soc/intel/intel_adsp/cavs/multiprocessing.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /* Copyright (c) 2021 Intel Corporation
  * SPDX-License-Identifier: Apache-2.0
  */
 #include <zephyr/kernel.h>
 #include <cavs-idc.h>
 #include <adsp_memory.h>
 #include <adsp_shim.h>
 #include <zephyr/irq.h>
 #include <zephyr/pm/pm.h>
 #include <zephyr/cache.h>

 /* IDC power up message to the ROM firmware.  This isn't documented
  * anywhere, it's basically just a magic number (except the high bit,
  * which signals the hardware)
  */
 #define IDC_MSG_POWER_UP				  \
 	(BIT(31) |     /* Latch interrupt in ITC write */ \
 	 (0x1 << 24) | /* "ROM control version" = 1 */	  \
 	 (0x2 << 0))   /* "Core wake version" = 2 */

 #define IDC_CORE_MASK(num_cpus) (BIT(num_cpus) - 1)

 __imr void soc_mp_startup(uint32_t cpu)
 {
 	/* We got here via an IDC interrupt.  Clear the TFC high bit
 	 * (by writing a one!) to acknowledge and clear the latched
 	 * hardware interrupt (so we don't have to service it as a
 	 * spurious IPI when we enter user code).  Remember: this
 	 * could have come from any core, clear all of them.
 	 */
 	unsigned int num_cpus = arch_num_cpus();

 	for (int i = 0; i < num_cpus; i++) {
 		IDC[cpu].core[i].tfc = BIT(31);
 	}

 	/* Interrupt must be enabled while running on current core */
 	irq_enable(DT_IRQN(INTEL_ADSP_IDC_DTNODE));

 }

 void soc_start_core(int cpu_num)
 {
 	uint32_t curr_cpu = arch_proc_id();

 	/* On cAVS v2.5, MP startup works differently.  The core has
 	 * no ROM, and starts running immediately upon receipt of an
 	 * IDC interrupt at the start of LPSRAM at 0xbe800000.  Note
 	 * that means we don't need to bother constructing a "message"
 	 * below, it will be ignored.  But it's left in place for
 	 * simplicity and compatibility.
 	 *
 	 * All we need to do is place a single jump at that address to
 	 * our existing MP entry point.  Unfortunately Xtensa makes
 	 * this difficult, as the region is beyond the range of a
 	 * relative jump instruction, so we need an immediate, which
 	 * can only be backwards-referenced.  So we hand-assemble a
 	 * tiny trampoline here ("jump over the immediate address,
 	 * load it, jump to it").
 	 *
 	 * Long term we want to have this in linkable LP-SRAM memory
 	 * such that the standard system bootstrap out of IMR can
 	 * place it there.  But this is fine for now.
 	 */
 	void **lpsram = sys_cache_uncached_ptr_get(
 			(__sparse_force void __sparse_cache *)LP_SRAM_BASE);
 	uint8_t tramp[] = {
 		0x06, 0x01, 0x00, /* J <PC+8>  (jump to L32R) */
 		0,                /* (padding to align entry_addr) */
 		0, 0, 0, 0,       /* (entry_addr goes here) */
 		0x01, 0xff, 0xff, /* L32R a0, <entry_addr> */
 		0xa0, 0x00, 0x00, /* JX a0 */
 	};

 	memcpy(lpsram, tramp, ARRAY_SIZE(tramp));
 #if CONFIG_PM
 	extern void dsp_restore_vector(void);

 	/* We need to find out what type of booting is taking place here. Secondary cores
 	 * can be disabled and enabled multiple times during runtime. During kernel
 	 * initialization, the next pm state is set to ACTIVE. This way we can determine
 	 * whether the core is being turned on again or for the first time.
 	 */
 	if (pm_state_next_get(cpu_num)->state == PM_STATE_ACTIVE)
 		lpsram[1] = z_soc_mp_asm_entry;
 	else
 		lpsram[1] = dsp_restore_vector;
 #else
 	lpsram[1] = z_soc_mp_asm_entry;
 #endif


 	/* Disable automatic power and clock gating for that CPU, so
 	 * it won't just go back to sleep.  Note that after startup,
 	 * the cores are NOT power gated even if they're configured to
 	 * be, so by default a core will launch successfully but then
 	 * turn itself off when it gets to the WAITI instruction in
 	 * the idle thread.
 	 */
 	CAVS_SHIM.clkctl |= CAVS_CLKCTL_TCPLCG(cpu_num);
 	CAVS_SHIM.pwrctl |= CAVS_PWRCTL_TCPDSPPG(cpu_num);

