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arm-trusted-firmware/plat/imx/imx8ulp/upower/upower_api.c
Jacky Bai fcd41e8692 feat(imx8ulp): add i.MX8ULP basic support 
Add the basic support for i.MX8ULP.

The i.MX 8ULP family of processors features NXP’s advanced
implementation of the dual Arm Cortex-A35 cores alongside
an Arm Cortex-M33. This combined architecture enables the
device to run a rich operating system (such as Linux) on
the Cortex-A35 core and an RTOS (such as FreeRTOS) on the
Cortex-M33 core. It also includes a Cadence Tensilica Fusion
DSP for low-power audio and a HiFi4 DSP for advanced audio
and machine learning applications.

Signed-off-by: Peng Fan <peng.fan@nxp.com>
Signed-off-by: Ye Li <ye.li@nxp.com>
Signed-off-by: Jacky Bai <ping.bai@nxp.com>
Change-Id: I12df622b95960bcdf7da52e4c66470a700690e36
2024-02-27 14:29:53 +08:00

3095 lines
101 KiB
C
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/* SPDX-License-Identifier: BSD-3-Clause */
/**
* Copyright 2019-2024 NXP
*
* KEYWORDS: micro-power uPower driver API
*/
#include <string.h>
#include "upower_api.h"
#include "upower_soc_defs.h"
/* ---------------------------------------------------------------
* Common Macros
* ---------------------------------------------------------------
*/
/* tests Service Group busy */
#define UPWR_SG_BUSY(sg) ((sg_busy & (1U << (sg))) == 1U)
/* install user callback for the Service Group */
#define UPWR_USR_CALLB(sg, cb) { user_callback[(sg)] = (cb); }
/* fills up common message header info */
#define UPWR_MSG_HDR(hdr, sg, fn) { \
(hdr).domain = (uint32_t)pwr_domain; \
(hdr).srvgrp = (sg); \
(hdr).function = (fn); }
/* ---------------------------------------------------------------
* Common Data Structures
* ---------------------------------------------------------------
*/
static soc_domain_t pwr_domain;
static upwr_code_vers_t fw_rom_version;
static upwr_code_vers_t fw_ram_version;
static uint32_t fw_launch_option;
/* shared memory buffers */
#define UPWR_API_BUFFER_SIZE (MAX_SG_EXCEPT_MEM_SIZE + \
MAX_SG_PWRMGMT_MEM_SIZE + MAX_SG_VOLTM_MEM_SIZE)
/* service group shared mem buffer pointers */
static void *sh_buffer[UPWR_SG_COUNT];
/* Callbacks registered for each service group :
*
* NULL means no callback is registered;
* for sgrp_callback, it also means the service group is
* free to receive a new request.
*/
static upwr_callb user_callback[UPWR_SG_COUNT];
static UPWR_RX_CALLB_FUNC_T sgrp_callback[UPWR_SG_COUNT];
/* request data structures for each service group */
/* message waiting for TX */
static upwr_down_max_msg sg_req_msg[UPWR_SG_COUNT];
/* waiting message size */
static unsigned int sg_req_siz[UPWR_SG_COUNT];
/* response msg */
static upwr_up_max_msg sg_rsp_msg[UPWR_SG_COUNT];
/* response msg size */
static unsigned int sg_rsp_siz[UPWR_SG_COUNT];
/* tx pending status for each (1 bit per service group) */
static volatile uint32_t sg_tx_pend;
/* serv.group of current ongoing Tx, if any */
static volatile upwr_sg_t sg_tx_curr;
/* service group busy status, only for this domain (MU index 0) */
/* SG bit = 1 if group is busy with a request */
static volatile uint32_t sg_busy;
/* OS-dependent memory allocation function */
static upwr_malloc_ptr_t os_malloc;
/* OS-dependent pointer->physical address conversion function */
static upwr_phyadr_ptr_t os_ptr2phy;
/* OS-dependent function to lock critical code */
static upwr_lock_ptr_t os_lock;
/* pointer to MU structure */
static struct MU_t *mu;
/*
* indicates that a transmission was done and is pending; this
* bit is necessary because the Tx and Rx interrupts are ORed
* together, and there is no way of telling if only Rx interrupt
* or both occurred just by looking at the MU status registers
*/
static uint32_t mu_tx_pend;
static UPWR_TX_CALLB_FUNC_T mu_tx_callb;
static UPWR_RX_CALLB_FUNC_T mu_rx_callb;
#define UPWR_API_INIT_WAIT (0U) /* waiting for ROM firmware initialization */
#define UPWR_API_INITLZED (1U) /* ROM firmware initialized */
#define UPWR_API_START_WAIT (2U) /* waiting for start services */
#define UPWR_API_SHUTDOWN_WAIT (3U) /* waiting for shutdown */
#define UPWR_API_READY (4U) /* ready to receive service requests */
volatile upwr_api_state_t api_state;
/* default pointer->physical address conversion, returns the same address */
static void *ptr2phys(const void *ptr)
{
return (void *)ptr;
}
/* ---------------------------------------------------------------
* SHARED MEMORY MANAGEMENT
* --------------------------------------------------------------
*/
/*
* upwr_ptr2offset() - converts a pointer (casted to uint64_t) to an
* address offset from the shared memory start. If it does not point
* to a shared memory location, the structure pointed is copied to a
* buffer in the shared memory, and the buffer offset is returned.
* The 2nd argument is the service group to which the buffer belongs;
* The 3rd argument is the size of structure to be copied. The 4th argument
* is an offset to apply to the copy destination address. The 5th argument
* is ptr before the conversion to physical address. 2nd, 3rd. 4th and 5th
* arguments are not used if the 1st one points to a location inside the
* shared memory.
*/
static uint32_t upwr_ptr2offset(unsigned long ptr,
upwr_sg_t sg,
size_t siz,
size_t offset,
const void *vptr)
{
if ((ptr >= UPWR_DRAM_SHARED_BASE_ADDR) &&
((ptr - UPWR_DRAM_SHARED_BASE_ADDR) < UPWR_DRAM_SHARED_SIZE)) {
return (uint32_t)(ptr - UPWR_DRAM_SHARED_BASE_ADDR);
}
/* pointer is outside the shared memory, copy the struct to buffer */
(void)memcpy((void *)(offset + (char *)sh_buffer[sg]), (void *)vptr, siz);
return (uint32_t)((unsigned long)sh_buffer[sg] + offset - UPWR_DRAM_SHARED_BASE_ADDR);
}
/*
* ---------------------------------------------------------------
* INTERRUPTS AND CALLBACKS
* Service-group specific callbacks are in their own sections
* --------------------------------------------------------------
*/
/*
* upwr_lock()- locks (lock=1) or unlocks (lock=0) a critical code section;
* for now it only needs to protect a portion of the code from being
* interrupted by the MU.
*/
static void upwr_lock(int lock)
{
if (os_lock != NULL) {
os_lock(lock);
}
}
/* upwr_exp_isr()- handles the exception interrupt from uPower */
static void upwr_exp_isr(void)
{
}
/* upwr_copy2tr prototype; function definition in auxiliary function section */
void upwr_copy2tr(struct MU_t *local_mu, const uint32_t *msg, unsigned int size);
#define UPWR_MU_TSR_EMPTY ((uint32_t)((1UL << UPWR_MU_MSG_SIZE) - 1UL))
/* upwr_txrx_isr()- handles both the Tx and Rx MU interrupts */
void upwr_txrx_isr(void)
{
/* Tx pending and TX register empty */
if ((mu_tx_pend != 0UL) && (mu->TSR.R == UPWR_MU_TSR_EMPTY)) {
mu_tx_pend = 0UL;
/* disable the tx interrupts */
mu->TCR.R = 0U;
/* urgency flag off, in case it was set */
mu->FCR.B.F0 = 0U;
if (mu_tx_callb != NULL) {
mu_tx_callb();
}
}
/* RX ISR occurred */
if (mu->RSR.R != 0UL) {
/* disable the interrupt until data is read */
mu->RCR.R = 0U;
if (mu_rx_callb != NULL) {
mu_rx_callb();
}
}
}
/**
* upwr_next_req() - sends the next pending service request message, if any.
*
* Called upon MU Tx interrupts, it checks if there is any service request
* pending amongst the service groups, and sends the request if needed.
*
* Context: no sleep, no locks taken/released.
* Return: none (void).
*/
static void upwr_next_req(void)
{
upwr_sg_t sg = (upwr_sg_t)0U;
/* no lock needed here, this is called from an MU ISR */
sg_tx_pend &= ~((uint32_t)1UL << sg_tx_curr); /* no longer pending */
if (sg_tx_pend == 0U) {
return; /* no other pending */
}
/* find the next one pending */
for (uint32_t mask = 1UL; mask < (1UL << UPWR_SG_COUNT); mask = mask << 1UL) {
if ((sg_tx_pend & mask) != 0U) {
break;
}
sg = (upwr_sg_t)(sg + 1U);
}
sg_tx_curr = sg;
if (upwr_tx((uint32_t *)&sg_req_msg[sg], sg_req_siz[sg], upwr_next_req) < 0) {
return; /* leave the Tx pending */
}
}
/**
* upwr_mu_int_callback() - general MU interrupt callback.
*
* Called upon MU Rx interrupts, it calls the Service Group-specific callback,
* if any registered, based on the service group field in the received message.
* Otherwise, calls the user callback, if any registered.
*
* Context: no sleep, no locks taken/released.
* Return: none (void).
*/
static void upwr_mu_int_callback(void)
{
upwr_sg_t sg; /* service group number */
UPWR_RX_CALLB_FUNC_T sg_callb; /* service group callback */
upwr_up_max_msg rxmsg = {0};
unsigned int size; /* in words */
if (upwr_rx((char *)&rxmsg, &size) < 0) {
return;
}
sg = (upwr_sg_t)rxmsg.hdr.srvgrp;
/* copy msg to the service group buffer */
msg_copy((char *)&sg_rsp_msg[sg], (char *)&rxmsg, size);
sg_rsp_siz[sg] = size;
/* clear the service group busy status */
sg_busy &= ~(1UL << sg); /* no lock needed here, we're in the MU ISR */
sg_callb = sgrp_callback[sg];
if (sg_callb == NULL) {
upwr_callb user_callb = user_callback[sg];
/* no service group callback; call the user callback if any */
if (user_callb == NULL) {
goto done; /* no user callback */
}
/* make the user callback */
user_callb(sg, rxmsg.hdr.function,
(upwr_resp_t)rxmsg.hdr.errcode,
(size == 2U) ? rxmsg.word2 : rxmsg.hdr.ret);
goto done;
}
/*
* finally make the group callback. don't uninstall the group
* callback, it is permanent.
