/* * Copyright (c) 2021-2022, STMicroelectronics - All Rights Reserved * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #include #include #include #define MAX_PROPERTY_LEN 64 CASSERT(PLAT_NB_RDEVS >= 1U, plat_nb_rdevs_must_be_higher); static struct rdev rdev_array[PLAT_NB_RDEVS]; #define for_each_rdev(rdev) \ for ((rdev) = rdev_array; (rdev) <= &rdev_array[PLAT_NB_RDEVS - 1U]; (rdev)++) #define for_each_registered_rdev(rdev) \ for ((rdev) = rdev_array; \ ((rdev) <= &rdev_array[PLAT_NB_RDEVS - 1U]) && ((rdev)->desc != NULL); (rdev)++) static void lock_driver(const struct rdev *rdev) { if (rdev->desc->ops->lock != NULL) { rdev->desc->ops->lock(rdev->desc); } } static void unlock_driver(const struct rdev *rdev) { if (rdev->desc->ops->unlock != NULL) { rdev->desc->ops->unlock(rdev->desc); } } static struct rdev *regulator_get_by_phandle(int32_t phandle) { struct rdev *rdev; for_each_registered_rdev(rdev) { if (rdev->phandle == phandle) { return rdev; } } WARN("%s: phandle %d not found\n", __func__, phandle); return NULL; } /* * Get a regulator from its node name * * @fdt - pointer to device tree memory * @node_name - name of the node "ldo1" * Return pointer to rdev if succeed, NULL else. */ struct rdev *regulator_get_by_name(const char *node_name) { struct rdev *rdev; assert(node_name != NULL); VERBOSE("get %s\n", node_name); for_each_registered_rdev(rdev) { if (strcmp(rdev->desc->node_name, node_name) == 0) { return rdev; } } WARN("%s: %s not found\n", __func__, node_name); return NULL; } static int32_t get_supply_phandle(const void *fdt, int node, const char *name) { const fdt32_t *cuint; int len __unused; int supply_phandle = -FDT_ERR_NOTFOUND; char prop_name[MAX_PROPERTY_LEN]; len = snprintf(prop_name, MAX_PROPERTY_LEN - 1, "%s-supply", name); assert((len >= 0) && (len < (MAX_PROPERTY_LEN - 1))); cuint = fdt_getprop(fdt, node, prop_name, NULL); if (cuint != NULL) { supply_phandle = fdt32_to_cpu(*cuint); VERBOSE("%s: supplied by %d\n", name, supply_phandle); } return supply_phandle; } /* * Get a regulator from a supply name * * @fdt - pointer to device tree memory * @node - offset of the node that contains the supply description * @name - name of the supply "vdd" for "vdd-supply' * Return pointer to rdev if succeed, NULL else. */ struct rdev *regulator_get_by_supply_name(const void *fdt, int node, const char *name) { const int p = get_supply_phandle(fdt, node, name); if (p < 0) { return NULL; } return regulator_get_by_phandle(p); } static int __regulator_set_state(struct rdev *rdev, bool state) { if (rdev->desc->ops->set_state == NULL) { return -ENODEV; } return rdev->desc->ops->set_state(rdev->desc, state); } /* * Enable regulator * * @rdev - pointer to rdev struct * Return 0 if succeed, non 0 else. */ int regulator_enable(struct rdev *rdev) { int ret; assert(rdev != NULL); ret = __regulator_set_state(rdev, STATE_ENABLE); udelay(rdev->enable_ramp_delay); return ret; } /* * Disable regulator * * @rdev - pointer to rdev struct * Return 0 if succeed, non 0 else. */ int regulator_disable(struct rdev *rdev) { int ret; assert(rdev != NULL); if ((rdev->flags & REGUL_ALWAYS_ON) != 0U) { return 0; } ret = __regulator_set_state(rdev, STATE_DISABLE); udelay(rdev->enable_ramp_delay); return ret; } /* * Regulator enabled query * * @rdev - pointer to rdev struct * Return 0 if disabled, 1 if enabled, <0 else. */ int regulator_is_enabled(const struct rdev *rdev) { int ret; assert(rdev != NULL); VERBOSE("%s: is en\n", rdev->desc->node_name); if (rdev->desc->ops->get_state == NULL) { return -ENODEV; } lock_driver(rdev); ret = rdev->desc->ops->get_state(rdev->desc); if (ret < 0) { ERROR("regul %s get state failed: err:%d\n", rdev->desc->node_name, ret); } unlock_driver(rdev); return