arch/x86_64/core/demo-kernel.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2018 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */
 #include "serial.h"
 #include "vgacon.h"
 #include "printf.h"
 #include "xuk.h"

 /* Tiny demonstration of the core64 code.  Implements enough of an
  * "OS" layer to do some simple unit testing.
  */

 static void putchar(int c)
 {
 	serial_putc(c);
 	vgacon_putc(c);
 }

 void test_timers(void)
 {
 	/* Quickly calibrate the timers against each other.  Note that
 	 * the APIC is counting DOWN instead of up!  Seems like on
 	 * qemu, the APIC base frequency is 3.7x slower than the tsc.
 	 * Looking at source, it seems like APIC is uniformly shifted
 	 * down from a nominal 1Ghz reference
 	 * (i.e. qemu_get_time_ns()), where the TSC is based on
 	 * cpu_get_ticks() and thus pulls in wall clock time & such.
 	 * If you specify "-icount shift=1", then they synchronize
 	 * properly.
 	 */
 	int tsc0, apic0, tsc1, apic1;

 	__asm__ volatile("rdtsc" : "=a"(tsc0) : : "rdx");
 	apic0 = _apic.CURR_COUNT;
 	do {
 		/* Qemu misbehaves if I spam these registers. */
 		for (int i = 0; i < 1000; i++) {
 			__asm__ volatile("nop");
 		}

 		__asm__ volatile("rdtsc" : "=a"(tsc1) : : "rdx");
 		apic1 = _apic.CURR_COUNT;
 	} while ((tsc1 - tsc0) < 10000 || (apic0 - apic1) < 10000);
 	printf("tsc %d apic %d\n", tsc1 - tsc0, apic0 - apic1);
 }

 void handler_timer(void *arg, int err)
 {
 	printf("Timer expired on CPU%d\n", (int)(long)xuk_get_f_ptr());
 }

 void handler_f3(void *arg, int err)
 {
 	printf("f3 handler on cpu%d arg %x, triggering INT 0xff\n",
 	       (int)(long)xuk_get_f_ptr(), (int)(long)arg);
 	__asm__ volatile("int $0xff");
 	printf("end f3 handler\n");
 }

 void z_unhandled_vector(int vector, int err, struct xuk_entry_frame *f)
 {
 	(void)f;
 	z_putchar = putchar;
 	printf("Unhandled vector %d (err %xh) on CPU%d\n",
 	       vector, err, (int)(long)xuk_get_f_ptr());
 }

 void z_isr_entry(void)
 {
 }

 void *z_isr_exit_restore_stack(void *interrupted)
 {
 	/* Somewhat hacky test of the ISR exit modes.  Two ways of
 	 * specifying "this stack", one of which does the full spill
 	 * and restore and one shortcuts that due to the NULL
 	 * return
 	 */
 	if (rdtsc() & 1) {
 		return interrupted;
 	} else {
 		return 0;
 	}
 }

 void *switch_back_to;

 void switch_back(int arg1, int arg2, int arg3)
 {
 	printf("Switching back (%d, %d, %d) sbt %xh\n",
 	       arg1, arg2, arg3, (int)(long)switch_back_to);
 	xuk_switch(switch_back_to, &switch_back_to);
 }

 void test_switch(void)
 {
 	static unsigned long long stack[256];
 	long args[] = { 5, 4, 3 };
 	int eflags = 0x20; /* interrupts disabled */

 	long handle = xuk_setup_stack((long)(sizeof(stack) + (char *)stack),
 				      switch_back, eflags, args, 3);

 	printf("Switching to %xh (stack %xh)\n",
 	       (int)handle, (int)(long)&stack[0]);
 	__asm__ volatile("cli");
 	xuk_switch((void *)handle, &switch_back_to);
 	__asm__ volatile("sti");
 	printf("Back from switch\n");
 }

 void local_ipi_handler(void *arg, int err)
 {
 	printf("local IPI handler on CPU%d\n", (int)(long)xuk_get_f_ptr());
 }

 /* Sends an IPI to the current CPU and validates it ran */
 void test_local_ipi(void)
 {
 	printf("Testing a local IPI on CPU%d\n", (int)(long)xuk_get_f_ptr());

 	_apic.ICR_HI = (struct apic_icr_hi) {};
 	_apic.ICR_LO = (struct apic_icr_lo) {
 		.delivery_mode = FIXED,
 		.vector = 0x90,
 		.shorthand = SELF,
 	};
 }

 void z_cpu_start(int cpu)
 {
 	z_putchar = putchar;
 	printf("Entering demo kernel\n");