 	/* We set the interrupt controller up already, but the ROM on
 	 * some platforms will mess it up.
 	 */
 	CAVS_INTCTRL[cpu_num].l2.clear = CAVS_L2_IDC;
 	unsigned int num_cpus = arch_num_cpus();

 	for (int c = 0; c < num_cpus; c++) {
 		IDC[c].busy_int |= IDC_CORE_MASK(num_cpus);
 	}

 	/* Send power-up message to the other core.  Start address
 	 * gets passed via the IETC scratch register (only 30 bits
 	 * available, so it's sent shifted).  The write to ITC
 	 * triggers the interrupt, so that comes last.
 	 */
 	uint32_t ietc = ((long)lpsram[1]) >> 2;

 	IDC[curr_cpu].core[cpu_num].ietc = ietc;
 	IDC[curr_cpu].core[cpu_num].itc = IDC_MSG_POWER_UP;
 }

 void arch_sched_ipi(void)
 {
 	uint32_t curr = arch_proc_id();
 	unsigned int num_cpus = arch_num_cpus();

 	for (int c = 0; c < num_cpus; c++) {
 		if (c != curr && soc_cpus_active[c]) {
 			IDC[curr].core[c].itc = BIT(31);
 		}
 	}
 }

 void idc_isr(const void *param)
 {
 	ARG_UNUSED(param);

 #ifdef CONFIG_SMP
 	/* Right now this interrupt is only used for IPIs */
 	z_sched_ipi();
 #endif

 	/* ACK the interrupt to all the possible sources.  This is a
 	 * level-sensitive interrupt triggered by a logical OR of each
 	 * of the ITC/TFC high bits, INCLUDING the one "from this
 	 * CPU".
 	 */

 	unsigned int num_cpus = arch_num_cpus();

 	for (int i = 0; i < num_cpus; i++) {
 		IDC[arch_proc_id()].core[i].tfc = BIT(31);
 	}
 }

 __imr void soc_mp_init(void)
 {
 	IRQ_CONNECT(DT_IRQN(INTEL_ADSP_IDC_DTNODE), 0, idc_isr, NULL, 0);

 	/* Every CPU should be able to receive an IDC interrupt from
 	 * every other CPU, but not to be back-interrupted when the
 	 * target core clears the busy bit.
 	 */
 	unsigned int num_cpus = arch_num_cpus();

 	for (int core = 0; core < num_cpus; core++) {
 		IDC[core].busy_int |= IDC_CORE_MASK(num_cpus);
 		IDC[core].done_int &= ~IDC_CORE_MASK(num_cpus);

 		/* Also unmask the IDC interrupt for every core in the
 		 * L2 mask register.
 		 */
 		CAVS_INTCTRL[core].l2.clear = CAVS_L2_IDC;
 	}

 	/* Clear out any existing pending interrupts that might be present */
 	for (int i = 0; i < num_cpus; i++) {
 		for (int j = 0; j < num_cpus; j++) {
 			IDC[i].core[j].tfc = BIT(31);
 		}
 	}

 	soc_cpus_active[0] = true;
 }

 int soc_adsp_halt_cpu(int id)
 {
 	unsigned int irq_mask;

 	if (id == 0 || id == arch_curr_cpu()->id) {
 		return -EINVAL;
 	}

 	irq_mask = CAVS_L2_IDC;

 #ifdef CONFIG_INTEL_ADSP_TIMER
 	/*
 	 * Mask timer interrupt for this CPU so it won't wake up
 	 * by itself once WFI (wait for interrupt) instruction
 	 * runs.
 	 */
 	irq_mask |= CAVS_L2_DWCT0;
 #endif

 	CAVS_INTCTRL[id].l2.set = irq_mask;

 	/* Stop sending IPIs to this core */
 	soc_cpus_active[id] = false;

 	/* Turn off the "prevent power/clock gating" bits, enabling
 	 * low power idle
 	 */
 	CAVS_SHIM.pwrctl &= ~CAVS_PWRCTL_TCPDSPPG(id);
 	CAVS_SHIM.clkctl &= ~CAVS_CLKCTL_TCPLCG(id);

