN(MAX(a, lo), hi)
#define EXTRACT_FIELD(val, which) (((val) & (which)) / ((which) & ~((which)-1)))
#define INSERT_FIELD(val, which, fieldval) (((val) & ~(which)) | ((fieldval) * ((which) & ~((which)-1))))
#define STR(x) XSTR(x)
#define XSTR(x) #x
#if __riscv_xlen == 64
# define SLL32 sllw
# define STORE sd
# define LOAD ld
# define LWU lwu
# define LOG_REGBYTES 3
#else
# define SLL32 sll
# define STORE sw
# define LOAD lw
# define LWU lw
# define LOG_REGBYTES 2
#endif
#define REGBYTES (1 << LOG_REGBYTES)
#endif

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// See LICENSE for license details.
/* Derived from <linux/const.h> */
#ifndef _SIFIVE_CONST_H
#define _SIFIVE_CONST_H
#ifdef __ASSEMBLER__
#define _AC(X,Y) X
#define _AT(T,X) X
#else
#define _AC(X,Y) (X##Y)
#define _AT(T,X) ((T)(X))
#endif /* !__ASSEMBLER__*/
#define _BITUL(x) (_AC(1,UL) << (x))
#define _BITULL(x) (_AC(1,ULL) << (x))
#endif /* _SIFIVE_CONST_H */

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// See LICENSE for license details.
#ifndef _SIFIVE_AON_H
#define _SIFIVE_AON_H
/* Register offsets */
#define AON_WDOGCFG 0x000
#define AON_WDOGCOUNT 0x008
#define AON_WDOGS 0x010
#define AON_WDOGFEED 0x018
#define AON_WDOGKEY 0x01C
#define AON_WDOGCMP 0x020
#define AON_RTCCFG 0x040
#define AON_RTCLO 0x048
#define AON_RTCHI 0x04C
#define AON_RTCS 0x050
#define AON_RTCCMP 0x060
#define AON_BACKUP0 0x080
#define AON_BACKUP1 0x084
#define AON_BACKUP2 0x088
#define AON_BACKUP3 0x08C
#define AON_BACKUP4 0x090
#define AON_BACKUP5 0x094
#define AON_BACKUP6 0x098
#define AON_BACKUP7 0x09C
#define AON_BACKUP8 0x0A0
#define AON_BACKUP9 0x0A4
#define AON_BACKUP10 0x0A8
#define AON_BACKUP11 0x0AC
#define AON_BACKUP12 0x0B0
#define AON_BACKUP13 0x0B4
#define AON_BACKUP14 0x0B8
#define AON_BACKUP15 0x0BC
#define AON_PMUWAKEUPI0 0x100
#define AON_PMUWAKEUPI1 0x104
#define AON_PMUWAKEUPI2 0x108
#define AON_PMUWAKEUPI3 0x10C
#define AON_PMUWAKEUPI4 0x110
#define AON_PMUWAKEUPI5 0x114
#define AON_PMUWAKEUPI6 0x118
#define AON_PMUWAKEUPI7 0x11C
#define AON_PMUSLEEPI0 0x120
#define AON_PMUSLEEPI1 0x124
#define AON_PMUSLEEPI2 0x128
#define AON_PMUSLEEPI3 0x12C
#define AON_PMUSLEEPI4 0x130
#define AON_PMUSLEEPI5 0x134
#define AON_PMUSLEEPI6 0x138
#define AON_PMUSLEEPI7 0x13C
#define AON_PMUIE 0x140
#define AON_PMUCAUSE 0x144
#define AON_PMUSLEEP 0x148
#define AON_PMUKEY 0x14C
#define AON_LFROSC 0x070
/* Constants */
#define AON_WDOGKEY_VALUE 0x51F15E
#define AON_WDOGFEED_VALUE 0xD09F00D
#define AON_WDOGCFG_SCALE 0x0000000F
#define AON_WDOGCFG_RSTEN 0x00000100
#define AON_WDOGCFG_ZEROCMP 0x00000200
#define AON_WDOGCFG_ENALWAYS 0x00001000
#define AON_WDOGCFG_ENCOREAWAKE 0x00002000
#define AON_WDOGCFG_CMPIP 0x10000000
#define AON_RTCCFG_SCALE 0x0000000F
#define AON_RTCCFG_ENALWAYS 0x00001000
#define AON_RTCCFG_CMPIP 0x10000000
#define AON_WAKEUPCAUSE_RESET 0x00
#define AON_WAKEUPCAUSE_RTC 0x01
#define AON_WAKEUPCAUSE_DWAKEUP 0x02
#define AON_WAKEUPCAUSE_AWAKEUP 0x03
#define AON_RESETCAUSE_POWERON 0x0000
#define AON_RESETCAUSE_EXTERNAL 0x0100
#define AON_RESETCAUSE_WATCHDOG 0x0200
#define AON_PMUCAUSE_WAKEUPCAUSE 0x00FF
#define AON_PMUCAUSE_RESETCAUSE 0xFF00
#endif /* _SIFIVE_AON_H */

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// See LICENSE for license details.
#ifndef _SIFIVE_CLIC_H
#define _SIFIVE_CLIC_H
#define CLIC_HART0 0x00800000
#define CLIC_MSIP 0x0000
#define CLIC_MSIP_size 0x4
#define CLIC_MTIMECMP 0x4000
#define CLIC_MTIMECMP_size 0x8
#define CLIC_MTIME 0xBFF8
#define CLIC_MTIME_size 0x8
#define CLIC_INTIP 0x000
#define CLIC_INTIE 0x400
#define CLIC_INTCFG 0x800
#define CLIC_CFG 0xc00
// These interrupt IDs are consistent across old and new mtvec modes
#define SSIPID 1
#define MSIPID 3
#define STIPID 5
#define MTIPID 7
#define SEIPID 9
#define MEIPID 11
#define CSIPID 12
#define LOCALINTIDBASE 16
#endif /* _SIFIVE_CLIC_H */

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// See LICENSE for license details
#ifndef _SIFIVE_CLINT_H
#define _SIFIVE_CLINT_H
#define CLINT_MSIP 0x0000
#define CLINT_MSIP_size 0x4
#define CLINT_MTIMECMP 0x4000
#define CLINT_MTIMECMP_size 0x8
#define CLINT_MTIME 0xBFF8
#define CLINT_MTIME_size 0x8
#endif /* _SIFIVE_CLINT_H */

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// See LICENSE for license details.
#ifndef _SIFIVE_GPIO_H
#define _SIFIVE_GPIO_H
#define GPIO_INPUT_VAL (0x00)
#define GPIO_INPUT_EN (0x04)
#define GPIO_OUTPUT_EN (0x08)
#define GPIO_OUTPUT_VAL (0x0C)
#define GPIO_PULLUP_EN (0x10)
#define GPIO_DRIVE (0x14)
#define GPIO_RISE_IE (0x18)
#define GPIO_RISE_IP (0x1C)
#define GPIO_FALL_IE (0x20)
#define GPIO_FALL_IP (0x24)
#define GPIO_HIGH_IE (0x28)
#define GPIO_HIGH_IP (0x2C)
#define GPIO_LOW_IE (0x30)
#define GPIO_LOW_IP (0x34)
#define GPIO_IOF_EN (0x38)
#define GPIO_IOF_SEL (0x3C)
#define GPIO_OUTPUT_XOR (0x40)
#endif /* _SIFIVE_GPIO_H */

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// See LICENSE for license details.
#ifndef _SIFIVE_OTP_H
#define _SIFIVE_OTP_H
/* Register offsets */
#define OTP_LOCK 0x00
#define OTP_CK 0x04
#define OTP_OE 0x08
#define OTP_SEL 0x0C
#define OTP_WE 0x10
#define OTP_MR 0x14
#define OTP_MRR 0x18
#define OTP_MPP 0x1C
#define OTP_VRREN 0x20
#define OTP_VPPEN 0x24
#define OTP_A 0x28
#define OTP_D 0x2C
#define OTP_Q 0x30
#define OTP_READ_TIMINGS 0x34
#endif

