Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Conor Dooley | 1683 | 100.00% | 1 | 100.00% |
Total | 1683 | 1 |
// SPDX-License-Identifier: GPL-2.0 /* * corePWM driver for Microchip "soft" FPGA IP cores. * * Copyright (c) 2021-2023 Microchip Corporation. All rights reserved. * Author: Conor Dooley <conor.dooley@microchip.com> * Documentation: * https://www.microsemi.com/document-portal/doc_download/1245275-corepwm-hb * * Limitations: * - If the IP block is configured without "shadow registers", all register * writes will take effect immediately, causing glitches on the output. * If shadow registers *are* enabled, setting the "SYNC_UPDATE" register * notifies the core that it needs to update the registers defining the * waveform from the contents of the "shadow registers". Otherwise, changes * will take effective immediately, even for those channels. * As setting the period/duty cycle takes 4 register writes, there is a window * in which this races against the start of a new period. * - The IP block has no concept of a duty cycle, only rising/falling edges of * the waveform. Unfortunately, if the rising & falling edges registers have * the same value written to them the IP block will do whichever of a rising * or a falling edge is possible. I.E. a 50% waveform at twice the requested * period. Therefore to get a 0% waveform, the output is set the max high/low * time depending on polarity. * If the duty cycle is 0%, and the requested period is less than the * available period resolution, this will manifest as a ~100% waveform (with * some output glitches) rather than 50%. * - The PWM period is set for the whole IP block not per channel. The driver * will only change the period if no other PWM output is enabled. */ #include <linux/clk.h> #include <linux/delay.h> #include <linux/err.h> #include <linux/io.h> #include <linux/ktime.h> #include <linux/math.h> #include <linux/module.h> #include <linux/mutex.h> #include <linux/of_device.h> #include <linux/platform_device.h> #include <linux/pwm.h> #define MCHPCOREPWM_PRESCALE_MAX 0xff #define MCHPCOREPWM_PERIOD_STEPS_MAX 0xfe #define MCHPCOREPWM_PERIOD_MAX 0xff00 #define MCHPCOREPWM_PRESCALE 0x00 #define MCHPCOREPWM_PERIOD 0x04 #define MCHPCOREPWM_EN(i) (0x08 + 0x04 * (i)) /* 0x08, 0x0c */ #define MCHPCOREPWM_POSEDGE(i) (0x10 + 0x08 * (i)) /* 0x10, 0x18, ..., 0x88 */ #define MCHPCOREPWM_NEGEDGE(i) (0x14 + 0x08 * (i)) /* 0x14, 0x1c, ..., 0x8c */ #define MCHPCOREPWM_SYNC_UPD 0xe4 #define MCHPCOREPWM_TIMEOUT_MS 100u struct mchp_core_pwm_chip { struct pwm_chip chip; struct clk *clk; void __iomem *base; struct mutex lock; /* protects the shared period */ ktime_t update_timestamp; u32 sync_update_mask; u16 channel_enabled; }; static inline struct mchp_core_pwm_chip *to_mchp_core_pwm(struct pwm_chip *chip) { return container_of(chip, struct mchp_core_pwm_chip, chip); } static void mchp_core_pwm_enable(struct pwm_chip *chip, struct pwm_device *pwm, bool enable, u64 period) { struct mchp_core_pwm_chip *mchp_core_pwm = to_mchp_core_pwm(chip); u8 channel_enable, reg_offset, shift; /* * There are two adjacent 8 bit control regs, the lower reg controls * 0-7 and the upper reg 8-15. Check if the pwm is in the upper reg * and if so, offset by the bus width. */ reg_offset = MCHPCOREPWM_EN(pwm->hwpwm >> 3); shift = pwm->hwpwm & 7; channel_enable = readb_relaxed(mchp_core_pwm->base + reg_offset); channel_enable &= ~(1 << shift); channel_enable |= (enable << shift); writel_relaxed(channel_enable, mchp_core_pwm->base + reg_offset); mchp_core_pwm->channel_enabled &= ~BIT(pwm->hwpwm); mchp_core_pwm->channel_enabled |= enable << pwm->hwpwm; /* * The updated values will not appear on the bus until they have been * applied to the waveform at the beginning of the next period. * This is a NO-OP if the channel does not have shadow registers. */ if (mchp_core_pwm->sync_update_mask & (1 << pwm->hwpwm)) mchp_core_pwm->update_timestamp = ktime_add_ns(ktime_get(), period); } static void mchp_core_pwm_wait_for_sync_update(struct mchp_core_pwm_chip *mchp_core_pwm, unsigned int channel) { /* * If