*/
sg_callb();
done:
if (rxmsg.hdr.errcode == UPWR_RESP_SHUTDOWN) { /* shutdown error: */
/*
* change the API state automatically. so new requests
* are rejected by the API immediately
*/
api_state = UPWR_API_INITLZED;
}
}
/**
* upwr_srv_req() - sends a service request message.
* @sg: message service group.
* @msg: pointer to the message
* @size: message size in 32-bit words.
*
* The message is sent right away if possible, or gets pending to be sent later.
* If pending, the message is stored in sg_req_msg and will be sent when the
* MU transmission buffer is clear and there are no other pending messages
* from higher priority service groups.
*
* This is an auxiliary function used by the rest of the API calls.
* It is normally not called by the driver code, unless maybe for test purposes.
*
* Context: no sleep, no locks taken/released.
* Return: none (void)
*/
static void upwr_srv_req(upwr_sg_t sg,
uint32_t *msg,
unsigned int size)
{
int rc;
upwr_lock(1);
sg_busy |= (uint32_t)1U << sg;
upwr_lock(0);
rc = upwr_tx(msg, size, upwr_next_req);
if (rc < 0) {
/* queue full, make the transmission pending */
msg_copy((char *)&sg_req_msg[sg], (char *)msg, size);
sg_req_siz[sg] = size;
upwr_lock(1);
sg_tx_curr = sg;
sg_tx_pend |= (uint32_t)1U << sg;
upwr_lock(0);
return;
}
}
/**---------------------------------------------------------------
* INITIALIZATION, CONFIGURATION
*
* A reference uPower initialization sequence goes as follows:
*
* 1. host CPU calls upwr_init.
* 2. (optional) host checks the ROM version and SoC code calling upwr_vers(...)
* and optionally performs any configuration or workaround accordingly.
* 3. host CPU calls upwr_start to start the uPower services, passing a
* service option number.
* If no RAM code is loaded or it has no service options, the launch option
* number passed must be 0, which will start the services available in ROM.
* upwr_start also receives a pointer to a callback called by the API
* when the firmware is ready to receive service requests.
* The callback may be replaced by polling, calling upwr_req_status in a loop
* or upwr_poll_req_status; in this case the callback pointer may be NULL.
* A host may call upwr_start even if the services were already started by
* any host: if the launch option is the same, the response will be ok,
* but will indicate error if the services were already started with a
* different launch option.
* 4. host waits for the callback calling, or polling finishing;
* if no error is returned, it can start making service calls using the API.
*
* Variations on that reference sequence are possible:
* - the uPower services can be started using the ROM code only, which includes
* the basic Power Management services, among others, with launch option
* number = 0.
* The code RAM can be loaded while these services are running and,
* when the loading is done, the services can be re-started with these 2
* requests executed in order: upwr_xcp_shutdown and upwr_start,
* using the newly loaded RAM code (launch option > 0).
*
* NOTE: the initialization call upwr_init is not effective and
* returns error when called after the uPower services are started.
*/
/**
* upwr_start_callb() - internal callback for the Rx message from uPower
* that indicates the firmware is ready to receive the start commands.
* It calls the user callbacks registered in the upwr_start_boot and upwr_start
* call.
*/
void upwr_start_callb(void)
{
switch (api_state) {
case UPWR_API_START_WAIT: {
upwr_rdy_callb start_callb = (upwr_rdy_callb)user_callback[UPWR_SG_EXCEPT];
upwr_ready_msg *msg = (upwr_ready_msg *)&sg_rsp_msg[UPWR_SG_EXCEPT];
fw_ram_version.soc_id = fw_rom_version.soc_id;
fw_ram_version.vmajor = msg->args.vmajor;
fw_ram_version.vminor = msg->args.vminor;
fw_ram_version.vfixes = msg->args.vfixes;
/*
* vmajor == vminor == vfixes == 0 indicates start error
* in this case, go back to the INITLZED state
*/
if ((fw_ram_version.vmajor != 0U) ||
(fw_ram_version.vminor != 0U) ||
(fw_ram_version.vfixes != 0U)) {
api_state = UPWR_API_READY;
/*
* initialization is over:
* uninstall the user callback just in case
*/
UPWR_USR_CALLB(UPWR_SG_EXCEPT, NULL);
if (fw_launch_option == 0U) {
/*
* launched ROM firmware:
* RAM fw versions must be all 0s
*/
fw_ram_version.vmajor = 0U;
fw_ram_version.vminor = 0U;
fw_ram_version.vfixes = 0U;
}
} else {
api_state = UPWR_API_INITLZED;
}
start_callb(msg->args.vmajor, msg->args.vminor, msg->args.vfixes);
}
break;
case UPWR_API_SHUTDOWN_WAIT: {
upwr_callb user_callb = (upwr_callb)user_callback[UPWR_SG_EXCEPT];
upwr_shutdown_msg *msg = (upwr_shutdown_msg *)&sg_rsp_msg[UPWR_SG_EXCEPT];
if ((upwr_resp_t)msg->hdr.errcode == UPWR_RESP_OK) {
api_state = UPWR_API_INITLZED;
}
if (user_callb != NULL) {
user_callb(UPWR_SG_EXCEPT, UPWR_XCP_SHUTDOWN,
(upwr_resp_t)msg->hdr.errcode, 0U);
}
}
break;
case UPWR_API_READY:
{
upwr_callb user_callb = (upwr_callb)user_callback[UPWR_SG_EXCEPT];
upwr_up_max_msg *msg = (upwr_up_max_msg *)&sg_rsp_msg[UPWR_SG_EXCEPT];
if (user_callb != NULL) {
user_callb(UPWR_SG_EXCEPT, msg->hdr.function,
(upwr_resp_t)msg->hdr.errcode,
(int)((sg_rsp_siz[UPWR_SG_EXCEPT] == 2U) ?
msg->word2 : msg->hdr.ret));
}
}
break;
default:
break;
}
}
/**
* upwr_init() - API initialization; must be the first API call after reset.
* @domain: SoC-dependent CPU domain id; identifier used by the firmware in
* many services. Defined by SoC-dependent type soc_domain_t found in
* upower_soc_defs.h.
* @muptr: pointer to the MU instance.
* @mallocptr: pointer to the memory allocation function
* @physaddrptr: pointer to the function to convert pointers to
* physical addresses. If NULL, no conversion is made (pointer=physical address)
* @isrinstptr: pointer to the function to install the uPower ISR callbacks;
* the function receives the pointers to the MU tx/rx and Exception ISRs
* callbacks, which must be called from the actual system ISRs.
* The function pointed by isrinstptr must also enable the interrupt at the
* core/interrupt controller, but must not enable the interrupt at the MU IP.
* The system ISRs are responsible for dealing with the interrupt controller,
* performing any other context save/restore, and any other housekeeping.
* @lockptr: pointer to a function that prevents MU interrupts (if argrument=1)
* or allows it (if argument=0). The API calls this function to make small
* specific code portions thread safe. Only MU interrupts must be avoided,
* the code may be suspended for other reasons.
* If no MU interrupts can happen during the execution of an API call or
* callback, even if enabled, for some other reason (e.g. interrupt priority),
* then this argument may be NULL.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if failed to allocate memory, or use some other resource.
* -2 if any argument is invalid.
* -3 if failed to send the ping message.