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// See LICENSE for license details.
#ifndef PLIC_H
#define PLIC_H
#include <sifive/const.h>
// 32 bits per source
#define PLIC_PRIORITY_OFFSET _AC(0x0000,UL)
#define PLIC_PRIORITY_SHIFT_PER_SOURCE 2
// 1 bit per source (1 address)
#define PLIC_PENDING_OFFSET _AC(0x1000,UL)
#define PLIC_PENDING_SHIFT_PER_SOURCE 0
//0x80 per target
#define PLIC_ENABLE_OFFSET _AC(0x2000,UL)
#define PLIC_ENABLE_SHIFT_PER_TARGET 7
#define PLIC_THRESHOLD_OFFSET _AC(0x200000,UL)
#define PLIC_CLAIM_OFFSET _AC(0x200004,UL)
#define PLIC_THRESHOLD_SHIFT_PER_TARGET 12
#define PLIC_CLAIM_SHIFT_PER_TARGET 12
#define PLIC_MAX_SOURCE 1023
#define PLIC_SOURCE_MASK 0x3FF
#define PLIC_MAX_TARGET 15871
#define PLIC_TARGET_MASK 0x3FFF
#endif /* PLIC_H */

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// See LICENSE for license details.
#ifndef _SIFIVE_PRCI_H
#define _SIFIVE_PRCI_H
/* Register offsets */
#define PRCI_HFROSCCFG (0x0000)
#define PRCI_HFXOSCCFG (0x0004)
#define PRCI_PLLCFG (0x0008)
#define PRCI_PLLDIV (0x000C)
#define PRCI_PROCMONCFG (0x00F0)
/* Fields */
#define ROSC_DIV(x) (((x) & 0x2F) << 0 )
#define ROSC_TRIM(x) (((x) & 0x1F) << 16)
#define ROSC_EN(x) (((x) & 0x1 ) << 30)
#define ROSC_RDY(x) (((x) & 0x1 ) << 31)
#define XOSC_EN(x) (((x) & 0x1) << 30)
#define XOSC_RDY(x) (((x) & 0x1) << 31)
#define PLL_R(x) (((x) & 0x7) << 0)
// single reserved bit for F LSB.
#define PLL_F(x) (((x) & 0x3F) << 4)
#define PLL_Q(x) (((x) & 0x3) << 10)
#define PLL_SEL(x) (((x) & 0x1) << 16)
#define PLL_REFSEL(x) (((x) & 0x1) << 17)
#define PLL_BYPASS(x) (((x) & 0x1) << 18)
#define PLL_LOCK(x) (((x) & 0x1) << 31)
#define PLL_R_default 0x1
#define PLL_F_default 0x1F
#define PLL_Q_default 0x3
#define PLL_REFSEL_HFROSC 0x0
#define PLL_REFSEL_HFXOSC 0x1
#define PLL_SEL_HFROSC 0x0
#define PLL_SEL_PLL 0x1
#define PLL_FINAL_DIV(x) (((x) & 0x3F) << 0)
#define PLL_FINAL_DIV_BY_1(x) (((x) & 0x1 ) << 8)
#define PROCMON_DIV(x) (((x) & 0x1F) << 0)
#define PROCMON_TRIM(x) (((x) & 0x1F) << 8)
#define PROCMON_EN(x) (((x) & 0x1) << 16)
#define PROCMON_SEL(x) (((x) & 0x3) << 24)
#define PROCMON_NT_EN(x) (((x) & 0x1) << 28)
#define PROCMON_SEL_HFCLK 0
#define PROCMON_SEL_HFXOSCIN 1
#define PROCMON_SEL_PLLOUTDIV 2
#define PROCMON_SEL_PROCMON 3
#endif // _SIFIVE_PRCI_H

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// See LICENSE for license details.
#ifndef _SIFIVE_PWM_H
#define _SIFIVE_PWM_H
/* Register offsets */
#define PWM_CFG 0x00
#define PWM_COUNT 0x08
#define PWM_S 0x10
#define PWM_CMP0 0x20
#define PWM_CMP1 0x24
#define PWM_CMP2 0x28
#define PWM_CMP3 0x2C
/* Constants */
#define PWM_CFG_SCALE 0x0000000F
#define PWM_CFG_STICKY 0x00000100
#define PWM_CFG_ZEROCMP 0x00000200
#define PWM_CFG_DEGLITCH 0x00000400
#define PWM_CFG_ENALWAYS 0x00001000
#define PWM_CFG_ONESHOT 0x00002000
#define PWM_CFG_CMP0CENTER 0x00010000
#define PWM_CFG_CMP1CENTER 0x00020000
#define PWM_CFG_CMP2CENTER 0x00040000
#define PWM_CFG_CMP3CENTER 0x00080000
#define PWM_CFG_CMP0GANG 0x01000000
#define PWM_CFG_CMP1GANG 0x02000000
#define PWM_CFG_CMP2GANG 0x04000000
#define PWM_CFG_CMP3GANG 0x08000000
#define PWM_CFG_CMP0IP 0x10000000
#define PWM_CFG_CMP1IP 0x20000000
#define PWM_CFG_CMP2IP 0x40000000
#define PWM_CFG_CMP3IP 0x80000000
#endif /* _SIFIVE_PWM_H */

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// See LICENSE for license details.
#ifndef _SIFIVE_SPI_H
#define _SIFIVE_SPI_H
/* Register offsets */
#define SPI_REG_SCKDIV 0x00
#define SPI_REG_SCKMODE 0x04
#define SPI_REG_CSID 0x10
#define SPI_REG_CSDEF 0x14
#define SPI_REG_CSMODE 0x18
#define SPI_REG_DCSSCK 0x28
#define SPI_REG_DSCKCS 0x2a
#define SPI_REG_DINTERCS 0x2c
#define SPI_REG_DINTERXFR 0x2e
#define SPI_REG_FMT 0x40
#define SPI_REG_TXFIFO 0x48
#define SPI_REG_RXFIFO 0x4c
#define SPI_REG_TXCTRL 0x50
#define SPI_REG_RXCTRL 0x54
#define SPI_REG_FCTRL 0x60
#define SPI_REG_FFMT 0x64
#define SPI_REG_IE 0x70
#define SPI_REG_IP 0x74
/* Fields */
#define SPI_SCK_PHA 0x1
#define SPI_SCK_POL 0x2
#define SPI_FMT_PROTO(x) ((x) & 0x3)
#define SPI_FMT_ENDIAN(x) (((x) & 0x1) << 2)
#define SPI_FMT_DIR(x) (((x) & 0x1) << 3)
#define SPI_FMT_LEN(x) (((x) & 0xf) << 16)
/* TXCTRL register */
#define SPI_TXWM(x) ((x) & 0xffff)
/* RXCTRL register */
#define SPI_RXWM(x) ((x) & 0xffff)
#define SPI_IP_TXWM 0x1
#define SPI_IP_RXWM 0x2
#define SPI_FCTRL_EN 0x1
#define SPI_INSN_CMD_EN 0x1
#define SPI_INSN_ADDR_LEN(x) (((x) & 0x7) << 1)
#define SPI_INSN_PAD_CNT(x) (((x) & 0xf) << 4)
#define SPI_INSN_CMD_PROTO(x) (((x) & 0x3) << 8)
#define SPI_INSN_ADDR_PROTO(x) (((x) & 0x3) << 10)
#define SPI_INSN_DATA_PROTO(x) (((x) & 0x3) << 12)
#define SPI_INSN_CMD_CODE(x) (((x) & 0xff) << 16)
#define SPI_INSN_PAD_CODE(x) (((x) & 0xff) << 24)
#define SPI_TXFIFO_FULL (1 << 31)
#define SPI_RXFIFO_EMPTY (1 << 31)
/* Values */
#define SPI_CSMODE_AUTO 0
#define SPI_CSMODE_HOLD 2
#define SPI_CSMODE_OFF 3
#define SPI_DIR_RX 0
#define SPI_DIR_TX 1
#define SPI_PROTO_S 0
#define SPI_PROTO_D 1
#define SPI_PROTO_Q 2
#define SPI_ENDIAN_MSB 0
#define SPI_ENDIAN_LSB 1
#endif /* _SIFIVE_SPI_H */

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// See LICENSE for license details.
#ifndef _SIFIVE_UART_H
#define _SIFIVE_UART_H
/* Register offsets */
#define UART_REG_TXFIFO 0x00
#define UART_REG_RXFIFO 0x04
#define UART_REG_TXCTRL 0x08
#define UART_REG_RXCTRL 0x0c
#define UART_REG_IE 0x10
#define UART_REG_IP 0x14
#define UART_REG_DIV 0x18
/* TXCTRL register */
#define UART_TXEN 0x1
#define UART_TXWM(x) (((x) & 0xffff) << 16)
/* RXCTRL register */
#define UART_RXEN 0x1
#define UART_RXWM(x) (((x) & 0xffff) << 16)
/* IP register */
#define UART_IP_TXWM 0x1
#define UART_IP_RXWM 0x2
#endif /* _SIFIVE_UART_H */