 	/* Make sure the FS/GS pointers work, then set F to store our
 	 * CPU ID
 	 */
 	xuk_set_f_ptr(cpu, (void *)(long)(0x19283700 + cpu));
 	xuk_set_g_ptr(cpu, (void *)(long)(0xabacad00 + cpu));
 	printf("fptr %p gptr %p\n", xuk_get_f_ptr(), xuk_get_g_ptr());

 	xuk_set_f_ptr(cpu, (void *)(long)cpu);

 	/* Set up this CPU's timer */
 	/* FIXME: this sets up a separate vector for every CPU's
 	 * timer, and we'll run out.  They should share the vector but
 	 * still have individually-set APIC config.  Probably wants a
 	 * "timer" API
 	 */
 	xuk_set_isr(INT_APIC_LVT_TIMER, 10, handler_timer, 0);
 	_apic.INIT_COUNT = 5000000U;
 	test_timers();

 	if (cpu == 0) {
 		xuk_start_cpu(1, (long)alloc_page(0) + 4096);
 		xuk_set_isr(0x1f3, 0, (void *)handler_f3, (void *)0x12345678);
 	}

 	__asm__ volatile("int $0xf3");

 	/* Fire it all up */
 	printf("Enabling Interrupts\n");
 	__asm__ volatile("sti");
 	printf("Interrupts are unmasked (eflags %xh), here we go...\n",
 	       eflags());

 	/* Wait a teeny bit then send an IPI to CPU0, which will hit
 	 * the unhandled_vector handler
 	 */
 	if (cpu == 1) {
 		int t0 = rdtsc();

 		while (rdtsc() - t0 < 1000000) {
 		}

 		_apic.ICR_HI = (struct apic_icr_hi) {
 			.destination = 0
 		};
 		_apic.ICR_LO = (struct apic_icr_lo) {
 			.delivery_mode = FIXED,
 			.vector = 66,
 		};
 		while (_apic.ICR_LO.send_pending) {
 		}
 	}

 	test_switch();

 	xuk_set_isr(XUK_INT_RAW_VECTOR(0x90), -1, local_ipi_handler, 0);
 	test_local_ipi();

 	printf("CPU%d initialized, sleeping\n", cpu);
 	while (1) {
 		__asm__ volatile("hlt");
 	}
 }
	/*
	* Copyright (c) 2018 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/
	#include "serial.h"
	#include "vgacon.h"
	#include "printf.h"
	#include "xuk.h"

	/* Tiny demonstration of the core64 code. Implements enough of an
	* "OS" layer to do some simple unit testing.
	*/

	static void putchar(int c)
	{
	serial_putc(c);
	vgacon_putc(c);
	}

	void test_timers(void)
	{
	/* Quickly calibrate the timers against each other. Note that
	* the APIC is counting DOWN instead of up! Seems like on
	* qemu, the APIC base frequency is 3.7x slower than the tsc.
	* Looking at source, it seems like APIC is uniformly shifted
	* down from a nominal 1Ghz reference
	* (i.e. qemu_get_time_ns()), where the TSC is based on
	* cpu_get_ticks() and thus pulls in wall clock time & such.
	* If you specify "-icount shift=1", then they synchronize
	* properly.
	*/
	int tsc0, apic0, tsc1, apic1;

	__asm__ volatile("rdtsc" : "=a"(tsc0) : : "rdx");
	apic0 = _apic.CURR_COUNT;
	do {
	/* Qemu misbehaves if I spam these registers. */
	for (int i = 0; i < 1000; i++) {
	__asm__ volatile("nop");
	}

	__asm__ volatile("rdtsc" : "=a"(tsc1) : : "rdx");
	apic1 = _apic.CURR_COUNT;
	} while ((tsc1 - tsc0) < 10000 \|\| (apic0 - apic1) < 10000);
	printf("tsc %d apic %d\n", tsc1 - tsc0, apic0 - apic1);
	}

	void handler_timer(void *arg, int err)
	{
	printf("Timer expired on CPU%d\n", (int)(long)xuk_get_f_ptr());
	}

	void handler_f3(void *arg, int err)
	{
	printf("f3 handler on cpu%d arg %x, triggering INT 0xff\n",
	(int)(long)xuk_get_f_ptr(), (int)(long)arg);
	__asm__ volatile("int $0xff");
	printf("end f3 handler\n");
	}