* -4 if failed to receive the initialization message, or was invalid
*/
int upwr_init(soc_domain_t domain, struct MU_t *muptr,
const upwr_malloc_ptr_t mallocptr,
const upwr_phyadr_ptr_t phyadrptr,
const upwr_inst_isr_ptr_t isrinstptr,
const upwr_lock_ptr_t lockptr)
{
uint32_t j;
upwr_sg_t sg; /* service group number */
unsigned int size;
unsigned long dom_buffer_base = (domain == RTD_DOMAIN) ? UPWR_API_BUFFER_BASE :
((UPWR_API_BUFFER_ENDPLUS + UPWR_API_BUFFER_BASE) / 2U);
upwr_init_msg *msg = (upwr_init_msg *)&sg_rsp_msg[UPWR_SG_EXCEPT];
mu = muptr;
/*
* Disable tx and rx interrupts in case not called
* 1st time after reset
*/
mu->TCR.R = mu->RCR.R = 0U;
os_malloc = mallocptr;
os_ptr2phy = (phyadrptr == (upwr_phyadr_ptr_t)NULL) ? ptr2phys : phyadrptr;
os_lock = lockptr;
api_state = UPWR_API_INIT_WAIT;
sg_busy = 0UL;
pwr_domain = domain;
/* initialize the versions, in case they are polled */
fw_rom_version.soc_id = 0U;
fw_rom_version.vmajor = 0U;
fw_rom_version.vminor = 0U;
fw_rom_version.vfixes = 0U;
fw_ram_version.soc_id = 0U;
fw_ram_version.vmajor = 0U;
fw_ram_version.vminor = 0U;
fw_ram_version.vfixes = 0U;
mu_tx_pend = (uint32_t)0U;
sg_tx_pend = (uint32_t)0U;
sg_tx_curr = UPWR_SG_COUNT; /* means none here */
sh_buffer[UPWR_SG_EXCEPT] = (void *)(unsigned long)dom_buffer_base;
sh_buffer[UPWR_SG_PWRMGMT] = (void *)(unsigned long)(dom_buffer_base +
MAX_SG_EXCEPT_MEM_SIZE);
sh_buffer[UPWR_SG_DELAYM] = NULL;
sh_buffer[UPWR_SG_VOLTM] = (void *)(unsigned long)(dom_buffer_base +
MAX_SG_EXCEPT_MEM_SIZE + MAX_SG_PWRMGMT_MEM_SIZE);
sh_buffer[UPWR_SG_CURRM] = NULL;
sh_buffer[UPWR_SG_TEMPM] = NULL;
sh_buffer[UPWR_SG_DIAG] = NULL;
/* (no buffers service groups other than xcp and pwm for now) */
for (j = 0; j < UPWR_SG_COUNT; j++) {
user_callback[j] = NULL;
/* service group Exception gets the initialization callbacks */
sgrp_callback[j] = (j == UPWR_SG_EXCEPT) ? upwr_start_callb : NULL;
/* response messages with an initial consistent content */
sg_rsp_msg[j].hdr.errcode = UPWR_RESP_SHUTDOWN;
}
/* init message already received, assume takss are running on upower */
if (mu->FSR.B.F0 != 0U) {
/* send a ping message down to get the ROM version back */
upwr_xcp_ping_msg ping_msg = {0};
ping_msg.hdr.domain = pwr_domain;
ping_msg.hdr.srvgrp = UPWR_SG_EXCEPT;
ping_msg.hdr.function = UPWR_XCP_PING;
if (mu->RSR.B.RF0 != 0U) { /* first clean any Rx message left over */
(void)upwr_rx((char *)msg, &size);
}
/* wait any TX left over to be sent */
while (mu->TSR.R != UPWR_MU_TSR_EMPTY) {
}
/*
* now send the ping message;
* do not use upwr_tx, which needs API initialized;
* just write to the MU TR register(s)
*/
mu->FCR.B.F0 = 1U; /* flag urgency status */
upwr_copy2tr(mu, (uint32_t *)&ping_msg, sizeof(ping_msg) / 4U);
}
do {
/*
* poll for the MU Rx status: wait for an init message, either
* 1st sent from uPower after reset or as a response to a ping
*/
while (mu->RSR.B.RF0 == 0U) {
}
/* urgency status off, in case it was set */
mu->FCR.B.F0 = 0U;
if (upwr_rx((char *)msg, &size) < 0) {
return -4;
}
if (size != (sizeof(upwr_init_msg) / 4U)) {
if (mu->FSR.B.F0 != 0U) {
continue; /* discard left over msg */
} else {
return -4;
}
}
sg = (upwr_sg_t)msg->hdr.srvgrp;
if (sg != UPWR_SG_EXCEPT) {
if (mu->FSR.B.F0 != 0U) {
continue; /* discard left over msg */
} else {
return -4;
}
}
if ((upwr_xcp_f_t)msg->hdr.function != UPWR_XCP_INIT) {
if (mu->FSR.B.F0 != 0U) {
continue; /* discard left over msg */
} else {
return -4;
}
}
break;
} while (true);
fw_rom_version.soc_id = msg->args.soc;
fw_rom_version.vmajor = msg->args.vmajor;
fw_rom_version.vminor = msg->args.vminor;
fw_rom_version.vfixes = msg->args.vfixes;
if (upwr_rx_callback(upwr_mu_int_callback) < 0) {
/* catastrophic error, but is it possible to happen? */
return -1;
}
mu_tx_callb = NULL; /* assigned on upwr_tx */
/* install the ISRs and enable the interrupts */
isrinstptr(upwr_txrx_isr, upwr_exp_isr);
/* enable only RR[0] receive interrupt */
mu->RCR.R = 1U;
api_state = UPWR_API_INITLZED;
return 0;
}
/**
* upwr_start() - Starts the uPower services.
* @launchopt: a number to select between multiple launch options,
* that may define, among other things, which services will be started,
* or which services implementations, features etc.
* launchopt = 0 selects a subset of services implemented in ROM;
* any other number selects service sets implemented in RAM, launched
* by the firmware function ram_launch; if an invalid launchopt value is passed,
* no services are started, and the callback returns error (see below).
* @rdycallb: pointer to the callback to be called when the uPower is ready
* to receive service requests. NULL if no callback needed.
* The callback receives as arguments the RAM firmware version numbers.
* If all 3 numbers (vmajor, vminor, vfixes) are 0, that means the
* service launching failed.
* Firmware version numbers will be the same as ROM if launchopt = 0,
* selecting the ROM services.
*
* upwr_start can be called by any domain even if the services are already
* started: it has no effect, returning success, if the launch option is the
* same as the one that actually started the service, and returns error if
* called with a different option.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded or
* not.
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_EXCEPT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if a resource failed,
* -2 if the domain passed is the same as the caller,
* -3 if called in an invalid API state
*/
int upwr_start(uint32_t launchopt, const upwr_rdy_callb rdycallb)
{
upwr_start_msg txmsg = {0};
if (api_state != UPWR_API_INITLZED) {
return -3;
}
UPWR_USR_CALLB(UPWR_SG_EXCEPT, (upwr_callb)rdycallb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_EXCEPT, UPWR_XCP_START);
txmsg.hdr.arg = fw_launch_option = launchopt;
if (upwr_tx((uint32_t *)&txmsg, sizeof(txmsg) / 4U, NULL) < 0) {
/* catastrophic error, but is it possible to happen? */
return -1;
}
api_state = UPWR_API_START_WAIT;
return 0;
}
/**---------------------------------------------------------------
* EXCEPTION SERVICE GROUP
*/
/**
* upwr_xcp_config() - Applies general uPower configurations.
* @config: pointer to the uPower SoC-dependent configuration struct
* upwr_xcp_config_t defined in upower_soc_defs.h. NULL may be passed, meaning
* a request to read the configuration, in which case it appears in the callback
* argument ret, or can be pointed by argument retptr in the upwr_req_status and
* upwr_poll_req_status calls, casted to upwr_xcp_config_t.
* @callb: pointer to the callback to be called when the uPower has finished
* the configuration, or NULL if no callback needed (polling used instead).
*
* Some configurations are targeted for a specific domain (see the struct
* upwr_xcp_config_t definition in upower_soc_defs.h); this call has implicit
* domain target (the same domain from which is called).
*
* The return value is always the current configuration value, either in a
* read-only request (config = NULL) or after setting a new configuration
* (non-NULL config).
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded or
* not.
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_EXCEPT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
*/
int upwr_xcp_config(const upwr_xcp_config_t *config, const upwr_callb callb)
{
upwr_xcp_config_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_EXCEPT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_EXCEPT, callb);
if (config == NULL) {
txmsg.hdr.arg = 1U; /* 1= read, txmsg.word2 ignored */
} else {
txmsg.hdr.arg = 0U; /* 1= write */
txmsg.word2 = config->R;
}
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_EXCEPT, UPWR_XCP_CONFIG);
upwr_srv_req(UPWR_SG_EXCEPT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_xcp_sw_alarm() - Makes uPower issue an alarm interrupt to given domain.
* @domain: identifier of the domain to alarm. Defined by SoC-dependent type
* soc_domain_t found in upower_soc_defs.h.
* @code: alarm code. Defined by SoC-dependent type upwr_alarm_t found in
* upower_soc_defs.h.
* @callb: pointer to the callback to be called when the uPower has finished
* the alarm, or NULL if no callback needed (polling used instead).
*
* The function requests the uPower to issue an alarm of the given code as if
* it had originated internally. This service is useful mainly to test the
* system response to such alarms, or to make the system handle a similar alarm
* situation detected externally to uPower.
*
* The system ISR/code handling the alarm may retrieve the alarm code by calling
* the auxiliary function upwr_alarm_code.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded or
* not.
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_EXCEPT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
*/
int upwr_xcp_sw_alarm(soc_domain_t domain,
upwr_alarm_t code,
const upwr_callb callb)
{
upwr_xcp_swalarm_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_EXCEPT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_EXCEPT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_EXCEPT, UPWR_XCP_SW_ALARM);
txmsg.hdr.domain = (uint32_t)domain;
txmsg.hdr.arg = (uint32_t)code;
upwr_srv_req(UPWR_SG_EXCEPT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_xcp_set_ddr_retention() - M33/A35 can use this API to set/clear ddr retention
* @domain: identifier of the caller domain.
* soc_domain_t found in upower_soc_defs.h.
* @enable: true, means that set ddr retention, false clear ddr retention.
* @callb: NULL
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_EXCEPT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
*/
int upwr_xcp_set_ddr_retention(soc_domain_t domain,
uint32_t enable,
const upwr_callb callb)
{
upwr_xcp_ddr_retn_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_EXCEPT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_EXCEPT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_EXCEPT, UPWR_XCP_SET_DDR_RETN);
txmsg.hdr.domain = (uint32_t)domain;
txmsg.hdr.arg = (uint32_t)enable;
upwr_srv_req(UPWR_SG_EXCEPT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_xcp_set_mipi_dsi_ena() - M33/A35 can use this API to set/clear mipi dsi ena
* @domain: identifier of the caller domain.
* soc_domain_t found in upower_soc_defs.h.
* @enable: true, means that set ddr retention, false clear ddr retention.
* @callb: NULL
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_EXCEPT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
*/
int upwr_xcp_set_mipi_dsi_ena(soc_domain_t domain,
uint32_t enable,
const upwr_callb callb)
{
upwr_xcp_set_mipi_dsi_ena_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_EXCEPT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_EXCEPT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_EXCEPT, UPWR_XCP_SET_MIPI_DSI_ENA);
txmsg.hdr.domain = (uint32_t)domain;
txmsg.hdr.arg = (uint32_t)enable;
upwr_srv_req(UPWR_SG_EXCEPT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_xcp_get_mipi_dsi_ena() - M33/A35 can use this API to get mipi dsi ena status
* @domain: identifier of the caller domain.
* soc_domain_t found in upower_soc_defs.h.
* @callb: NULL
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_EXCEPT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
*/
int upwr_xcp_get_mipi_dsi_ena(soc_domain_t domain, const upwr_callb callb)
{
upwr_xcp_get_mipi_dsi_ena_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_EXCEPT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_EXCEPT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_EXCEPT, UPWR_XCP_GET_MIPI_DSI_ENA);
txmsg.hdr.domain = (uint32_t)domain;
upwr_srv_req(UPWR_SG_EXCEPT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_xcp_set_osc_mode() - M33/A35 can use this API to set uPower OSC mode
* @domain: identifier of the caller domain.
* soc_domain_t found in upower_soc_defs.h.
* @osc_mode, 0 means low frequency, not 0 means high frequency.
