// SPDX-License-Identifier: GPL-2.0-or-later /* * Copyright (C) 2016 Maxime Ripard * Maxime Ripard */ #include #include #include "ccu_gate.h" #include "ccu_mp.h" static void ccu_mp_find_best(unsigned long parent, unsigned long rate, unsigned int max_m, unsigned int max_p, unsigned int *m, unsigned int *p) { unsigned long best_rate = 0; unsigned int best_m = 0, best_p = 0; unsigned int _m, _p; for (_p = 1; _p <= max_p; _p <<= 1) { for (_m = 1; _m <= max_m; _m++) { unsigned long tmp_rate = parent / _p / _m; if (tmp_rate > rate) continue; if ((rate - tmp_rate) < (rate - best_rate)) { best_rate = tmp_rate; best_m = _m; best_p = _p; } } } *m = best_m; *p = best_p; } static unsigned long ccu_mp_find_best_with_parent_adj(struct clk_hw *hw, unsigned long *parent, unsigned long rate, unsigned int max_m, unsigned int max_p) { unsigned long parent_rate_saved; unsigned long parent_rate, now; unsigned long best_rate = 0; unsigned int _m, _p, div; unsigned long maxdiv; parent_rate_saved = *parent; /* * The maximum divider we can use without overflowing * unsigned long in rate * m * p below */ maxdiv = max_m * max_p; maxdiv = min(ULONG_MAX / rate, maxdiv); for (_p = 1; _p <= max_p; _p <<= 1) { for (_m = 1; _m <= max_m; _m++) { div = _m * _p; if (div > maxdiv) break; if (rate * div == parent_rate_saved) { /* * It's the most ideal case if the requested * rate can be divided from parent clock without * needing to change parent rate, so return the * divider immediately. */ *parent = parent_rate_saved; return rate; } parent_rate = clk_hw_round_rate(hw, rate * div); now = parent_rate / div; if (now <= rate && now > best_rate) { best_rate = now; *parent = parent_rate; if (now == rate) return rate; } } } return best_rate; } static unsigned long ccu_mp_round_rate(struct ccu_mux_internal *mux, struct clk_hw *hw, unsigned long *parent_rate, unsigned long rate, void *data) { struct ccu_mp *cmp = data; unsigned int max_m, max_p; unsigned int m, p; if (cmp->common.features & CCU_FEATURE_FIXED_POSTDIV) rate *= cmp->fixed_post_div; max_m = cmp->m.max ?: 1 << cmp->m.width; max_p = cmp->p.max ?: 1 << ((1 << cmp->p.width) - 1); if (!(clk_hw_get_flags(hw) & CLK_SET_RATE_PARENT)) { ccu_mp_find_best(*parent_rate, rate, max_m, max_p, &m, &p); rate = *parent_rate / p / m; } else { rate = ccu_mp_find_best_with_parent_adj(hw, parent_rate, rate, max_m, max_p); } if (cmp->common.features & CCU_FEATURE_FIXED_POSTDIV) rate /= cmp->fixed_post_div; return rate; } static void ccu_mp_disable(struct clk_hw *hw) { struct ccu_mp *cmp = hw_to_ccu_mp(hw); return ccu_gate_helper_disable(&cmp->common, cmp->enable); } static int ccu_mp_enable(struct clk_hw *hw) { struct ccu_mp *cmp = hw_to_ccu_mp(hw); return ccu_gate_helper_enable(&cmp->common, cmp->enable); } static int ccu_mp_is_enabled(struct clk_hw *hw) { struct ccu_mp *cmp = hw_to_ccu_mp(hw); return ccu_gate_helper_is_enabled(&cmp->common, cmp->enable); } static unsigned long ccu_mp_recalc_rate(struct clk_hw *hw, unsigned long parent_rate) { struct ccu_mp *cmp = hw_to_ccu_mp(hw); unsigned long rate; unsigned int m, p; u32 reg; /* Adjust parent_rate according to pre-dividers */ parent_rate = ccu_mux_helper_apply_prediv(&cmp->common, &cmp->mux, -1, parent_rate); reg = readl(cmp->common.base + cmp->common.reg); m = reg >> cmp->m.shift; m &= (1 << cmp->m.width) - 1; m += cmp->m.offset; if (!m) m++; p = reg >> cmp->p.shift; p &= (1 << cmp->p.width) - 1; rate = (parent_rate >> p) / m; if (cmp->common.features & CCU_FEATURE_FIXED_POSTDIV) rate /= cmp->fixed_post_div; return rate; } static int ccu_mp_determine_rate(struct clk_hw *hw, struct clk_rate_request *req) { struct ccu_mp *cmp = hw_to_ccu_mp(hw); return ccu_mux_helper_determine_rate(&cmp->common, &cmp->mux, req, ccu_mp_round_rate, cmp); } static