a shadow register is used for this PWM channel, and iff there is * a pending update to the waveform, we must wait for it to be applied * before attempting to read its state. Reading the registers yields * the currently implemented settings & the new ones are only readable * once the current period has ended. */ if (mchp_core_pwm->sync_update_mask & (1 << channel)) { ktime_t current_time = ktime_get(); s64 remaining_ns; u32 delay_us; remaining_ns = ktime_to_ns(ktime_sub(mchp_core_pwm->update_timestamp, current_time)); /* * If the update has gone through, don't bother waiting for * obvious reasons. Otherwise wait around for an appropriate * amount of time for the update to go through. */ if (remaining_ns <= 0) return; delay_us = DIV_ROUND_UP_ULL(remaining_ns, NSEC_PER_USEC); fsleep(delay_us); } } static u64 mchp_core_pwm_calc_duty(const struct pwm_state *state, u64 clk_rate, u8 prescale, u8 period_steps) { u64 duty_steps, tmp; /* * Calculate the duty cycle in multiples of the prescaled period: * duty_steps = duty_in_ns / step_in_ns * step_in_ns = (prescale * NSEC_PER_SEC) / clk_rate * The code below is rearranged slightly to only divide once. */ tmp = (((u64)prescale) + 1) * NSEC_PER_SEC; duty_steps = mul_u64_u64_div_u64(state->duty_cycle, clk_rate, tmp); return duty_steps; } static void mchp_core_pwm_apply_duty(struct pwm_chip *chip, struct pwm_device *pwm, const struct pwm_state *state, u64 duty_steps, u16 period_steps) { struct mchp_core_pwm_chip *mchp_core_pwm = to_mchp_core_pwm(chip); u8 posedge, negedge; u8 first_edge = 0, second_edge = duty_steps; /* * Setting posedge == negedge doesn't yield a constant output, * so that's an unsuitable setting to model duty_steps = 0. * In that case set the unwanted edge to a value that never * triggers. */ if (duty_steps == 0) first_edge = period_steps + 1; if (state->polarity == PWM_POLARITY_INVERSED) { negedge = first_edge; posedge = second_edge; } else { posedge = first_edge; negedge = second_edge; } /* * Set the sync bit which ensures that periods that already started are * completed unaltered. At each counter reset event the values are * updated from the shadow registers. */ writel_relaxed(posedge, mchp_core_pwm->base + MCHPCOREPWM_POSEDGE(pwm->hwpwm)); writel_relaxed(negedge, mchp_core_pwm->base + MCHPCOREPWM_NEGEDGE(pwm->hwpwm)); } static int mchp_core_pwm_calc_period(const struct pwm_state *state, unsigned long clk_rate, u16 *prescale, u16 *period_steps) { u64 tmp; /* * Calculate the period cycles and prescale values. * The registers are each 8 bits wide & multiplied to compute the period * using the formula: * (prescale + 1) * (period_steps + 1) * period = ------------------------------------- * clk_rate * so the maximum period that can be generated is 0x10000 times the * period of the input clock. * However, due to the design of the "hardware", it is not possible to * attain a 100% duty cycle if the full range of period_steps is used. * Therefore period_steps is restricted to 0xfe and the maximum multiple * of the clock period attainable is (0xff + 1) * (0xfe + 1) = 0xff00 * * The prescale and period_steps registers operate similarly to * CLK_DIVIDER_ONE_BASED, where the value used by the hardware is that * in the register plus one. * It's therefore not possible to set a period lower than 1/clk_rate, so * if tmp is 0, abort. Without aborting, we will set a period that is * greater than that requested and, more importantly, will trigger the * neg-/pos-edge issue described in the limitations. */ tmp = mul_u64_u64_div_u64(state->period, clk_rate, NSEC_PER_SEC); if (tmp >= MCHPCOREPWM_PERIOD_MAX) { *prescale = MCHPCOREPWM_PRESCALE_MAX; *period_steps = MCHPCOREPWM_PERIOD_STEPS_MAX; return 0; } /* * There are multiple strategies that could be used to choose the * prescale & period_steps values. * Here the idea is to pick values so that the selection of duty cycles * is as finegrain as possible, while also keeping the period less than * that requested. * * A simple way to satisfy the first condition is to always set * period_steps to its maximum value. This neatly