* @callb: NULL
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_EXCEPT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
*/
int upwr_xcp_set_osc_mode(soc_domain_t domain,
uint32_t osc_mode,
const upwr_callb callb)
{
upwr_xcp_set_osc_mode_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_EXCEPT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_EXCEPT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_EXCEPT, UPWR_XCP_SET_OSC_MODE);
txmsg.hdr.domain = (uint32_t)domain;
txmsg.hdr.arg = (uint32_t)osc_mode;
upwr_srv_req(UPWR_SG_EXCEPT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_xcp_set_rtd_use_ddr() - M33 call this API to inform uPower, M33 is using ddr
* @domain: identifier of the caller domain.
* soc_domain_t found in upower_soc_defs.h.
* @is_use_ddr: not 0, true, means that RTD is using ddr. 0, false, means that, RTD
* is not using ddr.
* @callb: NULL
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_EXCEPT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
*/
int upwr_xcp_set_rtd_use_ddr(soc_domain_t domain,
uint32_t is_use_ddr,
const upwr_callb callb)
{
upwr_xcp_rtd_use_ddr_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_EXCEPT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_EXCEPT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_EXCEPT, UPWR_XCP_SET_RTD_USE_DDR);
txmsg.hdr.domain = (uint32_t)domain;
txmsg.hdr.arg = (uint32_t)is_use_ddr;
upwr_srv_req(UPWR_SG_EXCEPT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_xcp_set_rtd_apd_llwu() - M33/A35 can use this API to set/clear rtd_llwu apd_llwu
* @domain: set which domain (RTD_DOMAIN, APD_DOMAIN) LLWU.
* soc_domain_t found in upower_soc_defs.h.
* @enable: true, means that set rtd_llwu or apd_llwu, false clear rtd_llwu or apd_llwu.
* @callb: NULL
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_EXCEPT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
*/
int upwr_xcp_set_rtd_apd_llwu(soc_domain_t domain,
uint32_t enable,
const upwr_callb callb)
{
upwr_xcp_rtd_apd_llwu_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_EXCEPT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_EXCEPT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_EXCEPT, UPWR_XCP_SET_RTD_APD_LLWU);
txmsg.hdr.domain = (uint32_t)domain;
txmsg.hdr.arg = (uint32_t)enable;
upwr_srv_req(UPWR_SG_EXCEPT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_xcp_shutdown() - Shuts down all uPower services and power mode tasks.
* @callb: pointer to the callback to be called when the uPower has finished
* the shutdown, or NULL if no callback needed
* (polling used instead).
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded or
* not.
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_EXCEPT as the service group argument.
*
* At the callback the uPower/API is back to initialization/start-up phase,
* so service request calls return error.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
*/
int upwr_xcp_shutdown(const upwr_callb callb)
{
upwr_xcp_shutdown_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_EXCEPT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_EXCEPT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_EXCEPT, UPWR_XCP_SHUTDOWN);
upwr_srv_req(UPWR_SG_EXCEPT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
api_state = UPWR_API_SHUTDOWN_WAIT;
return 0;
}
/**
* upwr_xcp_i2c_access() - Performs an access through the uPower I2C interface.
* @addr: I2C slave address, up to 10 bits.
* @data_size: determines the access direction and data size in bytes, up to 4;
* negetive data_size determines a read access with size -data_size;
* positive data_size determines a write access with size data_size;
* data_size=0 is invalid, making the service return error UPWR_RESP_BAD_REQ.
* @subaddr_size: size of the sub-address in bytes, up to 4; if subaddr_size=0,
* no subaddress is used.
* @subaddr: sub-address, only used if subaddr_size > 0.
* @wdata: write data, up to 4 bytes; ignored if data_size < 0 (read)
* @callb: pointer to the callback to be called when the uPower has finished
* the access, or NULL if no callback needed
* (polling used instead).
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded or
* not.
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_EXCEPT as the service group argument.
*
* The service performs a read (data_size < 0) or a write (data_size > 0) of
* up to 4 bytes on the uPower I2C interface. The data read from I2C comes via
* the callback argument ret, or written to the variable pointed by retptr,
* if polling is used (calls upwr_req_status or upwr_poll_req_status).
* ret (or *retptr) also returns the data written on writes.
*
* Sub-addressing is supported, with sub-address size determined by the argument
* subaddr_size, up to 4 bytes. Sub-addressing is not used if subaddr_size=0.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
*/
int upwr_xcp_i2c_access(uint16_t addr,
int8_t data_size,
uint8_t subaddr_size,
uint32_t subaddr,
uint32_t wdata,
const upwr_callb callb)
{
unsigned long ptrval = (unsigned long)sh_buffer[UPWR_SG_EXCEPT];
upwr_i2c_access *i2c_acc_ptr = (upwr_i2c_access *)ptrval;
upwr_pwm_pmiccfg_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_EXCEPT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_EXCEPT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_EXCEPT, UPWR_XCP_I2C);
i2c_acc_ptr->addr = addr;
i2c_acc_ptr->subaddr = subaddr;
i2c_acc_ptr->subaddr_size = subaddr_size;
i2c_acc_ptr->data = wdata;
i2c_acc_ptr->data_size = data_size;
txmsg.ptr = upwr_ptr2offset(ptrval,
UPWR_SG_EXCEPT,
(size_t)sizeof(upwr_i2c_access),
0U,
i2c_acc_ptr);
upwr_srv_req(UPWR_SG_EXCEPT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**---------------------------------------------------------------
* VOLTAGE MANAGERMENT SERVICE GROUP
*/
/**
* upwr_vtm_pmic_cold_reset() -request cold reset the pmic.
* pmic will power cycle all the regulators
* @callb: response callback pointer; NULL if no callback needed.
*
* The function requests uPower to cold reset the pmic.
* The request is executed if arguments are within range, with no protections
* regarding the adequate voltage value for the given domain process,
* temperature and frequency.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_VOLTM as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_vtm_pmic_cold_reset(upwr_callb callb)
{
upwr_volt_pmic_cold_reset_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_VOLTM)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_VOLTM, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_VOLTM, UPWR_VTM_PMIC_COLD_RESET);
upwr_srv_req(UPWR_SG_VOLTM, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_vtm_set_pmic_mode() -request uPower set pmic mode
* @pmic_mode: the target mode need to be set
* @callb: response callback pointer; NULL if no callback needed.
*
* The function requests uPower to set pmic mode
* The request is executed if arguments are within range, with no protections
* regarding the adequate voltage value for the given domain process,
* temperature and frequency.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_VOLTM as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_vtm_set_pmic_mode(uint32_t pmic_mode, upwr_callb callb)
{
upwr_volt_pmic_set_mode_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_VOLTM)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_VOLTM, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_VOLTM, UPWR_VTM_SET_PMIC_MODE);
txmsg.hdr.arg = pmic_mode;
upwr_srv_req(UPWR_SG_VOLTM, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_vtm_chng_pmic_voltage() - Changes the voltage of a given rail.
* @rail: pmic rail id.
* @volt: the target voltage of the given rail, accurate to uV
* If pass volt value 0, means that power off this rail.
* @callb: response callback pointer; NULL if no callback needed.
*
* The function requests uPower to change the voltage of the given rail.
* The request is executed if arguments are within range, with no protections
* regarding the adequate voltage value for the given domain process,
* temperature and frequency.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_VOLTM as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_vtm_chng_pmic_voltage(uint32_t rail, uint32_t volt, upwr_callb callb)
{
upwr_volt_pmic_set_volt_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_VOLTM)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_VOLTM, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_VOLTM, UPWR_VTM_CHNG_PMIC_RAIL_VOLT);
txmsg.args.rail = rail;
txmsg.args.volt = (volt + PMIC_VOLTAGE_MIN_STEP - 1U) / PMIC_VOLTAGE_MIN_STEP;
upwr_srv_req(UPWR_SG_VOLTM, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_vtm_get_pmic_voltage() - Get the voltage of a given rail.
* @rail: pmic rail id.
* @callb: response callback pointer; NULL if no callback needed.
* (polling used instead)
*
* The function requests uPower to get the voltage of the given rail.
* The request is executed if arguments are within range, with no protections
* regarding the adequate voltage value for the given domain process,
* temperature and frequency.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_VOLTM as the service group argument.
*
* The voltage data read from uPower via
* the callback argument ret, or written to the variable pointed by retptr,
* if polling is used (calls upwr_req_status or upwr_poll_req_status).
* ret (or *retptr) also returns the data written on writes.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_vtm_get_pmic_voltage(uint32_t rail, upwr_callb callb)
{
upwr_volt_pmic_get_volt_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_VOLTM)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_VOLTM, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_VOLTM, UPWR_VTM_GET_PMIC_RAIL_VOLT);
txmsg.args.rail = rail;
upwr_srv_req(UPWR_SG_VOLTM, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_vtm_power_measure() - request uPower to measure power consumption
* @ssel: This field determines which power switches will have their currents
* sampled to be accounted for a
* current/power measurement. Support 0~7
* SSEL bit # Power Switch
* 0 M33 core complex/platform/peripherals
* 1 Fusion Core and Peripherals
* 2 A35[0] core complex
* 3 A35[1] core complex
* 4 3DGPU
* 5 HiFi4
* 6 DDR Controller (PHY and PLL NOT included)
* 7 PXP, EPDC
*
* @callb: response callback pointer; NULL if no callback needed.
* (polling used instead)
*
* The function requests uPower to measure power consumption
* The request is executed if arguments are within range, with no protections
* regarding the adequate voltage value for the given domain process,
* temperature and frequency.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_VOLTM as the service group argument.
*
* The power consumption data read from uPower via
* the callback argument ret, or written to the variable pointed by retptr,
* if polling is used (calls upwr_req_status or upwr_poll_req_status).
* ret (or *retptr) also returns the data written on writes.
* upower fw needs support cocurrent request from M33 and A35.
*
* Accurate to uA
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_vtm_power_measure(uint32_t ssel, upwr_callb callb)
{
upwr_volt_pmeter_meas_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_VOLTM)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_VOLTM, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_VOLTM, UPWR_VTM_PMETER_MEAS);
txmsg.hdr.arg = ssel;
upwr_srv_req(UPWR_SG_VOLTM, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_vtm_vmeter_measure() - request uPower to measure voltage
* @vdetsel: Voltage Detector Selector, support 0~3
* 00b - RTD sense point
01b - LDO output
10b - APD domain sense point
11b - AVD domain sense point
Refer to upower_defs.h
* @callb: response callback pointer; NULL if no callback needed.