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// See LICENSE for license details.
#ifndef _SECTIONS_H
#define _SECTIONS_H
extern unsigned char _rom[];
extern unsigned char _rom_end[];
extern unsigned char _ram[];
extern unsigned char _ram_end[];
extern unsigned char _ftext[];
extern unsigned char _etext[];
extern unsigned char _fbss[];
extern unsigned char _ebss[];
extern unsigned char _end[];
#endif /* _SECTIONS_H */

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#ifndef SIFIVE_SMP
#define SIFIVE_SMP
// The maximum number of HARTs this code supports
#ifndef MAX_HARTS
#define MAX_HARTS 32
#endif
#define CLINT_END_HART_IPI CLINT_CTRL_ADDR + (MAX_HARTS*4)
// The hart that non-SMP tests should run on
#ifndef NONSMP_HART
#define NONSMP_HART 0
#endif
/* If your test cannot handle multiple-threads, use this:
* smp_disable(reg1)
*/
#define smp_disable(reg1, reg2) \
csrr reg1, mhartid ;\
li reg2, NONSMP_HART ;\
beq reg1, reg2, hart0_entry ;\
42: ;\
wfi ;\
j 42b ;\
hart0_entry:
/* If your test needs to temporarily block multiple-threads, do this:
* smp_pause(reg1, reg2)
* ... single-threaded work ...
* smp_resume(reg1, reg2)
* ... multi-threaded work ...
*/
#define smp_pause(reg1, reg2) \
li reg2, 0x8 ;\
csrw mie, reg2 ;\
csrr reg2, mhartid ;\
bnez reg2, 42f
#define smp_resume(reg1, reg2) \
li reg1, CLINT_CTRL_ADDR ;\
41: ;\
li reg2, 1 ;\
sw reg2, 0(reg1) ;\
addi reg1, reg1, 4 ;\
li reg2, CLINT_END_HART_IPI ;\
blt reg1, reg2, 41b ;\
42: ;\
wfi ;\
csrr reg2, mip ;\
andi reg2, reg2, 0x8 ;\
beqz reg2, 42b ;\
li reg1, CLINT_CTRL_ADDR ;\
csrr reg2, mhartid ;\
slli reg2, reg2, 2 ;\
add reg2, reg2, reg1 ;\
sw zero, 0(reg2) ;\
41: ;\
lw reg2, 0(reg1) ;\
bnez reg2, 41b ;\
addi reg1, reg1, 4 ;\
li reg2, CLINT_END_HART_IPI ;\
blt reg1, reg2, 41b
#endif

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# See LICENSE for license details.
ifndef _SIFIVE_MK_LIBWRAP
_SIFIVE_MK_LIBWRAP := # defined
LIBWRAP_DIR := $(dir $(lastword $(MAKEFILE_LIST)))
LIBWRAP_DIR := $(LIBWRAP_DIR:/=)
LIBWRAP_SRCS := \
stdlib/malloc.c \
sys/open.c \
sys/lseek.c \
sys/read.c \
sys/write.c \
sys/fstat.c \
sys/stat.c \
sys/close.c \
sys/link.c \
sys/unlink.c \
sys/execve.c \
sys/fork.c \
sys/getpid.c \
sys/kill.c \
sys/wait.c \
sys/isatty.c \
sys/times.c \
sys/sbrk.c \
sys/_exit.c \
sys/puts.c \
misc/write_hex.c
LIBWRAP_SRCS := $(foreach f,$(LIBWRAP_SRCS),$(LIBWRAP_DIR)/$(f))
LIBWRAP_OBJS := $(LIBWRAP_SRCS:.c=.o)
LIBWRAP_SYMS := malloc free \
open lseek read write fstat stat close link unlink \
execve fork getpid kill wait \
isatty times sbrk _exit puts
LIBWRAP := libwrap.a
LINK_DEPS += $(LIBWRAP)
LDFLAGS += $(foreach s,$(LIBWRAP_SYMS),-Wl,--wrap=$(s))
LDFLAGS += $(foreach s,$(LIBWRAP_SYMS),-Wl,--wrap=_$(s))
LDFLAGS += -L. -Wl,--start-group -lwrap -lc -Wl,--end-group
CLEAN_OBJS += $(LIBWRAP_OBJS)
$(LIBWRAP_OBJS): %.o: %.c $(HEADERS)
$(CC) $(CFLAGS) $(INCLUDES) -c -o $@ $<
$(LIBWRAP): $(LIBWRAP_OBJS)
$(AR) rcs $@ $^
endif # _SIFIVE_MK_LIBWRAP

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/* See LICENSE of license details. */
#include <stdint.h>
#include <unistd.h>
#include "platform.h"
void write_hex(int fd, unsigned long int hex)
{
uint8_t ii;
uint8_t jj;
char towrite;
write(fd , "0x", 2);
for (ii = sizeof(unsigned long int) * 2 ; ii > 0; ii--) {
jj = ii - 1;
uint8_t digit = ((hex & (0xF << (jj*4))) >> (jj*4));
towrite = digit < 0xA ? ('0' + digit) : ('A' + (digit - 0xA));
write(fd, &towrite, 1);
}
}

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/* See LICENSE for license details. */
/* These functions are intended for embedded RV32 systems and are
obviously incorrect in general. */
void* __wrap_malloc(unsigned long sz)
{
extern void* sbrk(long);
void* res = sbrk(sz);
if ((long)res == -1)
return 0;
return res;
}
void __wrap_free(void* ptr)
{
}

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/* See LICENSE of license details. */
#include <unistd.h>
#include "platform.h"
#include "weak_under_alias.h"
void __wrap_exit(int code)
{
const char message[] = "\nProgam has exited with code:";
write(STDERR_FILENO, message, sizeof(message) - 1);
write_hex(STDERR_FILENO, code);
write(STDERR_FILENO, "\n", 1);
for (;;);
}
weak_under_alias(exit);

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@ -0,0 +1,11 @@
/* See LICENSE of license details. */
#include <errno.h>
#include "stub.h"
#include "weak_under_alias.h"
int __wrap_close(int fd)
{
return _stub(EBADF);
}
weak_under_alias(close);

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@ -0,0 +1,11 @@
/* See LICENSE of license details. */
#include <errno.h>
#include "stub.h"
#include "weak_under_alias.h"
int __wrap_execve(const char* name, char* const argv[], char* const env[])
{
return _stub(ENOMEM);
}
weak_under_alias(execve);

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@ -0,0 +1,9 @@
/* See LICENSE of license details. */
#include <errno.h>
#include "stub.h"
int fork(void)
{
return _stub(EAGAIN);
}

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@ -0,0 +1,18 @@
/* See LICENSE of license details. */
#include <errno.h>
#include <unistd.h>
#include <sys/stat.h>
#include "stub.h"
#include "weak_under_alias.h"
int __wrap_fstat(int fd, struct stat* st)
{
if (isatty(fd)) {
st->st_mode = S_IFCHR;
return 0;
}
return _stub(EBADF);
}
weak_under_alias(fstat);

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@ -0,0 +1,8 @@
/* See LICENSE of license details. */
#include "weak_under_alias.h"
int __wrap_getpid(void)
{
return 1;
}
weak_under_alias(getpid);

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@ -0,0 +1,13 @@
/* See LICENSE of license details. */
#include <unistd.h>
#include "weak_under_alias.h"
int __wrap_isatty(int fd)
{
if (fd == STDOUT_FILENO || fd == STDERR_FILENO)
return 1;
return 0;
}
weak_under_alias(isatty);

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@ -0,0 +1,11 @@
/* See LICENSE of license details. */
#include <errno.h>
#include "stub.h"
#include "weak_under_alias.h"
int __wrap_kill(int pid, int sig)
{
return _stub(EINVAL);
}
weak_under_alias(kill);

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@ -0,0 +1,11 @@
/* See LICENSE of license details. */
#include <errno.h>
#include "stub.h"
#include "weak_under_alias.h"
int __wrap_link(const char *old_name, const char *new_name)
{
return _stub(EMLINK);
}
weak_under_alias(link);

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@ -0,0 +1,16 @@
/* See LICENSE of license details. */
#include <errno.h>
#include <unistd.h>
#include <sys/types.h>
#include "stub.h"
#include "weak_under_alias.h"
off_t __wrap_lseek(int fd, off_t ptr, int dir)
{
if (isatty(fd))
return 0;
return _stub(EBADF);
}
weak_under_alias(lseek);

