plat/xilinx/versal/pm_service/pm_client.c - filogic/atf - Gitiles

 /*
  * Copyright (c) 2019-2020, Xilinx, Inc. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 /*
  * APU specific definition of processors in the subsystem as well as functions
  * for getting information about and changing state of the APU.
  */

 #include <assert.h>
 #include <plat_ipi.h>
 #include <platform_def.h>
 #include <versal_def.h>
 #include <lib/bakery_lock.h>
 #include <lib/mmio.h>
 #include <lib/utils.h>
 #include <drivers/arm/gicv3.h>
 #include <drivers/arm/gic_common.h>
 #include <plat/common/platform.h>
 #include "pm_api_sys.h"
 #include "pm_client.h"

 #define UNDEFINED_CPUID		(~0)
 #define IRQ_MAX		142
 #define NUM_GICD_ISENABLER	((IRQ_MAX >> 5) + 1)

 DEFINE_BAKERY_LOCK(pm_client_secure_lock);

 static const struct pm_ipi apu_ipi = {
 	.local_ipi_id = IPI_ID_APU,
 	.remote_ipi_id = IPI_ID_PMC,
 	.buffer_base = IPI_BUFFER_APU_BASE,
 };

 /* Order in pm_procs_all array must match cpu ids */
 static const struct pm_proc pm_procs_all[] = {
 	{
 		.node_id = XPM_DEVID_ACPU_0,
 		.ipi = &apu_ipi,
 		.pwrdn_mask = APU_0_PWRCTL_CPUPWRDWNREQ_MASK,
 	},
 	{
 		.node_id = XPM_DEVID_ACPU_1,
 		.ipi = &apu_ipi,
 		.pwrdn_mask = APU_1_PWRCTL_CPUPWRDWNREQ_MASK,
 	}
 };

 const struct pm_proc *primary_proc = &pm_procs_all[0];

 /* Interrupt to PM node index map */
 static enum pm_device_node_idx irq_node_map[IRQ_MAX + 1] = {
 	[13] = XPM_NODEIDX_DEV_GPIO,
 	[14] = XPM_NODEIDX_DEV_I2C_0,
 	[15] = XPM_NODEIDX_DEV_I2C_1,
 	[16] = XPM_NODEIDX_DEV_SPI_0,
 	[17] = XPM_NODEIDX_DEV_SPI_1,
 	[18] = XPM_NODEIDX_DEV_UART_0,
 	[19] = XPM_NODEIDX_DEV_UART_1,
 	[20] = XPM_NODEIDX_DEV_CAN_FD_0,
 	[21] = XPM_NODEIDX_DEV_CAN_FD_1,
 	[22] = XPM_NODEIDX_DEV_USB_0,
 	[23] = XPM_NODEIDX_DEV_USB_0,
 	[24] = XPM_NODEIDX_DEV_USB_0,
 	[25] = XPM_NODEIDX_DEV_USB_0,
 	[26] = XPM_NODEIDX_DEV_USB_0,
 	[37] = XPM_NODEIDX_DEV_TTC_0,
 	[38] = XPM_NODEIDX_DEV_TTC_0,
 	[39] = XPM_NODEIDX_DEV_TTC_0,
 	[40] = XPM_NODEIDX_DEV_TTC_1,
 	[41] = XPM_NODEIDX_DEV_TTC_1,
 	[42] = XPM_NODEIDX_DEV_TTC_1,
 	[43] = XPM_NODEIDX_DEV_TTC_2,
 	[44] = XPM_NODEIDX_DEV_TTC_2,
 	[45] = XPM_NODEIDX_DEV_TTC_2,
 	[46] = XPM_NODEIDX_DEV_TTC_3,
 	[47] = XPM_NODEIDX_DEV_TTC_3,
 	[48] = XPM_NODEIDX_DEV_TTC_3,
 	[56] = XPM_NODEIDX_DEV_GEM_0,
 	[57] = XPM_NODEIDX_DEV_GEM_0,
 	[58] = XPM_NODEIDX_DEV_GEM_1,
 	[59] = XPM_NODEIDX_DEV_GEM_1,
 	[60] = XPM_NODEIDX_DEV_ADMA_0,
 	[61] = XPM_NODEIDX_DEV_ADMA_1,
 	[62] = XPM_NODEIDX_DEV_ADMA_2,
 	[63] = XPM_NODEIDX_DEV_ADMA_3,
 	[64] = XPM_NODEIDX_DEV_ADMA_4,
 	[65] = XPM_NODEIDX_DEV_ADMA_5,
 	[66] = XPM_NODEIDX_DEV_ADMA_6,
 	[67] = XPM_NODEIDX_DEV_ADMA_7,
 	[74] = XPM_NODEIDX_DEV_USB_0,
 	[126] = XPM_NODEIDX_DEV_SDIO_0,
 	[127] = XPM_NODEIDX_DEV_SDIO_0,
 	[128] = XPM_NODEIDX_DEV_SDIO_1,
 	[129] = XPM_NODEIDX_DEV_SDIO_1,
 	[142] = XPM_NODEIDX_DEV_RTC,
 };