* (polling used instead)
*
* The function requests uPower to use vmeter to measure voltage
* The request is executed if arguments are within range, with no protections
* regarding the adequate voltage value for the given domain process,
* temperature and frequency.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_VOLTM as the service group argument.
*
* The voltage data read from uPower via
* the callback argument ret, or written to the variable pointed by retptr,
* if polling is used (calls upwr_req_status or upwr_poll_req_status).
* ret (or *retptr) also returns the data written on writes.
* upower fw needs support cocurrent request from M33 and A35.
*
* Refer to RM COREREGVL (Core Regulator Voltage Level)
* uPower return VDETLVL to user, user can calculate the real voltage:
*
0b000000(0x00) - 0.595833V
0b100110(0x26) - 1.007498V
<value> - 0.595833V + <value>x10.8333mV
0b110010(0x32) - 1.138V
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_vtm_vmeter_measure(uint32_t vdetsel, upwr_callb callb)
{
upwr_volt_vmeter_meas_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_VOLTM)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_VOLTM, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_VOLTM, UPWR_VTM_VMETER_MEAS);
txmsg.hdr.arg = vdetsel;
upwr_srv_req(UPWR_SG_VOLTM, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_vtm_pmic_config() - Configures the SoC PMIC (Power Management IC).
* @config: pointer to a PMIC-dependent struct defining the PMIC configuration.
* @size: size of the struct pointed by config, in bytes.
* @callb: pointer to the callback called when configurations are applied.
* NULL if no callback is required.
*
* The function requests uPower to change/define the PMIC configuration.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok, -1 if service group is busy,
* -2 if the pointer conversion to physical address failed,
* -3 if called in an invalid API state.
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_vtm_pmic_config(const void *config, uint32_t size, upwr_callb callb)
{
upwr_pwm_pmiccfg_msg txmsg = {0};
unsigned long ptrval = 0UL; /* needed for X86, ARM64 */
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_VOLTM)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_VOLTM, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_VOLTM, UPWR_VTM_PMIC_CONFIG);
ptrval = (unsigned long)os_ptr2phy(config);
if (ptrval == 0UL) {
return -2; /* pointer conversion failed */
}
txmsg.ptr = upwr_ptr2offset(ptrval,
UPWR_SG_VOLTM,
(size_t)size,
0U,
config);
upwr_srv_req(UPWR_SG_VOLTM, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**---------------------------------------------------------------
* TEMPERATURE MANAGEMENT SERVICE GROUP
*/
/**
* upwr_tpm_get_temperature() - request uPower to get temperature of one temperature sensor
* @sensor_id: temperature sensor ID, support 0~2
* @callb: response callback pointer; NULL if no callback needed.
* (polling used instead)
*
* The function requests uPower to measure temperature
* The request is executed if arguments are within range, with no protections
* regarding the adequate voltage value for the given domain process,
* temperature and frequency.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_TEMPM as the service group argument.
*
* The temperature data read from uPower via
* the callback argument ret, or written to the variable pointed by retptr,
* if polling is used (calls upwr_req_status or upwr_poll_req_status).
* ret (or *retptr) also returns the data written on writes.
*
* uPower return TSEL to the caller (M33 or A35), caller calculate the real temperature
* Tsh = 0.000002673049*TSEL[7:0]^3 + 0.0003734262*TSEL[7:0]^2 +
0.4487042*TSEL[7:0] - 46.98694
*
* upower fw needs support cocurrent request from M33 and A35.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_tpm_get_temperature(uint32_t sensor_id, upwr_callb callb)
{
upwr_temp_get_cur_temp_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_TEMPM)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_TEMPM, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_TEMPM, UPWR_TEMP_GET_CUR_TEMP);
txmsg.args.sensor_id = sensor_id;
upwr_srv_req(UPWR_SG_TEMPM, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**---------------------------------------------------------------
* DELAY MANAGEMENT SERVICE GROUP
*/
/**
* upwr_dlm_get_delay_margin() - request uPower to get delay margin
* @path: The critical path
* @index: Use whitch delay meter
* @callb: response callback pointer; NULL if no callback needed.
* (polling used instead)
*
* The function requests uPower to get delay margin
* The request is executed if arguments are within range, with no protections
* regarding the adequate voltage value for the given domain process,
* temperature and frequency.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_DELAYM as the service group argument.
*
* The delay margin data read from uPower via
* the callback argument ret, or written to the variable pointed by retptr,
* if polling is used (calls upwr_req_status or upwr_poll_req_status).
* ret (or *retptr) also returns the data written on writes.
* upower fw needs support cocurrent request from M33 and A35.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_dlm_get_delay_margin(uint32_t path, uint32_t index, upwr_callb callb)
{
upwr_dmeter_get_delay_margin_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_DELAYM)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_DELAYM, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_DELAYM, UPWR_DMETER_GET_DELAY_MARGIN);
txmsg.args.path = path;
txmsg.args.index = index;
upwr_srv_req(UPWR_SG_DELAYM, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_dlm_set_delay_margin() - request uPower to set delay margin
* @path: The critical path
* @index: Use whitch delay meter
* @delay_margin: the value of delay margin
* @callb: response callback pointer; NULL if no callback needed.
* (polling used instead)
*
* The function requests uPower to set delay margin
* The request is executed if arguments are within range, with no protections
* regarding the adequate voltage value for the given domain process,
* temperature and frequency.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_DELAYM as the service group argument.
*
* The result of the corresponding critical path, failed or not read from uPower via
* the callback argument ret, or written to the variable pointed by retptr,
* if polling is used (calls upwr_req_status or upwr_poll_req_status).
* ret (or *retptr) also returns the data written on writes.
* upower fw needs support cocurrent request from M33 and A35.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_dlm_set_delay_margin(uint32_t path, uint32_t index, uint32_t delay_margin,
upwr_callb callb)
{
upwr_dmeter_set_delay_margin_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_DELAYM)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_DELAYM, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_DELAYM, UPWR_DMETER_SET_DELAY_MARGIN);
txmsg.args.path = path;
txmsg.args.index = index;
txmsg.args.dm = delay_margin;
upwr_srv_req(UPWR_SG_DELAYM, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_dlm_process_monitor() - request uPower to do process monitor
* @chain_sel: Chain Cell Type Selection
* Select the chain to be used for the clock signal generation.
* Support two types chain cell, 0~1
0b - P4 type delay cells selected
1b - P16 type delay cells selected
* @callb: response callback pointer; NULL if no callback needed.
* (polling used instead)
*
* The function requests uPower to do process monitor
* The request is executed if arguments are within range, with no protections
* regarding the adequate voltage value for the given domain process,
* temperature and frequency.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_DELAYM as the service group argument.
*
* The result of process monitor, failed or not read from uPower via
* the callback argument ret, or written to the variable pointed by retptr,
* if polling is used (calls upwr_req_status or upwr_poll_req_status).
* ret (or *retptr) also returns the data written on writes.
* upower fw needs support cocurrent request from M33 and A35.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_dlm_process_monitor(uint32_t chain_sel, upwr_callb callb)
{
upwr_pmon_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_DELAYM)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_DELAYM, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_DELAYM, UPWR_PMON_REQ);
txmsg.args.chain_sel = chain_sel;
upwr_srv_req(UPWR_SG_DELAYM, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**---------------------------------------------------------------
* POWER MANAGEMENT SERVICE GROUP
*/
/**
* upwr_pwm_dom_power_on() - Commands uPower to power on the platform of other
* domain (not necessarily its core(s)); does not release the core reset.
* @domain: identifier of the domain to power on. Defined by SoC-dependent type
* soc_domain_t found in upower_soc_defs.h.
* @boot_start: must be 1 to start the domain core(s) boot(s), releasing
* its (their) resets, or 0 otherwise.
* @pwroncallb: pointer to the callback to be called when the uPower has
* finished the power on procedure, or NULL if no callback needed
* (polling used instead).
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded or
* not.
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -2 if the domain passed is the same as the caller,
* -3 if called in an invalid API state
*/
int upwr_pwm_dom_power_on(soc_domain_t domain,
int boot_start,
const upwr_callb pwroncallb)
{
upwr_pwm_dom_pwron_msg txmsg = {0};
if (pwr_domain == domain) {
return -2;
}
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, (upwr_callb)pwroncallb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_DOM_PWRON);
txmsg.hdr.domain = (uint32_t)domain;
txmsg.hdr.arg = (uint32_t)boot_start;
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_pwm_boot_start() - Commands uPower to release the reset of other CPU(s),
* starting their boots.
* @domain: identifier of the domain to release the reset. Defined by
* SoC-dependent type soc_domain_t found in upower_soc_defs.h.
* @bootcallb: pointer to the callback to be called when the uPower has finished
* the boot start procedure, or NULL if no callback needed
* (polling used instead).
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded or
* not.
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* The callback calling doesn't mean the CPUs boots have finished:
* it only indicates that uPower released the CPUs resets, and can receive
* other power management service group requests.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -2 if the domain passed is the same as the caller,
* -3 if called in an invalid API state
*/
int upwr_pwm_boot_start(soc_domain_t domain, const upwr_callb bootcallb)
{
upwr_pwm_boot_start_msg txmsg = {0};
if (pwr_domain == domain) {
return -2;
}
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, (upwr_callb)bootcallb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_BOOT);
txmsg.hdr.domain = (uint32_t)domain;
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_pwm_param() - Changes Power Management parameters.
* @param: pointer to a parameter structure upwr_pwm_param_t, SoC-dependent,
* defined in upwr_soc_defines.h. NULL may be passed, meaning
* a request to read the parameter set, in which case it appears in the callback
* argument ret, or can be pointed by argument retptr in the upwr_req_status and
* upwr_poll_req_status calls, casted to upwr_pwm_param_t.
* @callb: response callback pointer; NULL if no callback needed.
*
* The return value is always the current parameter set value, either in a
* read-only request (param = NULL) or after setting a new parameter
* (non-NULL param).
*
* Some parameters may be targeted for a specific domain (see the struct
* upwr_pwm_param_t definition in upower_soc_defs.h); this call has implicit
* domain target (the same domain from which is called).