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@ -0,0 +1,11 @@
/* See LICENSE of license details. */
#include <errno.h>
#include "stub.h"
#include "weak_under_alias.h"
int __wrap_open(const char* name, int flags, int mode)
{
return _stub(ENOENT);
}
weak_under_alias(open);

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@ -0,0 +1,11 @@
/* See LICENSE of license details. */
#include <errno.h>
#include "stub.h"
#include "weak_under_alias.h"
int __wrap_openat(int dirfd, const char* name, int flags, int mode)
{
return _stub(ENOENT);
}
weak_under_alias(openat);

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@ -0,0 +1,28 @@
/* See LICENSE of license details. */
#include <stdint.h>
#include <errno.h>
#include <unistd.h>
#include <sys/types.h>
#include "platform.h"
#include "stub.h"
#include "weak_under_alias.h"
int __wrap_puts(const char *s)
{
while (*s != '\0') {
while (UART0_REG(UART_REG_TXFIFO) & 0x80000000) ;
UART0_REG(UART_REG_TXFIFO) = *s;
if (*s == '\n') {
while (UART0_REG(UART_REG_TXFIFO) & 0x80000000) ;
UART0_REG(UART_REG_TXFIFO) = '\r';
}
++s;
}
return 0;
}
weak_under_alias(puts);

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@ -0,0 +1,32 @@
/* See LICENSE of license details. */
#include <stdint.h>
#include <errno.h>
#include <unistd.h>
#include <sys/types.h>
#include "platform.h"
#include "stub.h"
#include "weak_under_alias.h"
ssize_t __wrap_read(int fd, void* ptr, size_t len)
{
uint8_t * current = (uint8_t *)ptr;
volatile uint32_t * uart_rx = (uint32_t *)(UART0_CTRL_ADDR + UART_REG_RXFIFO);
volatile uint8_t * uart_rx_cnt = (uint8_t *)(UART0_CTRL_ADDR + UART_REG_RXCTRL + 2);
ssize_t result = 0;
if (isatty(fd)) {
for (current = (uint8_t *)ptr;
(current < ((uint8_t *)ptr) + len) && (*uart_rx_cnt > 0);
current ++) {
*current = *uart_rx;
result++;
}
return result;
}
return _stub(EBADF);
}
weak_under_alias(read);

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@ -0,0 +1,18 @@
/* See LICENSE of license details. */
#include <stddef.h>
#include "weak_under_alias.h"
void *__wrap_sbrk(ptrdiff_t incr)
{
extern char _end[];
extern char _heap_end[];
static char *curbrk = _end;
if ((curbrk + incr < _end) || (curbrk + incr > _heap_end))
return NULL - 1;
curbrk += incr;
return curbrk - incr;
}
weak_under_alias(sbrk);

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@ -0,0 +1,12 @@
/* See LICENSE of license details. */
#include <errno.h>
#include <sys/stat.h>
#include "stub.h"
#include "weak_under_alias.h"
int __wrap_stat(const char* file, struct stat* st)
{
return _stub(EACCES);
}
weak_under_alias(stat);

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@ -0,0 +1,10 @@
/* See LICENSE of license details. */
#ifndef _SIFIVE_SYS_STUB_H
#define _SIFIVE_SYS_STUB_H
static inline int _stub(int err)
{
return -1;
}
#endif /* _SIFIVE_SYS_STUB_H */

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@ -0,0 +1,12 @@
/* See LICENSE of license details. */
#include <errno.h>
#include <sys/times.h>
#include "stub.h"
#include "weak_under_alias.h"
clock_t __wrap_times(struct tms* buf)
{
return _stub(EACCES);
}
weak_under_alias(times);

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@ -0,0 +1,11 @@
/* See LICENSE of license details. */
#include <errno.h>
#include "stub.h"
#include "weak_under_alias.h"
int __wrap_unlink(const char* name)
{
return _stub(ENOENT);
}
weak_under_alias(unlink);

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@ -0,0 +1,9 @@
/* See LICENSE of license details. */
#include <errno.h>
#include "stub.h"
int wait(int* status)
{
return _stub(ECHILD);
}

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@ -0,0 +1,7 @@
#ifndef _BSP_LIBWRAP_WEAK_UNDER_ALIAS_H
#define _BSP_LIBWRAP_WEAK_UNDER_ALIAS_H
#define weak_under_alias(name) \
extern __typeof (__wrap_##name) __wrap__##name __attribute__ ((weak, alias ("__wrap_"#name)))
#endif

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@ -0,0 +1,31 @@
/* See LICENSE of license details. */
#include <stdint.h>
#include <errno.h>
#include <unistd.h>
#include <sys/types.h>
#include "platform.h"
#include "stub.h"
#include "weak_under_alias.h"
ssize_t __wrap_write(int fd, const void* ptr, size_t len)
{
const uint8_t * current = (const char *)ptr;
if (isatty(fd)) {
for (size_t jj = 0; jj < len; jj++) {
while (UART0_REG(UART_REG_TXFIFO) & 0x80000000) ;
UART0_REG(UART_REG_TXFIFO) = current[jj];
if (current[jj] == '\n') {
while (UART0_REG(UART_REG_TXFIFO) & 0x80000000) ;
UART0_REG(UART_REG_TXFIFO) = '\r';
}
}
return len;
}
return _stub(EBADF);
}
weak_under_alias(write);

BIN
fpga_spn/raven_spn Executable file

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22
fpga_spn/src/bsp.h Normal file
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/*
* bsp.h
*
* Created on: 30.07.2018
* Author: eyck
*/
#ifndef BSP_H_
#define BSP_H_
#ifdef __cplusplus
extern "C" {
#endif
#include <fe300prci/fe300prci_driver.h>
#include <platform.h>
#include <encoding.h>
extern void trap_entry();
#ifdef __cplusplus
}
#endif
#endif /* BSP_H_ */

123
fpga_spn/src/delay.c Normal file
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/*
* delay.c
*
* Created on: 30.07.2018
* Author: eyck
*/
#include "delay.h"
#define rdmcycle(x) { \
uint32_t lo, hi, hi2; \
__asm__ __volatile__ ("1:\n\t" \
"csrr %0, mcycleh\n\t" \
"csrr %1, mcycle\n\t" \
"csrr %2, mcycleh\n\t" \
"bne %0, %2, 1b\n\t" \
: "=r" (hi), "=r" (lo), "=r" (hi2)) ; \
*(x) = lo | ((uint64_t) hi << 32); \
}
typedef struct {
uint32_t n;
uint32_t mult;
uint32_t shift;
} int_inverse ;
int_inverse f_cpu_1000_inv;
int_inverse f_cpu_1000000_inv;
uint32_t F_CPU=1000000;
void calc_inv(uint32_t n, int_inverse * res){
uint32_t one = ~0;
uint32_t d = one/n;
uint32_t r = one%n + 1;
if (r >= n) ++d;
if (d == 0) --d;
uint32_t shift = 0;
while ((d & 0x80000000) == 0){
d <<= 1;
++shift;
}
res->n = n;
res->mult = d;
res->shift = shift;
}
uint32_t divide32_using_inverse(uint32_t n, int_inverse *inv){
uint32_t d = (uint32_t)(((uint64_t)n * inv->mult) >> 32);
d >>= inv->shift;
if (n - d*inv->n >= inv->n) ++d;
return d;
}
// Almost full-range 64/32 divide.
// If divisor-1 has i bits, then the answer is exact for n of up to 64-i bits
// e.g. for divisors up to a million, n can have up to 45 bits
// On RV32IM with divide32_using_inverse inlines this uses 5 multiplies,
// 33 instructions, zero branches, 3 loads, 0 stores.
uint64_t divide64_using_inverse(uint64_t n, int_inverse *inv){
uint32_t preshift = (31 - inv->shift) & 31;
uint64_t d = (uint64_t)divide32_using_inverse(n >> preshift, inv) << preshift;
uint32_t r = n - d * inv->n;
d += divide32_using_inverse(r, inv);
return d;
}
uint32_t millis(){
uint64_t x;
rdmcycle(&x);
x = divide64_using_inverse(x, &f_cpu_1000_inv);
return((uint32_t) (x & 0xFFFFFFFF));
}
uint32_t micros(void){
uint64_t x;
rdmcycle(&x);
// For Power-of-two MHz F_CPU,
// this compiles into a simple shift,
// and is faster than the general solution.
#if F_CPU==16000000
x = x / (F_CPU / 1000000);
#else
#if F_CPU==256000000
x = x / (F_CPU / 1000000);
#else
x = divide64_using_inverse(x, &f_cpu_1000000_inv);
#endif
#endif
return((uint32_t) (x & 0xFFFFFFFF));
}
void delayMS(uint32_t dwMs){
uint64_t current, later;
rdmcycle(&current);
later = current + dwMs * (F_CPU/1000);
if (later > current){ // usual case
while (later > current)
rdmcycle(&current);
} else { // wrap. Though this is unlikely to be hit w/ 64-bit mcycle
while (later < current)
rdmcycle(&current);
while (current < later)
rdmcycle(&current);
}
}
void delayUS(uint32_t dwUs){
uint64_t current, later;
rdmcycle(&current);
later = current + dwUs * (F_CPU/1000000);
if (later > current){ // usual case
while (later > current)
rdmcycle(&current);
} else {// wrap. Though this is unlikely to be hit w/ 64-bit mcycle
while (later < current)
rdmcycle(&current);
while (current < later)
rdmcycle(&current);
}
}