 /**
  * irq_to_pm_node_idx - Get PM node index corresponding to the interrupt number
  * @irq:	Interrupt number
  *
  * Return:	PM node index corresponding to the specified interrupt
  */
 static enum pm_device_node_idx irq_to_pm_node_idx(unsigned int irq)
 {
 	assert(irq <= IRQ_MAX);
 	return irq_node_map[irq];
 }

 /**
  * pm_client_set_wakeup_sources - Set all devices with enabled interrupts as
  *				  wake sources in the LibPM.
  * @node_id:	Node id of processor
  */
 static void pm_client_set_wakeup_sources(uint32_t node_id)
 {
 	uint32_t reg_num;
 	uint32_t device_id;
 	uint8_t pm_wakeup_nodes_set[XPM_NODEIDX_DEV_MAX];
 	uintptr_t isenabler1 = PLAT_VERSAL_GICD_BASE + GICD_ISENABLER + 4;

 	zeromem(&pm_wakeup_nodes_set, sizeof(pm_wakeup_nodes_set));

 	for (reg_num = 0; reg_num < NUM_GICD_ISENABLER; reg_num++) {
 		uint32_t base_irq = reg_num << ISENABLER_SHIFT;
 		uint32_t reg = mmio_read_32(isenabler1 + (reg_num << 2));

 		if (!reg)
 			continue;

 		while (reg) {
 			enum pm_device_node_idx node_idx;
 			uint32_t idx, ret, irq, lowest_set = reg & (-reg);

 			idx = __builtin_ctz(lowest_set);
 			irq = base_irq + idx;

 			if (irq > IRQ_MAX)
 				break;

 			node_idx = irq_to_pm_node_idx(irq);
 			reg &= ~lowest_set;

 			if ((node_idx != XPM_NODEIDX_DEV_MIN) &&
 			    (!pm_wakeup_nodes_set[node_idx])) {
 				/* Get device ID from node index */
 				device_id = PERIPH_DEVID(node_idx);
 				ret = pm_set_wakeup_source(node_id,
 							   device_id, 1,
 							   SECURE_FLAG);
 				pm_wakeup_nodes_set[node_idx] = !ret;
 			}
 		}
 	}
 }

 /**
  * pm_client_suspend() - Client-specific suspend actions
  *
  * This function should contain any PU-specific actions
  * required prior to sending suspend request to PMU
  * Actions taken depend on the state system is suspending to.
  */
 void pm_client_suspend(const struct pm_proc *proc, unsigned int state)
 {
 	bakery_lock_get(&pm_client_secure_lock);

 	if (state == PM_STATE_SUSPEND_TO_RAM)
 		pm_client_set_wakeup_sources(proc->node_id);

 	/* Set powerdown request */
 	mmio_write_32(FPD_APU_PWRCTL, mmio_read_32(FPD_APU_PWRCTL) |
 		      proc->pwrdn_mask);

 	bakery_lock_release(&pm_client_secure_lock);
 }

 /**
  * pm_client_abort_suspend() - Client-specific abort-suspend actions
  *
  * This function should contain any PU-specific actions
  * required for aborting a prior suspend request
  */
 void pm_client_abort_suspend(void)
 {
 	/* Enable interrupts at processor level (for current cpu) */
 	gicv3_cpuif_enable(plat_my_core_pos());

 	bakery_lock_get(&pm_client_secure_lock);