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded or
* not.
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
*/
int upwr_pwm_param(upwr_pwm_param_t *param, const upwr_callb callb)
{
upwr_pwm_param_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_PARAM);
if (param == NULL) {
txmsg.hdr.arg = 1U; /* 1= read, txmsg.word2 ignored */
} else {
txmsg.hdr.arg = 0U; /* 1= write */
txmsg.word2 = param->R; /* just 1 word, so that's ok */
}
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_pwm_chng_reg_voltage() - Changes the voltage at a given regulator.
* @reg: regulator id.
* @volt: voltage value; value unit is SoC-dependent, converted from mV by the
* macro UPWR_VTM_MILIV, or from micro-Volts by the macro UPWR_VTM_MICROV,
* both macros in upower_soc_defs.h
* @callb: response callback pointer; NULL if no callback needed.
*
* The function requests uPower to change the voltage of the given regulator.
* The request is executed if arguments are within range, with no protections
* regarding the adequate voltage value for the given domain process,
* temperature and frequency.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_pwm_chng_reg_voltage(uint32_t reg, uint32_t volt, upwr_callb callb)
{
upwr_pwm_volt_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_VOLT);
txmsg.args.reg = reg;
txmsg.args.volt = volt;
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_pwm_freq_setup() - Determines the next frequency target for a given
* domain and current frequency.
* @domain: identifier of the domain to change frequency. Defined by
* SoC-dependent type soc_domain_t found in upower_soc_defs.h.
* @rail: the pmic regulator number for the target domain.
* @stage: DVA adjust stage
* refer to upower_defs.h "DVA adjust stage"
* @target_freq: the target adjust frequency, accurate to MHz
*
* refer to upower_defs.h structure definition upwr_pwm_freq_msg
*
* @callb: response callback pointer; NULL if no callback needed.
*
* The DVA algorithm is broken down into two phases.
* The first phase uses a look up table to get a safe operating voltage
* for the requested frequency.
* This voltage is guaranteed to work over process and temperature.
*
* The second step of the second phase is to measure the temperature
* using the uPower Temperature Sensor module.
* This is accomplished by doing a binary search of the TSEL bit field
* in the Temperature Measurement Register (TMR).
* The search is repeated until the THIGH bit fields in the same register change value.
* There are 3 temperature sensors in 8ULP (APD, AVD, and RTD).
*
*
* The second phase is the fine adjust of the voltage.
* This stage is entered only when the new frequency requested
* by application was already set as well as the voltage for that frequency.
* The first step of the fine adjust is to find what is the current margins
* for the monitored critical paths, or, in other words,
* how many delay cells will be necessary to generate a setup-timing violation.
* The function informs uPower that the given domain frequency has changed or
* will change to the given value. uPower firmware will then adjust voltage and
* bias to cope with the new frequency (if decreasing) or prepare for it
* (if increasing). The function must be called after decreasing the frequency,
* and before increasing it. The actual increase in frequency must not occur
* before the service returns its response.
*
* So, for increase clock frequency case, user need to call this API twice,
* the first stage gross adjust and the second stage fine adjust.
*
* for reduce clock frequency case, user can only call this API once,
* full stage (combine gross stage and fine adjust)
*
* The request is executed if arguments are within range.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_pwm_freq_setup(soc_domain_t domain, uint32_t rail, uint32_t stage, uint32_t target_freq,
upwr_callb callb)
{
upwr_pwm_freq_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_FREQ);
txmsg.hdr.domain = (uint32_t)domain;
txmsg.args.rail = rail;
txmsg.args.stage = stage;
txmsg.args.target_freq = target_freq;
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_pwm_power_on()- Powers on (not off) one or more switches and ROM/RAMs.
* @swton: pointer to an array of words that tells which power switches to
* turn on. Each word in the array has 1 bit for each switch.
* A bit=1 means the respective switch must be turned on,
* bit = 0 means it will stay unchanged (on or off).
* The pointer may be set to NULL, in which case no switch will be changed,
* unless a memory that it feeds must be turned on.
* WARNING: swton must not point to the first shared memory address.
* @memon: pointer to an array of words that tells which memories to turn on.
* Each word in the array has 1 bit for each switch.
* A bit=1 means the respective memory must be turned on, both array and
* periphery logic;
* bit = 0 means it will stay unchanged (on or off).
* The pointer may be set to NULL, in which case no memory will be changed.
* WARNING: memon must not point to the first shared memory address.
* @callb: pointer to the callback called when configurations are applyed.
* NULL if no callback is required.
*
* The function requests uPower to turn on the PMC and memory array/peripheral
* switches that control their power, as specified above.
* The request is executed if arguments are within range, with no protections
* regarding the adequate memory power state related to overall system state.
*
* If a memory is requested to turn on, but the power switch that feeds that
* memory is not, the power switch will be turned on anyway, if the pwron
* array is not provided (that is, if pwron is NULL).
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* Callback or polling may return error if the service contends for a resource
* already being used by a power mode transition or an ongoing service in
* another domain.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok, -1 if service group is busy,
* -2 if a pointer conversion to physical address failed,
* -3 if called in an invalid API state.
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_pwm_power_on(const uint32_t swton[],
const uint32_t memon[],
upwr_callb callb)
{
upwr_pwm_pwron_msg txmsg = {0};
unsigned long ptrval = 0UL; /* needed for X86, ARM64 */
size_t stsize = 0U;
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_PWR_ON);
ptrval = (unsigned long)os_ptr2phy((void *)swton);
if (swton == NULL) {
txmsg.ptrs.ptr0 = 0; /* NULL pointer -> 0 offset */
} else if (ptrval == 0U) {
return -2; /* pointer conversion failed */
} else {
txmsg.ptrs.ptr0 = upwr_ptr2offset(ptrval,
UPWR_SG_PWRMGMT,
(stsize = UPWR_PMC_SWT_WORDS * 4U),
0U,
swton);
}
ptrval = (unsigned long)os_ptr2phy((void *)memon);
if (memon == NULL) {
txmsg.ptrs.ptr1 = 0; /* NULL pointer -> 0 offset */
} else if (ptrval == 0U) {
return -2; /* pointer conversion failed */
} else {
txmsg.ptrs.ptr1 = upwr_ptr2offset(ptrval,
UPWR_SG_PWRMGMT,
UPWR_PMC_MEM_WORDS * 4U,
stsize,
memon);
}
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_pwm_power_off()- Powers off (not on) one or more switches and ROM/RAMs.
* @swtoff: pointer to an array of words that tells which power switches to
* turn off. Each word in the array has 1 bit for each switch.
* A bit=1 means the respective switch must be turned off,
* bit = 0 means it will stay unchanged (on or off).
* The pointer may be set to NULL, in which case no switch will be changed.
* WARNING: swtoff must not point to the first shared memory address.
* @memoff: pointer to an array of words that tells which memories to turn off.
* Each word in the array has 1 bit for each switch.
* A bit=1 means the respective memory must be turned off, both array and
* periphery logic;
* bit = 0 means it will stay unchanged (on or off).
* The pointer may be set to NULL, in which case no memory will be changed,
* but notice it may be turned off if the switch that feeds it is powered off.
* WARNING: memoff must not point to the first shared memory address.
* @callb: pointer to the callback called when configurations are applyed.
* NULL if no callback is required.
*
* The function requests uPower to turn off the PMC and memory array/peripheral
* switches that control their power, as specified above.
* The request is executed if arguments are within range, with no protections
* regarding the adequate memory power state related to overall system state.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* Callback or polling may return error if the service contends for a resource
* already being used by a power mode transition or an ongoing service in
* another domain.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok, -1 if service group is busy,
* -2 if a pointer conversion to physical address failed,
* -3 if called in an invalid API state.
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_pwm_power_off(const uint32_t swtoff[],
const uint32_t memoff[],
upwr_callb callb)
{
upwr_pwm_pwroff_msg txmsg = {0};
unsigned long ptrval = 0UL; /* needed for X86, ARM64 */
size_t stsize = 0;
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_PWR_OFF);
ptrval = (unsigned long)os_ptr2phy((void *)swtoff);
if (swtoff == NULL) {
txmsg.ptrs.ptr0 = 0; /* NULL pointer -> 0 offset */
} else if (ptrval == 0U) {
return -2; /* pointer conversion failed */
} else {
txmsg.ptrs.ptr0 = upwr_ptr2offset(ptrval,
UPWR_SG_PWRMGMT,
(stsize = UPWR_PMC_SWT_WORDS * 4U),
0U,
swtoff);
}
ptrval = (unsigned long)os_ptr2phy((void *)memoff);
if (memoff == NULL) {
txmsg.ptrs.ptr1 = 0; /* NULL pointer -> 0 offset */
} else if (ptrval == 0U) {
return -2; /* pointer conversion failed */
} else {
txmsg.ptrs.ptr1 = upwr_ptr2offset(ptrval,
UPWR_SG_PWRMGMT,
UPWR_PMC_MEM_WORDS * 4U,
stsize,
memoff);
}
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_pwm_mem_retain()- Configures one or more memory power switches to
* retain its contents, having the power array on, while its peripheral logic
* is turned off.
* @mem: pointer to an array of words that tells which memories to put in a
* retention state. Each word in the array has 1 bit for each memory.
* A bit=1 means the respective memory must be put in retention state,
* bit = 0 means it will stay unchanged (retention, fully on or off).
* @callb: pointer to the callback called when configurations are applyed.
* NULL if no callback is required.
*
* The function requests uPower to turn off the memory peripheral and leave
* its array on, as specified above.
* The request is executed if arguments are within range.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* Callback or polling may return error if the service contends for a resource
* already being used by a power mode transition or an ongoing service in
* another domain.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok, -1 if service group is busy,
* -2 if a pointer conversion to physical address failed,
* -3 if called in an invalid API state.
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_pwm_mem_retain(const uint32_t mem[], upwr_callb callb)
{
upwr_pwm_retain_msg txmsg = {0};
unsigned long ptrval = 0UL; /* needed for X86, ARM64 */
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_RETAIN);
ptrval = (unsigned long)os_ptr2phy((void *)mem);
if (ptrval == 0U) {
return -2; /* pointer conversion failed */
}
txmsg.ptr = upwr_ptr2offset(ptrval,
UPWR_SG_PWRMGMT,
UPWR_PMC_MEM_WORDS * 4U,
0U,
mem);
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_pwm_chng_switch_mem() - Turns on/off power on one or more PMC switches
* and memories, including their array and peripheral logic.