25
fpga_spn/src/delay.h Normal file
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/*
* delay.h
*
* Created on: 30.07.2018
* Author: eyck
*/
#ifndef DELAY_H_
#define DELAY_H_
#include <stdint.h>
#ifdef __cplusplus
extern "C" {
#endif
extern uint32_t F_CPU;
void delayMS(uint32_t dwMs);
void delayUS(uint32_t dwUs);
#ifdef __cplusplus
}
#endif
#endif /* DELAY_H_ */

56
fpga_spn/src/dma_regs.h Normal file
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#ifndef _DMA_REGS_H_
#define _DMA_REGS_H_
#include <util/bit_field.h>
#include <cstdint>
#define DMA_REG_START 0x00
#define DMA_REG_CLEAR_INTERRUPT 0x0C
#define DMA_REG_FPGA_ADDRESS 0x10
#define DMA_REG_SC_ADDRESS 0x20
#define DMA_REG_WRITE 0x30
#define DMA_REG_BYTES 0x40
template<uint32_t BASE_ADDR>
class dma_regs {
public:
// storage declarations
// BEGIN_BF_DECL(start_t, uint32_t);
// BF_FIELD(start, 0, 1);
// END_BF_DECL() r_start;
uint32_t r_start;
uint32_t r_address;
uint32_t r_write;
uint32_t r_bytes;
static inline uint32_t& start_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+DMA_REG_START);
}
static inline uint32_t& clear_interrupt_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+DMA_REG_CLEAR_INTERRUPT);
}
static inline uint32_t & fpga_address_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+DMA_REG_FPGA_ADDRESS);
}
static inline uint32_t & sc_address_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+DMA_REG_SC_ADDRESS);
}
static inline uint32_t & write_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+DMA_REG_WRITE);
}
static inline uint32_t & bytes_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+DMA_REG_BYTES);
}
};
#endif // _SPN_REGS_H_

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fpga_spn/src/init.h Normal file
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#ifndef SRC_INIT_H_
#define SRC_INIT_H_
#include <cstdio>
#include <array>
#include "delay.h"
#include "bsp.h"
#include "plic/plic_driver.h"
typedef void (*function_ptr_t) (void);
//! Instance data for the PLIC.
plic_instance_t g_plic;
std::array<function_ptr_t,PLIC_NUM_INTERRUPTS> g_ext_interrupt_handlers;
bool hw_interrupt{true};
/*! \brief external interrupt handler
*
* routes the peripheral interrupts to the the respective handler
*
*/
extern "C" void handle_m_ext_interrupt() {
plic_source int_num = PLIC_claim_interrupt(&g_plic);
if ((int_num >=1 ) && (int_num < PLIC_NUM_INTERRUPTS))
g_ext_interrupt_handlers[int_num]();
else
exit(1 + (uintptr_t) int_num);
PLIC_complete_interrupt(&g_plic, int_num);
}
/*! \brief dummy interrupt handler
*
*/
void no_interrupt_handler (void) {};
/*! \brief configure the per-interrupt handler
*
*/
void configure_irq(size_t irq_num, function_ptr_t handler, unsigned char prio=1) {
g_ext_interrupt_handlers[irq_num] = handler;
// Priority must be set > 0 to trigger the interrupt.
PLIC_set_priority(&g_plic, irq_num, prio);
// Have to enable the interrupt both at the GPIO level, and at the PLIC level.
PLIC_enable_interrupt(&g_plic, irq_num);
}
static void msi_interrupt_handler(){
hw_interrupt = false;
}
void wait_for_interrupt() {
// wait until HW is done
if(hw_interrupt) {
do{
asm("wfi");
asm("nop");
}while(hw_interrupt);
}
hw_interrupt=true;
}
/*!\brief initializes platform
*
*/
void platform_init(){
// UART init section TODO: clarify how to get the functions from init.c?
GPIO_REG(GPIO_IOF_SEL) &= ~IOF0_UART0_MASK;
GPIO_REG(GPIO_IOF_EN) |= IOF0_UART0_MASK;
UART0_REG(UART_REG_TXCTRL) |= UART_TXEN;
F_CPU=PRCI_measure_mcycle_freq(20, RTC_FREQ);
printf("core freq at %d Hz\n", F_CPU);
// initialie interupt & trap handling
write_csr(mtvec, &trap_entry);
PLIC_init(&g_plic, PLIC_CTRL_ADDR, PLIC_NUM_INTERRUPTS, PLIC_NUM_PRIORITIES, 0);
// Disable the machine & timer interrupts until setup is done.
clear_csr(mie, MIP_MEIP);
clear_csr(mie, MIP_MTIP);
for (auto& h:g_ext_interrupt_handlers) h=no_interrupt_handler;
configure_irq(2, msi_interrupt_handler);
// Enable interrupts in general.
set_csr(mstatus, MSTATUS_MIE);
// Enable the Machine-External bit in MIE
set_csr(mie, MIP_MEIP);
//hw_interrupt = false;
}
#endif /* SRC_INIT_H_ */

89
fpga_spn/src/io/gpio.h Normal file
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/*
* gpio.h
*
* Created on: 29.07.2018
* Author: eyck
*/
#ifndef GPIO_H_
#define GPIO_H_
#include <sifive/devices/gpio.h>
#include <cstdint>
template<uint32_t BASE_ADDR>
class gpio_regs {
public:
static inline uint32_t& value_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_INPUT_VAL);
}
static inline uint32_t& input_en_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_INPUT_EN);
}
static inline uint32_t& output_en_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_OUTPUT_EN);
}
static inline uint32_t& port_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_OUTPUT_VAL);
}
static inline uint32_t& pue_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_PULLUP_EN);
}
static inline uint32_t& ds_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_DRIVE);
}
static inline uint32_t& rise_ie_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_RISE_IE);
}
static inline uint32_t& rise_ip_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_RISE_IP);
}
static inline uint32_t& fall_ie_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_FALL_IE);
}
static inline uint32_t& fall_ip_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_FALL_IP);
}
static inline uint32_t& high_ie_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_HIGH_IE);
}
static inline uint32_t& high_ip_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_HIGH_IP);
}
static inline uint32_t& low_ie_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_LOW_IE);
}
static inline uint32_t& low_ip_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_LOW_IP);
}
static inline uint32_t& iof_en_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_IOF_EN);
}
static inline uint32_t& iof_sel_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_IOF_SEL);
}
static inline uint32_t& out_xor_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+GPIO_OUTPUT_XOR);
}
};
#endif /* GPIO_H_ */