int ccu_mp_set_rate(struct clk_hw *hw, unsigned long rate, unsigned long parent_rate) { struct ccu_mp *cmp = hw_to_ccu_mp(hw); unsigned long flags; unsigned int max_m, max_p; unsigned int m, p; u32 reg; /* Adjust parent_rate according to pre-dividers */ parent_rate = ccu_mux_helper_apply_prediv(&cmp->common, &cmp->mux, -1, parent_rate); max_m = cmp->m.max ?: 1 << cmp->m.width; max_p = cmp->p.max ?: 1 << ((1 << cmp->p.width) - 1); /* Adjust target rate according to post-dividers */ if (cmp->common.features & CCU_FEATURE_FIXED_POSTDIV) rate = rate * cmp->fixed_post_div; ccu_mp_find_best(parent_rate, rate, max_m, max_p, &m, &p); spin_lock_irqsave(cmp->common.lock, flags); reg = readl(cmp->common.base + cmp->common.reg); reg &= ~GENMASK(cmp->m.width + cmp->m.shift - 1, cmp->m.shift); reg &= ~GENMASK(cmp->p.width + cmp->p.shift - 1, cmp->p.shift); reg |= (m - cmp->m.offset) << cmp->m.shift; reg |= ilog2(p) << cmp->p.shift; writel(reg, cmp->common.base + cmp->common.reg); spin_unlock_irqrestore(cmp->common.lock, flags); return 0; } static u8 ccu_mp_get_parent(struct clk_hw *hw) { struct ccu_mp *cmp = hw_to_ccu_mp(hw); return ccu_mux_helper_get_parent(&cmp->common, &cmp->mux); } static int ccu_mp_set_parent(struct clk_hw *hw, u8 index) { struct ccu_mp *cmp = hw_to_ccu_mp(hw); return ccu_mux_helper_set_parent(&cmp->common, &cmp->mux, index); } const struct clk_ops ccu_mp_ops = { .disable = ccu_mp_disable, .enable = ccu_mp_enable, .is_enabled = ccu_mp_is_enabled, .get_parent = ccu_mp_get_parent, .set_parent = ccu_mp_set_parent, .determine_rate = ccu_mp_determine_rate, .recalc_rate = ccu_mp_recalc_rate, .set_rate = ccu_mp_set_rate, }; /* * Support for MMC timing mode switching * * The MMC clocks on some SoCs support switching between old and * new timing modes. A platform specific API is provided to query * and set the timing mode on supported SoCs. * * In addition, a special class of ccu_mp_ops is provided, which * takes in to account the timing mode switch. When the new timing * mode is active, the clock output rate is halved. This new class * is a wrapper around the generic ccu_mp_ops. When clock rates * are passed through to ccu_mp_ops callbacks, they are doubled * if the new timing mode bit is set, to account for the post * divider. Conversely, when clock rates are passed back, they * are halved if the mode bit is set. */ static unsigned long ccu_mp_mmc_recalc_rate(struct clk_hw *hw, unsigned long parent_rate) { unsigned long rate = ccu_mp_recalc_rate(hw, parent_rate); struct ccu_common *cm = hw_to_ccu_common(hw); u32 val = readl(cm->base + cm->reg); if (val & CCU_MMC_NEW_TIMING_MODE) return rate / 2; return rate; } static int ccu_mp_mmc_determine_rate(struct clk_hw *hw, struct clk_rate_request *req) { struct ccu_common *cm = hw_to_ccu_common(hw); u32 val = readl(cm->base + cm->reg); int ret; /* adjust the requested clock rate */ if (val & CCU_MMC_NEW_TIMING_MODE) { req->rate *= 2; req->min_rate *= 2; req->max_rate *= 2; } ret = ccu_mp_determine_rate(hw, req); /* re-adjust the requested clock rate back */ if (val & CCU_MMC_NEW_TIMING_MODE) { req->rate /= 2; req->min_rate /= 2; req->max_rate /= 2; } return ret; } static int ccu_mp_mmc_set_rate(struct clk_hw *hw, unsigned long rate, unsigned long parent_rate) { struct ccu_common *cm = hw_to_ccu_common(hw); u32 val = readl(cm->base + cm->reg); if (val & CCU_MMC_NEW_TIMING_MODE) rate *= 2; return ccu_mp_set_rate(hw, rate, parent_rate); } const struct clk_ops ccu_mp_mmc_ops = { .disable = ccu_mp_disable, .enable = ccu_mp_enable, .is_enabled = ccu_mp_is_enabled, .get_parent = ccu_mp_get_parent, .set_parent = ccu_mp_set_parent, .determine_rate = ccu_mp_mmc_determine_rate, .recalc_rate = ccu_mp_mmc_recalc_rate, .set_rate = ccu_mp_mmc_set_rate, };