* @swt: pointer to a list of PMC switches to be opened/closed.
* The list is structured as an array of struct upwr_switch_board_t
* (see upower_defs.h), each one containing a word for up to 32 switches,
* one per bit. A bit = 1 means switch closed, bit = 0 means switch open.
* struct upwr_switch_board_t also specifies a mask with 1 bit for each
* respective switch: mask bit = 1 means the open/close action is applied,
* mask bit = 0 means the switch stays unchanged.
* The pointer may be set to NULL, in which case no switch will be changed,
* unless a memory that it feeds must be turned on.
* WARNING: swt must not point to the first shared memory address.
* @mem: pointer to a list of switches to be turned on/off.
* The list is structured as an array of struct upwr_mem_switches_t
* (see upower_defs.h), each one containing 2 word for up to 32 switches,
* one per bit, one word for the RAM array power switch, other for the
* RAM peripheral logic power switch. A bit = 1 means switch closed,
* bit = 0 means switch open.
* struct upwr_mem_switches_t also specifies a mask with 1 bit for each
* respective switch: mask bit = 1 means the open/close action is applied,
* mask bit = 0 means the switch stays unchanged.
* The pointer may be set to NULL, in which case no memory switch will be
* changed, but notice it may be turned off if the switch that feeds it is
* powered off.
* WARNING: mem must not point to the first shared memory address.
* @callb: pointer to the callback called when the configurations are applied.
* NULL if no callback is required.
*
* The function requests uPower to change the PMC switches and/or memory power
* as specified above.
* The request is executed if arguments are within range, with no protections
* regarding the adequate switch combinations and overall system state.
*
* If a memory is requested to turn on, but the power switch that feeds that
* memory is not, the power switch will be turned on anyway, if the swt
* array is not provided (that is, if swt is NULL).
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* Callback or polling may return error if the service contends for a resource
* already being used by a power mode transition or an ongoing service in
* another domain.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok, -1 if service group is busy.
* -2 if a pointer conversion to physical address failed,
* -3 if called in an invalid API state.
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_pwm_chng_switch_mem(const struct upwr_switch_board_t swt[],
const struct upwr_mem_switches_t mem[],
upwr_callb callb)
{
upwr_pwm_switch_msg txmsg = {0};
unsigned long ptrval = 0UL; /* needed for X86, ARM64 */
size_t stsize = 0U;
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_SWITCH);
ptrval = (unsigned long)os_ptr2phy((void *)swt);
if (swt == NULL) {
txmsg.ptrs.ptr0 = 0; /* NULL pointer -> 0 offset */
} else if (ptrval == 0U) {
return -2; /* pointer conversion failed */
} else {
txmsg.ptrs.ptr0 = upwr_ptr2offset(ptrval,
UPWR_SG_PWRMGMT,
(stsize = UPWR_PMC_SWT_WORDS * sizeof(struct upwr_switch_board_t)),
0U,
swt);
}
ptrval = (unsigned long)os_ptr2phy((void *)mem);
if (mem == NULL) {
txmsg.ptrs.ptr1 = 0; /* NULL pointer -> 0 offset */
} else if (ptrval == 0U) {
return -2; /* pointer conversion failed */
} else {
txmsg.ptrs.ptr1 = upwr_ptr2offset(ptrval,
UPWR_SG_PWRMGMT,
UPWR_PMC_MEM_WORDS * sizeof(struct upwr_mem_switches_t),
stsize,
mem);
}
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_pwm_pmode_config() - Configures a given power mode in a given domain.
* @domain: identifier of the domain to which the power mode belongs.
* Defined by SoC-dependent type soc_domain_t found in upower_soc_defs.h.
* @pmode: SoC-dependent power mode identifier defined by type abs_pwr_mode_t
* found in upower_soc_defs.h.
* @config: pointer to an SoC-dependent struct defining the power mode
* configuration, found in upower_soc_defs.h.
* @callb: pointer to the callback called when configurations are applied.
* NULL if no callback is required.
*
* The function requests uPower to change the power mode configuration as
* specified above. The request is executed if arguments are within range,
* and complies with SoC-dependent restrictions on value combinations.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok, -1 if service group is busy,
* -2 if the pointer conversion to physical address failed,
* -3 if called in an invalid API state.
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_pwm_pmode_config(soc_domain_t domain,
abs_pwr_mode_t pmode,
const void *config,
upwr_callb callb)
{
upwr_pwm_pmode_cfg_msg txmsg = {0};
unsigned long ptrval = 0UL; /* needed for X86, ARM64 */
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_CONFIG);
txmsg.hdr.domain = (uint32_t)domain;
txmsg.hdr.arg = pmode;
ptrval = (unsigned long)os_ptr2phy(config);
if (ptrval == 0U) {
return -2; /* pointer conversion failed */
}
/*
* upwr_pwm_pmode_config is an exception: use the pointer
* (physical addr) as is
*/
txmsg.ptr = (uint32_t)ptrval;
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_pwm_reg_config() - Configures the uPower internal regulators.
* @config: pointer to the struct defining the regulator configuration;
* the struct upwr_reg_config_t is defined in the file upower_defs.h.
* @callb: pointer to the callback called when configurations are applied.
* NULL if no callback is required.
*
* The function requests uPower to change/define the configurations of the
* internal regulators.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* The service may fail with error UPWR_RESP_RESOURCE if a power mode transition
* or the same service (called from another domain) is executing simultaneously.
* This error should be interpreted as a "try later" response, as the service
* will succeed once those concurrent executions are done, and no other is
* started.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok, -1 if service group is busy,
* -2 if the pointer conversion to physical address failed,
* -3 if called in an invalid API state.
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_pwm_reg_config(const struct upwr_reg_config_t *config,
upwr_callb callb)
{
upwr_pwm_regcfg_msg txmsg = {0};
unsigned long ptrval = 0UL; /* needed for X86, ARM64 */
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_REGCFG);
ptrval = (unsigned long)os_ptr2phy(config);
if (ptrval == 0U) {
return -2; /* pointer conversion failed */
}
txmsg.ptr = upwr_ptr2offset(ptrval,
UPWR_SG_PWRMGMT,
sizeof(struct upwr_reg_config_t),
0U,
config);
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_pwm_chng_dom_bias() - Changes the domain bias.
* @bias: pointer to a domain bias configuration struct (see upower_soc_defs.h).
* @callb: pointer to the callback called when configurations are applied.
* NULL if no callback is required.
*
* The function requests uPower to change the domain bias configuration as
* specified above. The request is executed if arguments are within range,
* with no protections regarding the adequate value combinations and
* overall system state.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok, -1 if service group is busy,
* -3 if called in an invalid API state.
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_pwm_chng_dom_bias(const struct upwr_dom_bias_cfg_t *bias,
upwr_callb callb)
{
upwr_pwm_dom_bias_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_DOM_BIAS);
/* SoC-dependent argument filling, defined in upower_soc_defs.h */
UPWR_FILL_DOMBIAS_ARGS(txmsg.hdr.domain, bias, txmsg.args);
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**
* upwr_pwm_chng_mem_bias()- Changes a ROM/RAM power bias.
* @domain: identifier of the domain upon which the bias is applied.
* Defined by SoC-dependent type soc_domain_t found in upower_soc_defs.h.
* @bias: pointer to a memory bias configuration struct (see upower_soc_defs.h).
* @callb: pointer to the callback called when configurations are applied.
* NULL if no callback is required.
*
* The function requests uPower to change the memory bias configuration as
* specified above. The request is executed if arguments are within range,
* with no protections regarding the adequate value combinations and
* overall system state.
*
* A callback can be optionally registered, and will be called upon the arrival
* of the request response from the uPower firmware, telling if it succeeded
* or not.
*
* A callback may not be registered (NULL pointer), in which case polling has
* to be used to check the response, by calling upwr_req_status or
* upwr_poll_req_status, using UPWR_SG_PWRMGMT as the service group argument.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok, -1 if service group is busy,
* -3 if called in an invalid API state.
* Note that this is not the error response from the request itself:
* it only tells if the request was successfully sent to the uPower.
*/
int upwr_pwm_chng_mem_bias(soc_domain_t domain,
const struct upwr_mem_bias_cfg_t *bias,
upwr_callb callb)
{
upwr_pwm_mem_bias_msg txmsg = {0};
if (api_state != UPWR_API_READY) {
return -3;
}
if (UPWR_SG_BUSY(UPWR_SG_PWRMGMT)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_PWRMGMT, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_PWRMGMT, UPWR_PWM_MEM_BIAS);
txmsg.hdr.domain = (uint32_t)domain;
/* SoC-dependent argument filling, defined in upower_soc_defs.h */
UPWR_FILL_MEMBIAS_ARGS(bias, txmsg.args);
upwr_srv_req(UPWR_SG_PWRMGMT, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**---------------------------------------------------------------
* DIAGNOSE SERVICE GROUP
*/
/**
* upwr_dgn_mode() - Sets the diagnostic mode.
* @mode: diagnostic mode, which can be:
* - UPWR_DGN_NONE: no diagnostic recorded
* - UPWR_DGN_TRACE: warnings, errors, service, internal activity recorded
* - UPWR_DGN_SRVREQ: warnings, errors, service activity recorded
* - UPWR_DGN_WARN: warnings and errors recorded
* - UPWR_DGN_ALL: trace, service, warnings, errors, task state recorded
* - UPWR_DGN_ERROR: only errors recorded
* - UPWR_DGN_ALL2ERR: record all until an error occurs,
* freeze recording on error
* - UPWR_DGN_ALL2HLT: record all until an error occurs,
* executes an ebreak on error, which halts the core if enabled through
* the debug interface
* @callb: pointer to the callback called when mode is changed.