 	/* If possible, wait for the other CPU to reach an idle state
 	 * before returning.  On older hardware this doesn't work
 	 * because power is controlled by the host, so synchronization
 	 * needs to be part of the application layer.
 	 */
 	while ((CAVS_SHIM.pwrsts & CAVS_PWRSTS_PDSPPGS(id))) {
 	}
 	return 0;
 }
	/* Copyright (c) 2021 Intel Corporation
	* SPDX-License-Identifier: Apache-2.0
	*/
	#include <zephyr/kernel.h>
	#include <cavs-idc.h>
	#include <adsp_memory.h>
	#include <adsp_shim.h>
	#include <zephyr/irq.h>
	#include <zephyr/pm/pm.h>
	#include <zephyr/cache.h>

	/* IDC power up message to the ROM firmware. This isn't documented
	* anywhere, it's basically just a magic number (except the high bit,
	* which signals the hardware)
	*/
	#define IDC_MSG_POWER_UP \
	(BIT(31) \| /* Latch interrupt in ITC write */ \
	(0x1 << 24) \| /* "ROM control version" = 1 */ \
	(0x2 << 0)) /* "Core wake version" = 2 */

	#define IDC_CORE_MASK(num_cpus) (BIT(num_cpus) - 1)

	__imr void soc_mp_startup(uint32_t cpu)
	{
	/* We got here via an IDC interrupt. Clear the TFC high bit
	* (by writing a one!) to acknowledge and clear the latched
	* hardware interrupt (so we don't have to service it as a
	* spurious IPI when we enter user code). Remember: this
	* could have come from any core, clear all of them.
	*/
	unsigned int num_cpus = arch_num_cpus();

	for (int i = 0; i < num_cpus; i++) {
	IDC[cpu].core[i].tfc = BIT(31);
	}

	/* Interrupt must be enabled while running on current core */
	irq_enable(DT_IRQN(INTEL_ADSP_IDC_DTNODE));

	}

	void soc_start_core(int cpu_num)
	{
	uint32_t curr_cpu = arch_proc_id();

	/* On cAVS v2.5, MP startup works differently. The core has
	* no ROM, and starts running immediately upon receipt of an
	* IDC interrupt at the start of LPSRAM at 0xbe800000. Note
	* that means we don't need to bother constructing a "message"
	* below, it will be ignored. But it's left in place for
	* simplicity and compatibility.
	*
	* All we need to do is place a single jump at that address to
	* our existing MP entry point. Unfortunately Xtensa makes
	* this difficult, as the region is beyond the range of a
	* relative jump instruction, so we need an immediate, which
	* can only be backwards-referenced. So we hand-assemble a
	* tiny trampoline here ("jump over the immediate address,
	* load it, jump to it").
	*
	* Long term we want to have this in linkable LP-SRAM memory
	* such that the standard system bootstrap out of IMR can
	* place it there. But this is fine for now.
	*/
	void **lpsram = sys_cache_uncached_ptr_get(
	(__sparse_force void __sparse_cache *)LP_SRAM_BASE);
	uint8_t tramp[] = {
	0x06, 0x01, 0x00, /* J <PC+8> (jump to L32R) */
	0, /* (padding to align entry_addr) */
	0, 0, 0, 0, /* (entry_addr goes here) */
	0x01, 0xff, 0xff, /* L32R a0, <entry_addr> */
	0xa0, 0x00, 0x00, /* JX a0 */
	};

	memcpy(lpsram, tramp, ARRAY_SIZE(tramp));
	#if CONFIG_PM
	extern void dsp_restore_vector(void);

	/* We need to find out what type of booting is taking place here. Secondary cores
	* can be disabled and enabled multiple times during runtime. During kernel
	* initialization, the next pm state is set to ACTIVE. This way we can determine
	* whether the core is being turned on again or for the first time.
	*/
	if (pm_state_next_get(cpu_num)->state == PM_STATE_ACTIVE)
	lpsram[1] = z_soc_mp_asm_entry;
	else
	lpsram[1] = dsp_restore_vector;
	#else
	lpsram[1] = z_soc_mp_asm_entry;
	#endif


	/* Disable automatic power and clock gating for that CPU, so
	* it won't just go back to sleep. Note that after startup,
	* the cores are NOT power gated even if they're configured to
	* be, so by default a core will launch successfully but then
	* turn itself off when it gets to the WAITI instruction in
	* the idle thread.
	*/
	CAVS_SHIM.clkctl \|= CAVS_CLKCTL_TCPLCG(cpu_num);
	CAVS_SHIM.pwrctl \|= CAVS_PWRCTL_TCPDSPPG(cpu_num);