also satisfies the * second condition too, since using the maximum value of period_steps * to calculate prescale actually calculates its upper bound. * Integer division will ensure a round down, so the period will thereby * always be less than that requested. * * The downside of this approach is a significant degree of inaccuracy, * especially as tmp approaches integer multiples of * MCHPCOREPWM_PERIOD_STEPS_MAX. * * As we must produce a period less than that requested, and for the * sake of creating a simple algorithm, disallow small values of tmp * that would need special handling. */ if (tmp < MCHPCOREPWM_PERIOD_STEPS_MAX + 1) return -EINVAL; /* * This "optimal" value for prescale is be calculated using the maximum * permitted value of period_steps, 0xfe. * * period * clk_rate * prescale = ------------------------- - 1 * NSEC_PER_SEC * (0xfe + 1) * * * period * clk_rate * ------------------- was precomputed as `tmp` * NSEC_PER_SEC */ *prescale = ((u16)tmp) / (MCHPCOREPWM_PERIOD_STEPS_MAX + 1) - 1; /* * period_steps can be computed from prescale: * period * clk_rate * period_steps = ----------------------------- - 1 * NSEC_PER_SEC * (prescale + 1) * * However, in this approximation, we simply use the maximum value that * was used to compute prescale. */ *period_steps = MCHPCOREPWM_PERIOD_STEPS_MAX; return 0; } static int mchp_core_pwm_apply_locked(struct pwm_chip *chip, struct pwm_device *pwm, const struct pwm_state *state) { struct mchp_core_pwm_chip *mchp_core_pwm = to_mchp_core_pwm(chip); bool period_locked; unsigned long clk_rate; u64 duty_steps; u16 prescale, period_steps; int ret; if (!state->enabled) { mchp_core_pwm_enable(chip, pwm, false, pwm->state.period); return 0; } /* * If clk_rate is too big, the following multiplication might overflow. * However this is implausible, as the fabric of current FPGAs cannot * provide clocks at a rate high enough. */ clk_rate = clk_get_rate(mchp_core_pwm->clk); if (clk_rate >= NSEC_PER_SEC) return -EINVAL; ret = mchp_core_pwm_calc_period(state, clk_rate, &prescale, &period_steps); if (ret) return ret; /* * If the only thing that has changed is the duty cycle or the polarity, * we can shortcut the calculations and just compute/apply the new duty * cycle pos & neg edges * As all the channels share the same period, do not allow it to be * changed if any other channels are enabled. * If the period is locked, it may not be possible to use a period * less than that requested. In that case, we just abort. */ period_locked = mchp_core_pwm->channel_enabled & ~(1 << pwm->hwpwm); if (period_locked) { u16 hw_prescale; u16 hw_period_steps; hw_prescale = readb_relaxed(mchp_core_pwm->base + MCHPCOREPWM_PRESCALE); hw_period_steps = readb_relaxed(mchp_core_pwm->base + MCHPCOREPWM_PERIOD); if ((period_steps + 1) * (prescale + 1) < (hw_period_steps + 1) * (hw_prescale + 1)) return -EINVAL; /* * It is possible that something could have set the period_steps * register to 0xff, which would prevent us from setting a 100% * or 0% relative duty cycle, as explained above in * mchp_core_pwm_calc_period(). * The period is locked and we cannot change this, so we abort. */ if (hw_period_steps == MCHPCOREPWM_PERIOD_STEPS_MAX) return -EINVAL; prescale = hw_prescale; period_steps = hw_period_steps; } duty_steps = mchp_core_pwm_calc_duty(state, clk_rate, prescale, period_steps); /* * Because the period is not per channel, it is possible that the * requested duty cycle is longer than the period, in which case cap it * to the period, IOW a 100% duty cycle. */ if (duty_steps > period_steps) duty_steps = period_steps + 1; if (!period_locked) { writel_relaxed(prescale, mchp_core_pwm->base + MCHPCOREPWM_PRESCALE); writel_relaxed(period_steps, mchp_core_pwm->base + MCHPCOREPWM_PERIOD); } mchp_core_pwm_apply_duty(chip, pwm, state, duty_steps, period_steps); mchp_core_pwm_enable(chip, pwm, true, pwm->state.period); return 0; } static int mchp_core_pwm_apply(struct pwm_chip *chip, struct pwm_device *pwm, const struct pwm_state *state) { struct mchp_core_pwm_chip *mchp_core_pwm = to_mchp_core_pwm(chip); int