 	/* Clear powerdown request */
 	mmio_write_32(FPD_APU_PWRCTL, mmio_read_32(FPD_APU_PWRCTL) &
 		      ~primary_proc->pwrdn_mask);

 	bakery_lock_release(&pm_client_secure_lock);
 }

 /**
  * pm_get_cpuid() - get the local cpu ID for a global node ID
  * @nid:	node id of the processor
  *
  * Return: the cpu ID (starting from 0) for the subsystem
  */
 static unsigned int pm_get_cpuid(uint32_t nid)
 {
 	for (size_t i = 0; i < ARRAY_SIZE(pm_procs_all); i++) {
 		if (pm_procs_all[i].node_id == nid)
 			return i;
 	}
 	return UNDEFINED_CPUID;
 }

 /**
  * pm_client_wakeup() - Client-specific wakeup actions
  *
  * This function should contain any PU-specific actions
  * required for waking up another APU core
  */
 void pm_client_wakeup(const struct pm_proc *proc)
 {
 	unsigned int cpuid = pm_get_cpuid(proc->node_id);

 	if (cpuid == UNDEFINED_CPUID)
 		return;

 	bakery_lock_get(&pm_client_secure_lock);

 	/* clear powerdown bit for affected cpu */
 	uint32_t val = mmio_read_32(FPD_APU_PWRCTL);
 	val &= ~(proc->pwrdn_mask);
 	mmio_write_32(FPD_APU_PWRCTL, val);

 	bakery_lock_release(&pm_client_secure_lock);
 }

 /**
  * pm_get_proc() - returns pointer to the proc structure
  * @cpuid:	id of the cpu whose proc struct pointer should be returned
  *
  * Return: pointer to a proc structure if proc is found, otherwise NULL
  */
 const struct pm_proc *pm_get_proc(unsigned int cpuid)
 {
 	if (cpuid < ARRAY_SIZE(pm_procs_all))
 		return &pm_procs_all[cpuid];

 	return NULL;
 }
	/*
	* Copyright (c) 2019-2020, Xilinx, Inc. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	/*
	* APU specific definition of processors in the subsystem as well as functions
	* for getting information about and changing state of the APU.
	*/

	#include <assert.h>
	#include <plat_ipi.h>
	#include <platform_def.h>
	#include <versal_def.h>
	#include <lib/bakery_lock.h>
	#include <lib/mmio.h>
	#include <lib/utils.h>
	#include <drivers/arm/gicv3.h>
	#include <drivers/arm/gic_common.h>
	#include <plat/common/platform.h>
	#include "pm_api_sys.h"
	#include "pm_client.h"

	#define UNDEFINED_CPUID (~0)
	#define IRQ_MAX 142
	#define NUM_GICD_ISENABLER ((IRQ_MAX >> 5) + 1)

	DEFINE_BAKERY_LOCK(pm_client_secure_lock);

	static const struct pm_ipi apu_ipi = {
	.local_ipi_id = IPI_ID_APU,
	.remote_ipi_id = IPI_ID_PMC,
	.buffer_base = IPI_BUFFER_APU_BASE,
	};

	/* Order in pm_procs_all array must match cpu ids */
	static const struct pm_proc pm_procs_all[] = {
	{
	.node_id = XPM_DEVID_ACPU_0,
	.ipi = &apu_ipi,
	.pwrdn_mask = APU_0_PWRCTL_CPUPWRDWNREQ_MASK,
	},
	{
	.node_id = XPM_DEVID_ACPU_1,
	.ipi = &apu_ipi,
	.pwrdn_mask = APU_1_PWRCTL_CPUPWRDWNREQ_MASK,
	}
	};

	const struct pm_proc *primary_proc = &pm_procs_all[0];