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/*
* pwm.h
*
* Created on: 29.07.2018
* Author: eyck
*/
#ifndef PWM_H_
#define PWM_H_
#include <sifive/devices/pwm.h>
#include "util/bit_field.h"
#include <limits>
#include <cstdint>
template<uint32_t BASE_ADDR>
class pwm_regs {
public:
BEGIN_BF_DECL(pwmcfg_t, uint32_t);
BF_FIELD(scale, 0, 4);
BF_FIELD(sticky, 8, 1);
BF_FIELD(zerocmp, 9, 1);
BF_FIELD(deglitch, 10, 1);
BF_FIELD(enalways, 12, 1);
BF_FIELD(enoneshot, 13, 1);
BF_FIELD(cmp0center, 16, 1);
BF_FIELD(cmp1center, 17, 1);
BF_FIELD(cmp2center, 18, 1);
BF_FIELD(cmp3center, 19, 1);
BF_FIELD(cmp0gang, 24, 1);
BF_FIELD(cmp1gang, 25, 1);
BF_FIELD(cmp2gang, 26, 1);
BF_FIELD(cmp3gang, 27, 1);
BF_FIELD(cmp0ip, 28, 1);
BF_FIELD(cmp1ip, 29, 1);
BF_FIELD(cmp2ip, 30, 1);
BF_FIELD(cmp3ip, 31, 1);
END_BF_DECL();
BEGIN_BF_DECL(pwms_t, uint32_t);
BF_FIELD(s, 0, 16);
END_BF_DECL() r_pwms;
BEGIN_BF_DECL(pwmcmp0_t, uint32_t);
BF_FIELD(cmp0, 0, 16);
END_BF_DECL() r_pwmcmp0;
BEGIN_BF_DECL(pwmcmp1_t, uint32_t);
BF_FIELD(cmp0, 0, 16);
END_BF_DECL() r_pwmcmp1;
BEGIN_BF_DECL(pwmcmp2_t, uint32_t);
BF_FIELD(cmp0, 0, 16);
END_BF_DECL() r_pwmcmp2;
BEGIN_BF_DECL(pwmcmp3_t, uint32_t);
BF_FIELD(cmp0, 0, 16);
END_BF_DECL() r_pwmcmp3;
static inline pwmcfg_t& cfg_reg(){
return *reinterpret_cast<pwmcfg_t*>(BASE_ADDR+PWM_CFG);
}
static inline uint32_t& count_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+PWM_COUNT);
}
static inline pwms_t& s_reg(){
return *reinterpret_cast<pwms_t*>(BASE_ADDR+PWM_S);
}
static inline pwmcmp0_t& cmp0_reg(){
return *reinterpret_cast<pwmcmp0_t*>(BASE_ADDR+PWM_CMP0);
}
static inline pwmcmp1_t& cmp1_reg(){
return *reinterpret_cast<pwmcmp1_t*>(BASE_ADDR+PWM_CMP1);
}
static inline pwmcmp2_t& cmp2_reg(){
return *reinterpret_cast<pwmcmp2_t*>(BASE_ADDR+PWM_CMP2);
}
static inline pwmcmp3_t& cmp3_reg(){
return *reinterpret_cast<pwmcmp3_t*>(BASE_ADDR+PWM_CMP3);
}
static inline bool oneshot_delay(long delay_us){
auto scaling_factor=0;
while(delay_us/(1<<scaling_factor) > std::numeric_limits<unsigned short>::max()){
scaling_factor++;
}
cfg_reg()=0;
count_reg()=0;
cfg_reg().scale=4+scaling_factor; // divide by 16 so we get 1us per pwm clock
cmp0_reg().cmp0 = delay_us/(1<<scaling_factor);
pwm_active=true;
cfg_reg().enoneshot=true;
do{
asm("wfi");
asm("nop");
}while(pwm_active);
return true;
}
static void pwm_interrupt_handler(){
cfg_reg().cmp0ip=false;
pwm_active=false;
}
inline
static bool is_active(){ return pwm_active; }
inline
static void set_active() {pwm_active=true;}
private:
static volatile bool pwm_active;
};
#endif /* PWM_H_ */

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/*
* spi.h
*
* Created on: 29.07.2018
* Author: eyck
*/
#ifndef SPI_H_
#define SPI_H_
#include <sifive/devices/spi.h>
#include "util/bit_field.h"
#include <array>
#include <cstdint>
template<uint32_t BASE_ADDR>
class spi_regs {
public:
// storage declarations
BEGIN_BF_DECL(sckdiv_t, uint32_t);
BF_FIELD(div, 0, 12);
END_BF_DECL();
BEGIN_BF_DECL(sckmode_t, uint32_t);
BF_FIELD(pha, 0, 1);
BF_FIELD(pol, 1, 1);
END_BF_DECL();
uint32_t r_csid;
uint32_t r_csdef;
BEGIN_BF_DECL(csmode_t, uint32_t);
BF_FIELD(mode, 0, 2);
END_BF_DECL();
BEGIN_BF_DECL(delay0_t, uint32_t);
BF_FIELD(cssck, 0, 8);
BF_FIELD(sckcs, 16, 8);
END_BF_DECL();
BEGIN_BF_DECL(delay1_t, uint32_t);
BF_FIELD(intercs, 0, 16);
BF_FIELD(interxfr, 16, 8);
END_BF_DECL();
BEGIN_BF_DECL(fmt_t, uint32_t);
BF_FIELD(proto, 0, 2);
BF_FIELD(endian, 2, 1);
BF_FIELD(dir, 3, 1);
BF_FIELD(len, 16, 4);
END_BF_DECL();
BEGIN_BF_DECL(txdata_t, uint32_t);
BF_FIELD(data, 0, 8);
BF_FIELD(full, 31, 1);
END_BF_DECL() r_txdata;
BEGIN_BF_DECL(rxdata_t, uint32_t);
BF_FIELD(data, 0, 8);
BF_FIELD(empty, 31, 1);
END_BF_DECL();
BEGIN_BF_DECL(txmark_t, uint32_t);
BF_FIELD(txmark, 0, 3);
END_BF_DECL();
BEGIN_BF_DECL(rxmark_t, uint32_t);
BF_FIELD(rxmark, 0, 3);
END_BF_DECL();
BEGIN_BF_DECL(fctrl_t, uint32_t);
BF_FIELD(en, 0, 1);
END_BF_DECL();
BEGIN_BF_DECL(ffmt_t, uint32_t);
BF_FIELD(cmd_en, 0, 1);
BF_FIELD(addr_len, 1, 2);
BF_FIELD(pad_cnt, 3, 4);
BF_FIELD(cmd_proto, 7, 2);
BF_FIELD(addr_proto, 9, 2);
BF_FIELD(data_proto, 11, 2);
BF_FIELD(cmd_code, 16, 8);
BF_FIELD(pad_code, 24, 8);
END_BF_DECL();
BEGIN_BF_DECL(ie_t, uint32_t);
BF_FIELD(txwm, 0, 1);
BF_FIELD(rxwm, 1, 1);
END_BF_DECL();
BEGIN_BF_DECL(ip_t, uint32_t);
BF_FIELD(txwm, 0, 1);
BF_FIELD(rxwm, 1, 1);
END_BF_DECL();
static inline sckdiv_t& sckdiv_reg(){
return *reinterpret_cast<sckdiv_t*>(BASE_ADDR+SPI_REG_SCKDIV);
}
static inline sckmode_t& sckmode_reg(){
return *reinterpret_cast<sckmode_t*>(BASE_ADDR+SPI_REG_SCKMODE);
}
static inline uint32_t& csid_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPI_REG_CSID);
}
static inline uint32_t& csdef_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPI_REG_CSDEF);
}
static inline csmode_t& csmode_reg(){
return *reinterpret_cast<csmode_t*>(BASE_ADDR+SPI_REG_CSMODE);
}
static inline delay0_t& dcssck_reg(){
return *reinterpret_cast<delay0_t*>(BASE_ADDR+SPI_REG_DCSSCK);
}
static inline uint32_t& dsckcs_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPI_REG_DSCKCS);
}
static inline delay1_t& dintercs_reg(){
return *reinterpret_cast<delay1_t*>(BASE_ADDR+SPI_REG_DINTERCS);
}
static inline uint32_t& dinterxfr_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPI_REG_DINTERXFR);
}
static inline fmt_t& fmt_reg(){
return *reinterpret_cast<fmt_t*>(BASE_ADDR+SPI_REG_FMT);
}
static inline txdata_t& txfifo_reg(){
return *reinterpret_cast<txdata_t*>(BASE_ADDR+SPI_REG_TXFIFO);
}
static inline rxdata_t& rxfifo_reg(){
return *reinterpret_cast<rxdata_t*>(BASE_ADDR+SPI_REG_RXFIFO);
}
static inline txmark_t& txctrl_reg(){
return *reinterpret_cast<txmark_t*>(BASE_ADDR+SPI_REG_TXCTRL);
}
static inline rxmark_t& rxctrl_reg(){
return *reinterpret_cast<rxmark_t*>(BASE_ADDR+SPI_REG_RXCTRL);
}
static inline fctrl_t& fctrl_reg(){
return *reinterpret_cast<fctrl_t*>(BASE_ADDR+SPI_REG_FCTRL);
}
static inline ffmt_t& ffmt_reg(){
return *reinterpret_cast<ffmt_t*>(BASE_ADDR+SPI_REG_FFMT);
}
static inline ie_t& ie_reg(){
return *reinterpret_cast<ie_t*>(BASE_ADDR+SPI_REG_IE);
}
static inline ip_t& ip_reg(){
return *reinterpret_cast<ip_t*>(BASE_ADDR+SPI_REG_IP);
}
template<size_t SIZE>
static bool transfer(std::array<uint8_t, SIZE>& bytes){
csmode_reg().mode=2; // HOLD mode
rxctrl_reg().rxmark=bytes.size()-1; // trigger irq if more than 2 bytes are received;
ie_reg().rxwm=1;
// write data bytes
for(size_t i=0; i<bytes.size(); ++i)
txfifo_reg()=bytes[i];
// wait until SPI is done
spi_active=true;
do{
asm("wfi");
asm("nop");
}while(spi_active);
// deactivate SPI
csmode_reg().mode=0; // AUTO mode, deactivates CS
// fetch results
for(size_t i=0; i<bytes.size(); ++i) bytes[i]=rxfifo_reg();
return true;
}
static void spi_rx_interrupt_handler(){
ip_reg().rxwm=0;
ie_reg().rxwm=0;
spi_active=false;
}
private:
static volatile bool spi_active;
};
#endif /* SPI_H_ */