ret; mutex_lock(&mchp_core_pwm->lock); mchp_core_pwm_wait_for_sync_update(mchp_core_pwm, pwm->hwpwm); ret = mchp_core_pwm_apply_locked(chip, pwm, state); mutex_unlock(&mchp_core_pwm->lock); return ret; } static int mchp_core_pwm_get_state(struct pwm_chip *chip, struct pwm_device *pwm, struct pwm_state *state) { struct mchp_core_pwm_chip *mchp_core_pwm = to_mchp_core_pwm(chip); u64 rate; u16 prescale, period_steps; u8 duty_steps, posedge, negedge; mutex_lock(&mchp_core_pwm->lock); mchp_core_pwm_wait_for_sync_update(mchp_core_pwm, pwm->hwpwm); if (mchp_core_pwm->channel_enabled & (1 << pwm->hwpwm)) state->enabled = true; else state->enabled = false; rate = clk_get_rate(mchp_core_pwm->clk); /* * Calculating the period: * The registers are each 8 bits wide & multiplied to compute the period * using the formula: * (prescale + 1) * (period_steps + 1) * period = ------------------------------------- * clk_rate * * Note: * The prescale and period_steps registers operate similarly to * CLK_DIVIDER_ONE_BASED, where the value used by the hardware is that * in the register plus one. */ prescale = readb_relaxed(mchp_core_pwm->base + MCHPCOREPWM_PRESCALE); period_steps = readb_relaxed(mchp_core_pwm->base + MCHPCOREPWM_PERIOD); state->period = (period_steps + 1) * (prescale + 1); state->period *= NSEC_PER_SEC; state->period = DIV64_U64_ROUND_UP(state->period, rate); posedge = readb_relaxed(mchp_core_pwm->base + MCHPCOREPWM_POSEDGE(pwm->hwpwm)); negedge = readb_relaxed(mchp_core_pwm->base + MCHPCOREPWM_NEGEDGE(pwm->hwpwm)); mutex_unlock(&mchp_core_pwm->lock); if (negedge == posedge) { state->duty_cycle = state->period; state->period *= 2; } else { duty_steps = abs((s16)posedge - (s16)negedge); state->duty_cycle = duty_steps * (prescale + 1) * NSEC_PER_SEC; state->duty_cycle = DIV64_U64_ROUND_UP(state->duty_cycle, rate); } state->polarity = negedge < posedge ? PWM_POLARITY_INVERSED : PWM_POLARITY_NORMAL; return 0; } static const struct pwm_ops mchp_core_pwm_ops = { .apply = mchp_core_pwm_apply, .get_state = mchp_core_pwm_get_state, .owner = THIS_MODULE, }; static const struct of_device_id mchp_core_of_match[] = { { .compatible = "microchip,corepwm-rtl-v4", }, { /* sentinel */ } }; MODULE_DEVICE_TABLE(of, mchp_core_of_match); static int mchp_core_pwm_probe(struct platform_device *pdev) { struct mchp_core_pwm_chip *mchp_core_pwm; struct resource *regs; int ret; mchp_core_pwm = devm_kzalloc(&pdev->dev, sizeof(*mchp_core_pwm), GFP_KERNEL); if (!mchp_core_pwm) return -ENOMEM; mchp_core_pwm->base = devm_platform_get_and_ioremap_resource(pdev, 0, ®s); if (IS_ERR(mchp_core_pwm->base)) return PTR_ERR(mchp_core_pwm->base); mchp_core_pwm->clk = devm_clk_get_enabled(&pdev->dev, NULL); if (IS_ERR(mchp_core_pwm->clk)) return dev_err_probe(&pdev->dev, PTR_ERR(mchp_core_pwm->clk), "failed to get PWM clock\n"); if (of_property_read_u32(pdev->dev.of_node, "microchip,sync-update-mask", &mchp_core_pwm->sync_update_mask)) mchp_core_pwm->sync_update_mask = 0; mutex_init(&mchp_core_pwm->lock); mchp_core_pwm->chip.dev = &pdev->dev; mchp_core_pwm->chip.ops = &mchp_core_pwm_ops; mchp_core_pwm->chip.npwm = 16; mchp_core_pwm->channel_enabled = readb_relaxed(mchp_core_pwm->base + MCHPCOREPWM_EN(0)); mchp_core_pwm->channel_enabled |= readb_relaxed(mchp_core_pwm->base + MCHPCOREPWM_EN(1)) << 8; /* * Enable synchronous update mode for all channels for which shadow * registers have been synthesised. */ writel_relaxed(1U, mchp_core_pwm->base + MCHPCOREPWM_SYNC_UPD); mchp_core_pwm->update_timestamp = ktime_get(); ret = devm_pwmchip_add(&pdev->dev, &mchp_core_pwm->chip); if (ret) return dev_err_probe(&pdev->dev, ret, "Failed to add pwmchip\n"); return 0; } static struct platform_driver mchp_core_pwm_driver = { .driver = { .name = "mchp-core-pwm", .of_match_table = mchp_core_of_match, }, .probe = mchp_core_pwm_probe, }; module_platform_driver(mchp_core_pwm_driver); MODULE_LICENSE("GPL"); MODULE_AUTHOR("Conor Dooley <conor.dooley@microchip.com>"); MODULE_DESCRIPTION("corePWM driver for Microchip FPGAs");
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