	/* We set the interrupt controller up already, but the ROM on
	* some platforms will mess it up.
	*/
	CAVS_INTCTRL[cpu_num].l2.clear = CAVS_L2_IDC;
	unsigned int num_cpus = arch_num_cpus();

	for (int c = 0; c < num_cpus; c++) {
	IDC[c].busy_int \|= IDC_CORE_MASK(num_cpus);
	}

	/* Send power-up message to the other core. Start address
	* gets passed via the IETC scratch register (only 30 bits
	* available, so it's sent shifted). The write to ITC
	* triggers the interrupt, so that comes last.
	*/
	uint32_t ietc = ((long)lpsram[1]) >> 2;

	IDC[curr_cpu].core[cpu_num].ietc = ietc;
	IDC[curr_cpu].core[cpu_num].itc = IDC_MSG_POWER_UP;
	}

	void arch_sched_ipi(void)
	{
	uint32_t curr = arch_proc_id();
	unsigned int num_cpus = arch_num_cpus();

	for (int c = 0; c < num_cpus; c++) {
	if (c != curr && soc_cpus_active[c]) {
	IDC[curr].core[c].itc = BIT(31);
	}
	}
	}

	void idc_isr(const void *param)
	{
	ARG_UNUSED(param);

	#ifdef CONFIG_SMP
	/* Right now this interrupt is only used for IPIs */
	z_sched_ipi();
	#endif

	/* ACK the interrupt to all the possible sources. This is a
	* level-sensitive interrupt triggered by a logical OR of each
	* of the ITC/TFC high bits, INCLUDING the one "from this
	* CPU".
	*/

	unsigned int num_cpus = arch_num_cpus();

	for (int i = 0; i < num_cpus; i++) {
	IDC[arch_proc_id()].core[i].tfc = BIT(31);
	}
	}

	__imr void soc_mp_init(void)
	{
	IRQ_CONNECT(DT_IRQN(INTEL_ADSP_IDC_DTNODE), 0, idc_isr, NULL, 0);

	/* Every CPU should be able to receive an IDC interrupt from
	* every other CPU, but not to be back-interrupted when the
	* target core clears the busy bit.
	*/
	unsigned int num_cpus = arch_num_cpus();

	for (int core = 0; core < num_cpus; core++) {
	IDC[core].busy_int \|= IDC_CORE_MASK(num_cpus);
	IDC[core].done_int &= ~IDC_CORE_MASK(num_cpus);

	/* Also unmask the IDC interrupt for every core in the
	* L2 mask register.
	*/
	CAVS_INTCTRL[core].l2.clear = CAVS_L2_IDC;
	}

	/* Clear out any existing pending interrupts that might be present */
	for (int i = 0; i < num_cpus; i++) {
	for (int j = 0; j < num_cpus; j++) {
	IDC[i].core[j].tfc = BIT(31);
	}
	}

	soc_cpus_active[0] = true;
	}

	int soc_adsp_halt_cpu(int id)
	{
	unsigned int irq_mask;

	if (id == 0 \|\| id == arch_curr_cpu()->id) {
	return -EINVAL;
	}

	irq_mask = CAVS_L2_IDC;

	#ifdef CONFIG_INTEL_ADSP_TIMER
	/*
	* Mask timer interrupt for this CPU so it won't wake up
	* by itself once WFI (wait for interrupt) instruction
	* runs.
	*/
	irq_mask \|= CAVS_L2_DWCT0;
	#endif

	CAVS_INTCTRL[id].l2.set = irq_mask;

	/* Stop sending IPIs to this core */
	soc_cpus_active[id] = false;

	/* Turn off the "prevent power/clock gating" bits, enabling
	* low power idle
	*/
	CAVS_SHIM.pwrctl &= ~CAVS_PWRCTL_TCPDSPPG(id);
	CAVS_SHIM.clkctl &= ~CAVS_CLKCTL_TCPLCG(id);

	/* If possible, wait for the other CPU to reach an idle state
	* before returning. On older hardware this doesn't work
	* because power is controlled by the host, so synchronization
	* needs to be part of the application layer.
	*/
	while ((CAVS_SHIM.pwrsts & CAVS_PWRSTS_PDSPPGS(id))) {
	}
	return 0;
	}