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/*
* spi.h
*
* Created on: 29.07.2018
* Author: eyck
*/
#ifndef UART_H_
#define UART_H_
#include <sifive/devices/uart.h>
#include "util/bit_field.h"
#include <cstdint>
template<uint32_t BASE_ADDR>
class uart_regs {
public:
BEGIN_BF_DECL(txdata_t, uint32_t);
BF_FIELD(data, 0, 8);
BF_FIELD(full, 31, 1);
END_BF_DECL() ;
BEGIN_BF_DECL(rxdata_t, uint32_t);
BF_FIELD(data, 0, 8);
BF_FIELD(empty, 31, 1);
END_BF_DECL();
BEGIN_BF_DECL(txctrl_t, uint32_t);
BF_FIELD(txen, 0, 1);
BF_FIELD(nstop, 1, 1);
BF_FIELD(txcnt, 16, 3);
END_BF_DECL();
BEGIN_BF_DECL(rxctrl_t, uint32_t);
BF_FIELD(rxen, 0, 1);
BF_FIELD(rxcnt, 16, 3);
END_BF_DECL();
BEGIN_BF_DECL(ie_t, uint32_t);
BF_FIELD(txwm, 0, 1);
BF_FIELD(rxwm, 1, 1);
END_BF_DECL();
BEGIN_BF_DECL(ip_t, uint32_t);
BF_FIELD(txwm, 0, 1);
BF_FIELD(rxwm, 1, 1);
END_BF_DECL();
BEGIN_BF_DECL(div_t, uint32_t);
BF_FIELD(div, 0, 16);
END_BF_DECL();
static inline txdata_t& txdata_reg(){
return *reinterpret_cast<txdata_t*>(BASE_ADDR+UART_REG_TXFIFO);
}
static inline rxdata_t& rxdata_reg(){
return *reinterpret_cast<rxdata_t*>(BASE_ADDR+UART_REG_RXFIFO);
}
static inline txctrl_t& txctrl_reg(){
return *reinterpret_cast<txctrl_t*>(BASE_ADDR+UART_REG_TXCTRL);
}
static inline rxctrl_t& rxctrl_reg(){
return *reinterpret_cast<rxctrl_t*>(BASE_ADDR+UART_REG_RXCTRL);
}
static inline ie_t& ie_reg(){
return *reinterpret_cast<ie_t*>(BASE_ADDR+UART_REG_IE);
}
static inline ip_t& ip_reg(){
return *reinterpret_cast<ip_t*>(BASE_ADDR+UART_REG_IP);
}
static inline div_t& div_reg(){
return *reinterpret_cast<div_t*>(BASE_ADDR+UART_REG_DIV);
}
};
#endif /* SPI_H_ */

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#include "raven_spn.h"
#include "spn_regs.h"
#include "dma_regs.h"
#include "init.h"
#include <math.h>
using spn = spn_regs<0x90000000>;
using dma = dma_regs<0xB0000000>;
// huge arrays of XSPN input and referance data
extern std::array<uint8_t, 50000> input_data;
extern std::array<double, 10000> ref_data;
bool double_equals(double a, double b, double epsilon = 0.001)
{
return std::abs(a - b) < epsilon;
}
void run_xspn(int in_addr, int out_addr, int num_samples, int in_beats, int out_beats) {
spn::mode_reg() = 0;
spn::input_length_reg() = num_samples; // each sample consists of 5 uint8 values
spn::input_addr_reg() = in_addr;
spn::output_addr_reg() = out_addr;
spn::num_of_in_beats_reg() = in_beats; // Number of AXI4 burst beats needed to load all input data
spn::num_of_out_beats_reg() = out_beats; // Number of AXI4 burst beats needed to store all result data
printf("Starting XSPN\n");
spn::start_reg() = 1;
}
void fpga_dma(int direction, int fpga_address, int sc_address, int num_bytes) {
dma::write_reg() = direction;
dma::fpga_address_reg() = fpga_address;
dma::sc_address_reg() = sc_address;
dma::bytes_reg() = num_bytes;
dma::start_reg() = 1;
wait_for_interrupt();
dma::clear_interrupt_reg() = 1;
}
void check_results(int addr, int k, int step) {
bool result = 0;
double *res_base = (double*) (addr);
int * error_exit = (int *)0xF0000000;
printf("Start result comparison %d - %d\n", k, k+step);
for (int i = 0; i < step; i++) {
//printf("%x%x vs %x%x\n", ((uint32_t*)res_base)[2*i], ((uint32_t*)res_base)[1+2*i], ((uint32_t*)ref_data.data())[2*i+k*20], ((uint32_t*)ref_data.data())[1+2*i+k*20]);
if (!double_equals(res_base[i], ref_data.at(k + i))) {
printf("XSPN ref %d comparison FAILED\n", k + i);
*error_exit = 0x1;
result = 1;
}
}
printf("Compared samples %d - %d with the reference\n", k, k+step);
}
/*! \brief main function
*
*/
int main() {
platform_init();
spn::mode_reg() = 1;
spn::start_reg() = 1;
wait_for_interrupt();
spn::interrupt_reg() = 1;
uint32_t readout = spn::readout_reg();
printf("READOUT HW:0x%x\n", readout);
uint32_t axi_bytes = readout;
axi_bytes = axi_bytes & 0xff;
axi_bytes = 1 << axi_bytes;
printf("AXI Bytes: %d\n", axi_bytes);
uint32_t sample_bytes = readout;
sample_bytes = sample_bytes >> 16;
sample_bytes = sample_bytes / 8;
printf("Sample Bytes: %d\n", sample_bytes);
uint32_t result_bytes = 8;
printf("Result Bytes: %d\n", result_bytes);
uint32_t step = 500;
uint32_t iterations = 10;
uint32_t in_beats = (step * sample_bytes) / axi_bytes;
if (in_beats * axi_bytes < step * sample_bytes) in_beats++;
uint32_t out_beats = (step * result_bytes) / axi_bytes;
if (out_beats * axi_bytes < step * result_bytes) out_beats++;
int in_addr = (int)input_data.data();
int out_addr = 0x800B0000;
int fpga_address_in = 0x10000000;
int fpga_address_out = 0x20000000;
//run_xspn(in_addr, out_addr);
for (int k = 0; k < iterations*step; k+=step) {
printf("XSPN processes samples %d - %d\n", k, k+step);
fpga_dma(1, fpga_address_in, in_addr, step * sample_bytes);
run_xspn(fpga_address_in, fpga_address_out, step, in_beats, out_beats);
wait_for_interrupt();
printf("XSPN finished\n");
spn::interrupt_reg() = 1;
fpga_dma(0, fpga_address_out, out_addr, step * result_bytes);
//check_results(out_addr, k, step);
//in_addr += step * sample_bytes; // 5 bytes in each sample
}
return 0;
}

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fpga_spn/src/raven_spn.h Normal file
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#ifndef RAVEN_SPN_H_
#define RAVEN_SPN_H_
extern "C" void handle_m_ext_interrupt();
#endif /* RAVEN_SPN_H_ */