	void z_unhandled_vector(int vector, int err, struct xuk_entry_frame *f)
	{
	(void)f;
	z_putchar = putchar;
	printf("Unhandled vector %d (err %xh) on CPU%d\n",
	vector, err, (int)(long)xuk_get_f_ptr());
	}

	void z_isr_entry(void)
	{
	}

	void z_isr_exit_restore_stack(void interrupted)
	{
	/* Somewhat hacky test of the ISR exit modes. Two ways of
	* specifying "this stack", one of which does the full spill
	* and restore and one shortcuts that due to the NULL
	* return
	*/
	if (rdtsc() & 1) {
	return interrupted;
	} else {
	return 0;
	}
	}

	void *switch_back_to;

	void switch_back(int arg1, int arg2, int arg3)
	{
	printf("Switching back (%d, %d, %d) sbt %xh\n",
	arg1, arg2, arg3, (int)(long)switch_back_to);
	xuk_switch(switch_back_to, &switch_back_to);
	}

	void test_switch(void)
	{
	static unsigned long long stack[256];
	long args[] = { 5, 4, 3 };
	int eflags = 0x20; /* interrupts disabled */

	long handle = xuk_setup_stack((long)(sizeof(stack) + (char *)stack),
	switch_back, eflags, args, 3);

	printf("Switching to %xh (stack %xh)\n",
	(int)handle, (int)(long)&stack[0]);
	__asm__ volatile("cli");
	xuk_switch((void *)handle, &switch_back_to);
	__asm__ volatile("sti");
	printf("Back from switch\n");
	}

	void local_ipi_handler(void *arg, int err)
	{
	printf("local IPI handler on CPU%d\n", (int)(long)xuk_get_f_ptr());
	}

	/* Sends an IPI to the current CPU and validates it ran */
	void test_local_ipi(void)
	{
	printf("Testing a local IPI on CPU%d\n", (int)(long)xuk_get_f_ptr());

	_apic.ICR_HI = (struct apic_icr_hi) {};
	_apic.ICR_LO = (struct apic_icr_lo) {
	.delivery_mode = FIXED,
	.vector = 0x90,
	.shorthand = SELF,
	};
	}

	void z_cpu_start(int cpu)
	{
	z_putchar = putchar;
	printf("Entering demo kernel\n");

	/* Make sure the FS/GS pointers work, then set F to store our
	* CPU ID
	*/
	xuk_set_f_ptr(cpu, (void *)(long)(0x19283700 + cpu));
	xuk_set_g_ptr(cpu, (void *)(long)(0xabacad00 + cpu));
	printf("fptr %p gptr %p\n", xuk_get_f_ptr(), xuk_get_g_ptr());

	xuk_set_f_ptr(cpu, (void *)(long)cpu);

	/* Set up this CPU's timer */
	/* FIXME: this sets up a separate vector for every CPU's
	* timer, and we'll run out. They should share the vector but
	* still have individually-set APIC config. Probably wants a
	* "timer" API
	*/
	xuk_set_isr(INT_APIC_LVT_TIMER, 10, handler_timer, 0);
	_apic.INIT_COUNT = 5000000U;
	test_timers();

	if (cpu == 0) {
	xuk_start_cpu(1, (long)alloc_page(0) + 4096);
	xuk_set_isr(0x1f3, 0, (void )handler_f3, (void )0x12345678);
	}

	__asm__ volatile("int $0xf3");

	/* Fire it all up */
	printf("Enabling Interrupts\n");
	__asm__ volatile("sti");
	printf("Interrupts are unmasked (eflags %xh), here we go...\n",
	eflags());

	/* Wait a teeny bit then send an IPI to CPU0, which will hit
	* the unhandled_vector handler
	*/
	if (cpu == 1) {
	int t0 = rdtsc();

	while (rdtsc() - t0 < 1000000) {
	}

	_apic.ICR_HI = (struct apic_icr_hi) {
	.destination = 0
	};
	_apic.ICR_LO = (struct apic_icr_lo) {
	.delivery_mode = FIXED,
	.vector = 66,
	};
	while (_apic.ICR_LO.send_pending) {
	}
	}

	test_switch();

	xuk_set_isr(XUK_INT_RAW_VECTOR(0x90), -1, local_ipi_handler, 0);
	test_local_ipi();

	printf("CPU%d initialized, sleeping\n", cpu);
	while (1) {
	__asm__ volatile("hlt");
	}
	}