ret; } /* * Set regulator voltage * * @rdev - pointer to rdev struct * @mvolt - Target voltage level in millivolt * Return 0 if succeed, non 0 else. */ int regulator_set_voltage(struct rdev *rdev, uint16_t mvolt) { int ret; assert(rdev != NULL); VERBOSE("%s: set mvolt\n", rdev->desc->node_name); if ((mvolt < rdev->min_mv) || (mvolt > rdev->max_mv)) { return -EPERM; } if (regulator_get_voltage(rdev) == mvolt) { return 0U; } if (rdev->desc->ops->set_voltage == NULL) { return -ENODEV; } lock_driver(rdev); ret = rdev->desc->ops->set_voltage(rdev->desc, mvolt); if (ret < 0) { ERROR("regul %s set volt failed: err:%d\n", rdev->desc->node_name, ret); } unlock_driver(rdev); return ret; } /* * Set regulator min voltage * * @rdev - pointer to rdev struct * Return 0 if succeed, non 0 else. */ int regulator_set_min_voltage(struct rdev *rdev) { return regulator_set_voltage(rdev, rdev->min_mv); } /* * Get regulator voltage * * @rdev - pointer to rdev struct * Return milli volts if succeed, <0 else. */ int regulator_get_voltage(const struct rdev *rdev) { int ret; assert(rdev != NULL); VERBOSE("%s: get volt\n", rdev->desc->node_name); if (rdev->desc->ops->get_voltage == NULL) { return rdev->min_mv; } lock_driver(rdev); ret = rdev->desc->ops->get_voltage(rdev->desc); if (ret < 0) { ERROR("regul %s get voltage failed: err:%d\n", rdev->desc->node_name, ret); } unlock_driver(rdev); return ret; } /* * List regulator voltages * * @rdev - pointer to rdev struct * @levels - out: array of supported millitvolt levels from min to max value * @count - out: number of possible millivolt values * Return 0 if succeed, non 0 else. */ int regulator_list_voltages(const struct rdev *rdev, const uint16_t **levels, size_t *count) { int ret; size_t n; assert(rdev != NULL); assert(levels != NULL); assert(count != NULL); VERBOSE("%s: list volt\n", rdev->desc->node_name); if (rdev->desc->ops->list_voltages == NULL) { return -ENODEV; } lock_driver(rdev); ret = rdev->desc->ops->list_voltages(rdev->desc, levels, count); unlock_driver(rdev); if (ret < 0) { ERROR("regul %s list_voltages failed: err: %d\n", rdev->desc->node_name, ret); return ret; } /* * Reduce the possible values depending on min and max from device-tree */ n = *count; while ((n > 1U) && ((*levels)[n - 1U] > rdev->max_mv)) { n--; } /* Verify that max val is a valid value */ if (rdev->max_mv != (*levels)[n - 1]) { ERROR("regul %s: max value %u is invalid\n", rdev->desc->node_name, rdev->max_mv); return -EINVAL; } while ((n > 1U) && ((*levels[0U]) < rdev->min_mv)) { (*levels)++; n--; } /* Verify that min is not too high */ if (n == 0U) { ERROR("regul %s set min voltage is too high\n", rdev->desc->node_name); return -EINVAL; } /* Verify that min val is a valid vlue */ if (rdev->min_mv != (*levels)[0U]) { ERROR("regul %s: min value %u is invalid\n", rdev->desc->node_name, rdev->min_mv); return -EINVAL; } *count = n; VERBOSE("rdev->min_mv=%u rdev->max_mv=%u\n", rdev->min_mv, rdev->max_mv); return 0; } /* * Get regulator voltages range * * @rdev - pointer to rdev struct * @min_mv - out: min possible millivolt value * @max_mv - out: max possible millivolt value * Return 0 if succeed, non 0 else. */ void regulator_get_range(const struct rdev *rdev, uint16_t *min_mv, uint16_t *max_mv) { assert(rdev != NULL); if (min_mv != NULL) { *min_mv = rdev->min_mv; } if (max_mv != NULL) { *max_mv = rdev->max_mv; } } /* * Set regulator flag * * @rdev - pointer to rdev struct * @flag - flag value to set (eg: REGUL_OCP) * Return 0 if succeed, non 0 else. */ int regulator_set_flag(struct rdev *rdev, uint16_t flag) { int ret; /* check that only one bit is set on flag */ if (__builtin_popcount(flag) != 1) { return -EINVAL; } /* REGUL_ALWAYS_ON and REGUL_BOOT_ON are internal properties of the