	/* Interrupt to PM node index map */
	static enum pm_device_node_idx irq_node_map[IRQ_MAX + 1] = {
	[13] = XPM_NODEIDX_DEV_GPIO,
	[14] = XPM_NODEIDX_DEV_I2C_0,
	[15] = XPM_NODEIDX_DEV_I2C_1,
	[16] = XPM_NODEIDX_DEV_SPI_0,
	[17] = XPM_NODEIDX_DEV_SPI_1,
	[18] = XPM_NODEIDX_DEV_UART_0,
	[19] = XPM_NODEIDX_DEV_UART_1,
	[20] = XPM_NODEIDX_DEV_CAN_FD_0,
	[21] = XPM_NODEIDX_DEV_CAN_FD_1,
	[22] = XPM_NODEIDX_DEV_USB_0,
	[23] = XPM_NODEIDX_DEV_USB_0,
	[24] = XPM_NODEIDX_DEV_USB_0,
	[25] = XPM_NODEIDX_DEV_USB_0,
	[26] = XPM_NODEIDX_DEV_USB_0,
	[37] = XPM_NODEIDX_DEV_TTC_0,
	[38] = XPM_NODEIDX_DEV_TTC_0,
	[39] = XPM_NODEIDX_DEV_TTC_0,
	[40] = XPM_NODEIDX_DEV_TTC_1,
	[41] = XPM_NODEIDX_DEV_TTC_1,
	[42] = XPM_NODEIDX_DEV_TTC_1,
	[43] = XPM_NODEIDX_DEV_TTC_2,
	[44] = XPM_NODEIDX_DEV_TTC_2,
	[45] = XPM_NODEIDX_DEV_TTC_2,
	[46] = XPM_NODEIDX_DEV_TTC_3,
	[47] = XPM_NODEIDX_DEV_TTC_3,
	[48] = XPM_NODEIDX_DEV_TTC_3,
	[56] = XPM_NODEIDX_DEV_GEM_0,
	[57] = XPM_NODEIDX_DEV_GEM_0,
	[58] = XPM_NODEIDX_DEV_GEM_1,
	[59] = XPM_NODEIDX_DEV_GEM_1,
	[60] = XPM_NODEIDX_DEV_ADMA_0,
	[61] = XPM_NODEIDX_DEV_ADMA_1,
	[62] = XPM_NODEIDX_DEV_ADMA_2,
	[63] = XPM_NODEIDX_DEV_ADMA_3,
	[64] = XPM_NODEIDX_DEV_ADMA_4,
	[65] = XPM_NODEIDX_DEV_ADMA_5,
	[66] = XPM_NODEIDX_DEV_ADMA_6,
	[67] = XPM_NODEIDX_DEV_ADMA_7,
	[74] = XPM_NODEIDX_DEV_USB_0,
	[126] = XPM_NODEIDX_DEV_SDIO_0,
	[127] = XPM_NODEIDX_DEV_SDIO_0,
	[128] = XPM_NODEIDX_DEV_SDIO_1,
	[129] = XPM_NODEIDX_DEV_SDIO_1,
	[142] = XPM_NODEIDX_DEV_RTC,
	};

	/**
	* irq_to_pm_node_idx - Get PM node index corresponding to the interrupt number
	* @irq: Interrupt number
	*
	* Return: PM node index corresponding to the specified interrupt
	*/
	static enum pm_device_node_idx irq_to_pm_node_idx(unsigned int irq)
	{
	assert(irq <= IRQ_MAX);
	return irq_node_map[irq];
	}

	/**
	* pm_client_set_wakeup_sources - Set all devices with enabled interrupts as
	* wake sources in the LibPM.
	* @node_id: Node id of processor
	*/
	static void pm_client_set_wakeup_sources(uint32_t node_id)
	{
	uint32_t reg_num;
	uint32_t device_id;
	uint8_t pm_wakeup_nodes_set[XPM_NODEIDX_DEV_MAX];
	uintptr_t isenabler1 = PLAT_VERSAL_GICD_BASE + GICD_ISENABLER + 4;

	zeromem(&pm_wakeup_nodes_set, sizeof(pm_wakeup_nodes_set));