* NULL if no callback is required.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok,
* -1 if service group is busy,
* -3 if called in an invalid API state
*/
int upwr_dgn_mode(upwr_dgn_mode_t mode, const upwr_callb callb)
{
upwr_dgn_mode_msg txmsg = {0};
if (UPWR_SG_BUSY(UPWR_SG_DIAG)) {
return -1;
}
UPWR_USR_CALLB(UPWR_SG_DIAG, callb);
UPWR_MSG_HDR(txmsg.hdr, UPWR_SG_DIAG, UPWR_DGN_MODE);
txmsg.hdr.arg = mode;
upwr_srv_req(UPWR_SG_DIAG, (uint32_t *)&txmsg, sizeof(txmsg) / 4U);
return 0;
}
/**---------------------------------------------------------------
* AUXILIARY CALLS
*/
/**
* upwr_rom_version() - informs the ROM firwmware version.
* @vmajor: pointer to the variable to get the firmware major version number.
* @vminor: pointer to the variable to get the firmware minor version number.
* @vfixes: pointer to the variable to get the firmware fixes number.
*
* Context: no sleep, no locks taken/released.
* Return: SoC id.
*/
uint32_t upwr_rom_version(uint32_t *vmajor, uint32_t *vminor, uint32_t *vfixes)
{
uint32_t soc;
upwr_lock(1);
soc = fw_rom_version.soc_id;
*vmajor = fw_rom_version.vmajor;
*vminor = fw_rom_version.vminor;
*vfixes = fw_rom_version.vfixes;
upwr_lock(0);
return soc;
}
/**
* upwr_ram_version() - informs the RAM firwmware version.
* @vminor: pointer to the variable to get the firmware minor version number.
* @vfixes: pointer to the variable to get the firmware fixes number.
*
* The 3 values returned are 0 if no RAM firmwmare was loaded and initialized.
*
* Context: no sleep, no locks taken/released.
* Return: firmware major version number.
*/
uint32_t upwr_ram_version(uint32_t *vminor, uint32_t *vfixes)
{
uint32_t vmajor;
upwr_lock(1);
vmajor = fw_ram_version.vmajor;
*vminor = fw_ram_version.vminor;
*vfixes = fw_ram_version.vfixes;
upwr_lock(0);
return vmajor;
}
/**
* upwr_req_status() - tells the status of the service group request, and
* returns a request return value, if any.
* @sg: service group of the request
* @sgfptr: pointer to the variable that will hold the function id of
* the last request completed; can be NULL, in which case it is not used.
* @errptr: pointer to the variable that will hold the error code;
* can be NULL, in which case it is not used.
* @retptr: pointer to the variable that will hold the value returned
* by the last request completed (invalid if the last request completed didn't
* return any value); can be NULL, in which case it is not used.
* Note that a request may return a value even if service error is returned
* (*errptr != UPWR_RESP_OK): that is dependent on the specific service.
*
* This call can be used in a poll loop of a service request completion in case
* a callback was not registered.
*
* Context: no sleep, no locks taken/released.
* Return: service request status: succeeded, failed, or ongoing (busy)
*/
upwr_req_status_t upwr_req_status(upwr_sg_t sg,
uint32_t *sgfptr,
upwr_resp_t *errptr,
int *retptr)
{
upwr_req_status_t status;
upwr_lock(1);
if (sgfptr != NULL) {
*sgfptr = (uint32_t)sg_rsp_msg[sg].hdr.function;
}
if (errptr != NULL) {
*errptr = (upwr_resp_t)sg_rsp_msg[sg].hdr.errcode;
}
if (retptr != NULL) {
*retptr = (int)((sg_rsp_siz[sg] == 2U) ?
sg_rsp_msg[sg].word2 : sg_rsp_msg[sg].hdr.ret);
}
status = ((sg_busy & (1UL << sg)) == 1U) ? UPWR_REQ_BUSY :
(sg_rsp_msg[sg].hdr.errcode == UPWR_RESP_OK) ? UPWR_REQ_OK :
UPWR_REQ_ERR;
upwr_lock(0);
return status;
}
/**
* upwr_poll_req_status() - polls the status of the service group request, and
* returns a request return value, if any.
* @sg: service group of the request
* @sgfptr: pointer to the variable that will hold the function id of
* the last request completed; can be NULL, in which case it is not used.
* @errptr: pointer to the variable that will hold the error code;
* can be NULL, in which case it is not used.
* @retptr: pointer to the variable that will hold the value returned
* by the last request completed (invalid if the last request completed didn't
* return any value); can be NULL, in which case it is not used.
* Note that a request may return a value even if service error is returned
* (*errptr != UPWR_RESP_OK): that is dependent on the specific service.
* @attempts: maximum number of polling attempts; if attempts > 0 and is
* reached with no service response received, upwr_poll_req_status returns
* UPWR_REQ_BUSY and variables pointed by sgfptr, retptr and errptr are not
* updated; if attempts = 0, upwr_poll_req_status waits "forever".
*
* This call can be used to poll a service request completion in case a
* callback was not registered.
*
* Context: no sleep, no locks taken/released.
* Return: service request status: succeeded, failed, or ongoing (busy)
*/
upwr_req_status_t upwr_poll_req_status(upwr_sg_t sg,
uint32_t *sgfptr,
upwr_resp_t *errptr,
int *retptr,
uint32_t attempts)
{
uint32_t i;
upwr_req_status_t ret;
if (attempts == 0U) {
while ((ret = upwr_req_status(sg, sgfptr, errptr, retptr)) == UPWR_REQ_BUSY) {
};
return ret;
}
for (i = 0U; i < attempts; i++) {
ret = upwr_req_status(sg, sgfptr, errptr, retptr);
if (ret != UPWR_REQ_BUSY) {
break;
}
}
return ret;
}
/**
* upwr_alarm_code() - returns the alarm code of the last alarm occurrence.
*
* The value returned is not meaningful if no alarm was issued by uPower.
*
* Context: no sleep, no locks taken/released.
* Return: alarm code, as defined by the type upwr_alarm_t in upwr_soc_defines.h
*/
upwr_alarm_t upwr_alarm_code(void)
{
return (upwr_alarm_t)(3U & (mu->FSR.R >> 1U)); /* FSR[2:1] */
}
/**---------------------------------------------------------------
* TRANSMIT/RECEIVE PRIMITIVES
* ---------------------------------------------------------------
*/
/*
* upwr_copy2tr() - copies a message to the MU TR registers;
* fill the TR registers before writing TIEN to avoid early interrupts;
* also, fill them from the higher index to the lowest, so the receive
* interrupt flag RF[0] will be the last to set, regardless of message size;
*/
void upwr_copy2tr(struct MU_t *local_mu, const uint32_t *msg, unsigned int size)
{
for (int i = (int)size - 1; i > -1; i--) {
local_mu->TR[i].R = msg[i];
}
}
/**
* upwr_tx() - queues a message for transmission.
* @msg : pointer to the message sent.
* @size: message size in 32-bit words
* @callback: pointer to a function to be called when transmission done;
* can be NULL, in which case no callback is done.
*
* This is an auxiliary function used by the rest of the API calls.
* It is normally not called by the driver code, unless maybe for test purposes.
*
* Context: no sleep, no locks taken/released.
* Return: number of vacant positions left in the transmission queue, or
* -1 if the queue was already full when upwr_tx was called, or
* -2 if any argument is invalid (like size off-range)
*/
int upwr_tx(const uint32_t *msg,
unsigned int size,
UPWR_TX_CALLB_FUNC_T callback)
{
if (size > UPWR_MU_MSG_SIZE) {
return -2;
}
if (size == 0U) {
return -2;
}
if (mu->TSR.R != UPWR_MU_TSR_EMPTY) {
return -1; /* not all TE bits in 1: some data to send still */
}
mu_tx_callb = callback;
upwr_copy2tr(mu, msg, size);
mu->TCR.R = 1UL << (size - 1UL);
mu_tx_pend = 1UL;
return 0;
}
/**
* upwr_rx() - unqueues a received message from the reception queue.
* @msg: pointer to the message destination buffer.
* @size: pointer to variable to hold message size in 32-bit words.
*
* This is an auxiliary function used by the rest of the API calls.
* It is normally not called by the driver code, unless maybe for test purposes.
*
* Context: no sleep, no locks taken/released.
* Return: number of messages remaining in the reception queue, or
* -1 if the queue was already empty when upwr_rx was called, or
* -2 if any argument is invalid (like mu off-range)
*/
int upwr_rx(char *msg, unsigned int *size)
{
unsigned int len = mu->RSR.R;
len = (len == 0x0U) ? 0U :
(len == 0x1U) ? 1U :
#if UPWR_MU_MSG_SIZE > 1
(len == 0x3U) ? 2U :
#if UPWR_MU_MSG_SIZE > 2
(len == 0x7U) ? 3U :
#if UPWR_MU_MSG_SIZE > 3
(len == 0xFU) ? 4U :
#endif
#endif
#endif
0xFFFFFFFFU; /* something wrong */
if (len == 0xFFFFFFFFU) {
return -3;
}
if (len == 0U) {
return -1;
}
*size = len;
/*
* copy the received message to the rx queue,
* so the interrupts are cleared.
*/
msg_copy(msg, (char *)&mu->RR[0], len);
mu->RCR.R = 1U; /* enable only RR[0] receive interrupt */
return 0;
}
/**
* upwr_rx_callback() - sets up a callback for a message receiving event.
* @callback: pointer to a function to be called when a message arrives;
* can be NULL, in which case no callback is done.
*
* This is an auxiliary function used by the rest of the API calls.
* It is normally not called by the driver code, unless maybe for test purposes.
*
* Context: no sleep, no locks taken/released.
* Return: 0 if ok; -2 if any argument is invalid (mu off-range).
*/
int upwr_rx_callback(UPWR_RX_CALLB_FUNC_T callback)
{
mu_rx_callb = callback;
return 0;
}
/**
* msg_copy() - copies a message.
* @dest: pointer to the destination message.
* @src : pointer to the source message.
* @size: message size in words.
*
* This is an auxiliary function used by the rest of the API calls.
* It is normally not called by the driver code, unless maybe for test purposes.
*
* Context: no sleep, no locks taken/released.
* Return: none (void)
*/
void msg_copy(char *dest, char *src, unsigned int size)
{
for (uint32_t i = 0U; i < size * sizeof(uint32_t); i++) {
dest[i] = src[i];
}
}
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