core */ if ((flag == REGUL_ALWAYS_ON) || (flag == REGUL_BOOT_ON)) { rdev->flags |= flag; return 0; } if (rdev->desc->ops->set_flag == NULL) { ERROR("%s can not set any flag\n", rdev->desc->node_name); return -ENODEV; } lock_driver(rdev); ret = rdev->desc->ops->set_flag(rdev->desc, flag); unlock_driver(rdev); if (ret != 0) { ERROR("%s: could not set flag %d ret=%d\n", rdev->desc->node_name, flag, ret); return ret; } rdev->flags |= flag; return 0; } static int parse_properties(const void *fdt, struct rdev *rdev, int node) { const fdt32_t *cuint; int ret; if (fdt_getprop(fdt, node, "regulator-always-on", NULL) != NULL) { VERBOSE("%s: set regulator-always-on\n", rdev->desc->node_name); ret = regulator_set_flag(rdev, REGUL_ALWAYS_ON); if (ret != 0) { return ret; } } cuint = fdt_getprop(fdt, node, "regulator-enable-ramp-delay", NULL); if (cuint != NULL) { rdev->enable_ramp_delay = fdt32_to_cpu(*cuint); VERBOSE("%s: enable_ramp_delay=%u\n", rdev->desc->node_name, rdev->enable_ramp_delay); } return 0; } /* * Parse the device-tree for a regulator * * Read min/max voltage from dt and check its validity * Read the properties, and call the driver to set flags * Read power supply phandle * Read and store low power mode states * * @rdev - pointer to rdev struct * @node - device-tree node offset of the regulator * Return 0 if disabled, 1 if enabled, <0 else. */ static int parse_dt(struct rdev *rdev, int node) { void *fdt; const fdt32_t *cuint; const uint16_t *levels; size_t size; int ret; VERBOSE("%s: parse dt\n", rdev->desc->node_name); if (fdt_get_address(&fdt) == 0) { return -ENOENT; } rdev->phandle = fdt_get_phandle(fdt, node); cuint = fdt_getprop(fdt, node, "regulator-min-microvolt", NULL); if (cuint != NULL) { uint16_t min_mv; min_mv = (uint16_t)(fdt32_to_cpu(*cuint) / 1000U); VERBOSE("%s: min_mv=%d\n", rdev->desc->node_name, (int)min_mv); if (min_mv <= rdev->max_mv) { rdev->min_mv = min_mv; } else { ERROR("%s: min_mv=%d is too high\n", rdev->desc->node_name, (int)min_mv); return -EINVAL; } } cuint = fdt_getprop(fdt, node, "regulator-max-microvolt", NULL); if (cuint != NULL) { uint16_t max_mv; max_mv = (uint16_t)(fdt32_to_cpu(*cuint) / 1000U); VERBOSE("%s: max_mv=%d\n", rdev->desc->node_name, (int)max_mv); if (max_mv >= rdev->min_mv) { rdev->max_mv = max_mv; } else { ERROR("%s: max_mv=%d is too low\n", rdev->desc->node_name, (int)max_mv); return -EINVAL; } } /* validate that min and max values can be used */ ret = regulator_list_voltages(rdev, &levels, &size); if ((ret != 0) && (ret != -ENODEV)) { return ret; } ret = parse_properties(fdt, rdev, node); if (ret != 0) { return ret; } return 0; } /* * Register a regulator driver in regulator framework. * Initialize voltage range from driver description * * @desc - pointer to the regulator description * @node - device-tree node offset of the regulator * Return 0 if succeed, non 0 else. */ int regulator_register(const struct regul_description *desc, int node) { struct rdev *rdev; assert(desc != NULL); VERBOSE("register %s\n", desc->node_name); for_each_rdev(rdev) { if (rdev->desc == NULL) { break; } } if (rdev > &rdev_array[PLAT_NB_RDEVS - 1U]) { WARN("Not enough place for regulators, PLAT_NB_RDEVS should be increased.\n"); return -ENOMEM; } rdev->desc = desc; rdev->enable_ramp_delay = rdev->desc->enable_ramp_delay; if (rdev->desc->ops->list_voltages != NULL) { int ret; const uint16_t *levels; size_t count; lock_driver(rdev); ret = rdev->desc->ops->list_voltages(rdev->desc, &levels, &count); unlock_driver(rdev); if (ret < 0) { ERROR("regul %s set state failed: err:%d\n", rdev->desc->node_name, ret); return ret; } rdev->min_mv = levels[0]; rdev->max_mv = levels[count - 1U]; } else { rdev->max_mv = UINT16_MAX; } return parse_dt(rdev, node); }