	for (reg_num = 0; reg_num < NUM_GICD_ISENABLER; reg_num++) {
	uint32_t base_irq = reg_num << ISENABLER_SHIFT;
	uint32_t reg = mmio_read_32(isenabler1 + (reg_num << 2));

	if (!reg)
	continue;

	while (reg) {
	enum pm_device_node_idx node_idx;
	uint32_t idx, ret, irq, lowest_set = reg & (-reg);

	idx = __builtin_ctz(lowest_set);
	irq = base_irq + idx;

	if (irq > IRQ_MAX)
	break;

	node_idx = irq_to_pm_node_idx(irq);
	reg &= ~lowest_set;

	if ((node_idx != XPM_NODEIDX_DEV_MIN) &&
	(!pm_wakeup_nodes_set[node_idx])) {
	/* Get device ID from node index */
	device_id = PERIPH_DEVID(node_idx);
	ret = pm_set_wakeup_source(node_id,
	device_id, 1,
	SECURE_FLAG);
	pm_wakeup_nodes_set[node_idx] = !ret;
	}
	}
	}
	}

	/**
	* pm_client_suspend() - Client-specific suspend actions
	*
	* This function should contain any PU-specific actions
	* required prior to sending suspend request to PMU
	* Actions taken depend on the state system is suspending to.
	*/
	void pm_client_suspend(const struct pm_proc *proc, unsigned int state)
	{
	bakery_lock_get(&pm_client_secure_lock);

	if (state == PM_STATE_SUSPEND_TO_RAM)
	pm_client_set_wakeup_sources(proc->node_id);

	/* Set powerdown request */
	mmio_write_32(FPD_APU_PWRCTL, mmio_read_32(FPD_APU_PWRCTL) \|
	proc->pwrdn_mask);

	bakery_lock_release(&pm_client_secure_lock);
	}

	/**
	* pm_client_abort_suspend() - Client-specific abort-suspend actions
	*
	* This function should contain any PU-specific actions
	* required for aborting a prior suspend request
	*/
	void pm_client_abort_suspend(void)
	{
	/* Enable interrupts at processor level (for current cpu) */
	gicv3_cpuif_enable(plat_my_core_pos());

	bakery_lock_get(&pm_client_secure_lock);

	/* Clear powerdown request */
	mmio_write_32(FPD_APU_PWRCTL, mmio_read_32(FPD_APU_PWRCTL) &
	~primary_proc->pwrdn_mask);

	bakery_lock_release(&pm_client_secure_lock);
	}

	/**
	* pm_get_cpuid() - get the local cpu ID for a global node ID
	* @nid: node id of the processor
	*
	* Return: the cpu ID (starting from 0) for the subsystem
	*/
	static unsigned int pm_get_cpuid(uint32_t nid)
	{
	for (size_t i = 0; i < ARRAY_SIZE(pm_procs_all); i++) {
	if (pm_procs_all[i].node_id == nid)
	return i;
	}
	return UNDEFINED_CPUID;
	}

	/**
	* pm_client_wakeup() - Client-specific wakeup actions
	*
	* This function should contain any PU-specific actions
	* required for waking up another APU core
	*/
	void pm_client_wakeup(const struct pm_proc *proc)
	{
	unsigned int cpuid = pm_get_cpuid(proc->node_id);

	if (cpuid == UNDEFINED_CPUID)
	return;

	bakery_lock_get(&pm_client_secure_lock);

	/* clear powerdown bit for affected cpu */
	uint32_t val = mmio_read_32(FPD_APU_PWRCTL);
	val &= ~(proc->pwrdn_mask);
	mmio_write_32(FPD_APU_PWRCTL, val);

	bakery_lock_release(&pm_client_secure_lock);
	}

	/**
	* pm_get_proc() - returns pointer to the proc structure
	* @cpuid: id of the cpu whose proc struct pointer should be returned
	*
	* Return: pointer to a proc structure if proc is found, otherwise NULL
	*/
	const struct pm_proc *pm_get_proc(unsigned int cpuid)
	{
	if (cpuid < ARRAY_SIZE(pm_procs_all))
	return &pm_procs_all[cpuid];

	return NULL;
	}