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fpga_spn/src/spn_regs.h Normal file
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////////////////////////////////////////////////////////////////////////////////
// Copyright (C) 2017, MINRES Technologies GmbH
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are met:
//
// 1. Redistributions of source code must retain the above copyright notice,
// this list of conditions and the following disclaimer.
//
// 2. Redistributions in binary form must reproduce the above copyright notice,
// this list of conditions and the following disclaimer in the documentation
// and/or other materials provided with the distribution.
//
// 3. Neither the name of the copyright holder nor the names of its contributors
// may be used to endorse or promote products derived from this software
// without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
// Created on: Thu Oct 01 15:45:55 CEST 2020
// * spn_regs.h Author: <RDL Generator>
//
////////////////////////////////////////////////////////////////////////////////
#ifndef _SPN_REGS_H_
#define _SPN_REGS_H_
#include <util/bit_field.h>
#include <cstdint>
#define SPN_REG_START 0x00
#define SPN_REG_READOUT 0x10
#define SPN_REG_MODE 0x20
#define SPN_REG_INPUT_LENGTH 0x30
#define SPN_REG_INPUT_ADDR 0x40
#define SPN_REG_OUTPUT_ADDR 0x50
#define SPN_REG_NUM_OF_INPUT_BEATS 0x60
#define SPN_REG_NUM_OF_OUTPUT_BEATS 0x70
#define SPN_REG_INTERRUPT 0x0C
template<uint32_t BASE_ADDR>
class spn_regs {
public:
// storage declarations
// BEGIN_BF_DECL(start_t, uint32_t);
// BF_FIELD(start, 0, 1);
// END_BF_DECL() r_start;
uint32_t r_start;
uint32_t r_readout;
uint32_t r_mode;
uint32_t r_input_length;
uint32_t r_input_addr;
uint32_t r_output_addr;
uint32_t r_num_of_input_beats;
uint32_t r_num_of_output_beats;
// static inline start_t& start_reg(){
// return *reinterpret_cast<start_t*>(BASE_ADDR+SPN_REG_START);
// }
static inline uint32_t& start_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPN_REG_START);
}
static inline uint32_t & readout_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPN_REG_READOUT);
}
static inline uint32_t & mode_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPN_REG_MODE);
}
static inline uint32_t & input_length_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPN_REG_INPUT_LENGTH);
}
static inline uint32_t & input_addr_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPN_REG_INPUT_ADDR);
}
static inline uint32_t & output_addr_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPN_REG_OUTPUT_ADDR);
}
static inline uint32_t & num_of_in_beats_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPN_REG_NUM_OF_INPUT_BEATS);
}
static inline uint32_t & num_of_out_beats_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPN_REG_NUM_OF_OUTPUT_BEATS);
}
static inline uint32_t & interrupt_reg(){
return *reinterpret_cast<uint32_t*>(BASE_ADDR+SPN_REG_INTERRUPT);
}
};
#endif // _SPN_REGS_H_

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/*---------------------------------------------------------
Copyright (c) 2015 Jeff Preshing
This software is provided 'as-is', without any express or implied
warranty. In no event will the authors be held liable for any damages
arising from the use of this software.
Permission is granted to anyone to use this software for any purpose,
including commercial applications, and to alter it and redistribute it
freely, subject to the following restrictions:
1. The origin of this software must not be misrepresented; you must not
claim that you wrote the original software. If you use this software
in a product, an acknowledgement in the product documentation would be
appreciated but is not required.
2. Altered source versions must be plainly marked as such, and must not be
misrepresented as being the original software.
3. This notice may not be removed or altered from any source distribution.
---------------------------------------------------------*/
#ifndef BIT_FIELD_H_
#define BIT_FIELD_H_
#ifndef __CPP11OM_BITFIELD_H__
#define __CPP11OM_BITFIELD_H__
#include <cassert>
//---------------------------------------------------------
// BitFieldMember<>: Used internally by ADD_BITFIELD_MEMBER macro.
// All members are public to simplify compliance with sections 9.0.7 and
// 9.5.1 of the C++11 standard, thereby avoiding undefined behavior.
//---------------------------------------------------------
template <typename T, int Offset, int Bits> struct BitFieldMember {
T value;
static_assert(Offset + Bits <= (int)sizeof(T) * 8, "Member exceeds bitfield boundaries");
static_assert(Bits < (int)sizeof(T) * 8, "Can't fill entire bitfield with one member");
static const T Maximum = (T(1) << Bits) - 1;
static const T Mask = Maximum << Offset;
T maximum() const { return Maximum; }
T one() const { return T(1) << Offset; }
operator T() const { return (value >> Offset) & Maximum; }
BitFieldMember &operator=(T v) {
assert(v <= Maximum); // v must fit inside the bitfield member
value = (value & ~Mask) | (v << Offset);
return *this;
}
BitFieldMember &operator+=(T v) {
assert(T(*this) + v <= Maximum); // result must fit inside the bitfield member
value += v << Offset;
return *this;
}
BitFieldMember &operator-=(T v) {
assert(T(*this) >= v); // result must not underflow
value -= v << Offset;
return *this;
}
BitFieldMember &operator++() { return *this += 1; }
BitFieldMember operator++(int) { // postfix form
BitFieldMember tmp(*this);
operator++();
return tmp;
}
BitFieldMember &operator--() { return *this -= 1; }
BitFieldMember operator--(int) { // postfix form
BitFieldMember tmp(*this);
operator--();
return tmp;
}
};
//---------------------------------------------------------
// BitFieldArray<>: Used internally by ADD_BITFIELD_ARRAY macro.
// All members are public to simplify compliance with sections 9.0.7 and
// 9.5.1 of the C++11 standard, thereby avoiding undefined behavior.
//---------------------------------------------------------
template <typename T, int BaseOffset, int BitsPerItem, int NumItems> class BitFieldArray {
public:
T value;
static_assert(BaseOffset + BitsPerItem * NumItems <= (int)sizeof(T) * 8, "Array exceeds bitfield boundaries");
static_assert(BitsPerItem < (int)sizeof(T) * 8, "Can't fill entire bitfield with one array element");
static const T Maximum = (T(1) << BitsPerItem) - 1;
T maximum() const { return Maximum; }
int numItems() const { return NumItems; }
class Element {
private:
T &value;
int offset;
public:
Element(T &value, int offset)
: value(value)
, offset(offset) {}
T mask() const { return Maximum << offset; }
operator T() const { return (value >> offset) & Maximum; }
Element &operator=(T v) {
assert(v <= Maximum); // v must fit inside the bitfield member
value = (value & ~mask()) | (v << offset);
return *this;
}
Element &operator+=(T v) {
assert(T(*this) + v <= Maximum); // result must fit inside the bitfield member
value += v << offset;
return *this;
}
Element &operator-=(T v) {
assert(T(*this) >= v); // result must not underflow
value -= v << offset;
return *this;
}
Element &operator++() { return *this += 1; }
Element operator++(int) { // postfix form
Element tmp(*this);
operator++();
return tmp;
}
Element &operator--() { return *this -= 1; }
Element operator--(int) { // postfix form
Element tmp(*this);
operator--();
return tmp;
}
};
Element operator[](int i) {
assert(i >= 0 && i < NumItems); // array index must be in range
return Element(value, BaseOffset + BitsPerItem * i);
}
const Element operator[](int i) const {
assert(i >= 0 && i < NumItems); // array index must be in range
return Element(value, BaseOffset + BitsPerItem * i);
}
};
//---------------------------------------------------------
// Bitfield definition macros.
// All members are public to simplify compliance with sections 9.0.7 and
// 9.5.1 of the C++11 standard, thereby avoiding undefined behavior.
//---------------------------------------------------------
#define BEGIN_BF_DECL(typeName, T) \
union typeName { \
struct Wrapper { \
T value; \
}; \
Wrapper flat; \
typeName(T v = 0) { flat.value = v; } \
typeName &operator=(T v) { \
flat.value = v; \
return *this; \
} \
operator T &() { return flat.value; } \
operator T() const { return flat.value; } \
using StorageType = T;
#define BF_FIELD(memberName, offset, bits) BitFieldMember<StorageType, offset, bits> memberName;
#define BF_ARRAY(memberName, offset, bits, numItems) BitFieldArray<StorageType, offset, bits, numItems> memberName;
#define END_BF_DECL() }
#endif // __CPP11OM_BITFIELD_H__
#endif /* BIT_FIELD_H_ */

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