diff --git a/sys/dev/qcom_clk/qcom_clk_rcg2.c b/sys/dev/qcom_clk/qcom_clk_rcg2.c index b6ae03e02ced..999e2c00c900 100644 --- a/sys/dev/qcom_clk/qcom_clk_rcg2.c +++ b/sys/dev/qcom_clk/qcom_clk_rcg2.c @@ -1,662 +1,662 @@ /*- * Copyright (c) 2021 Adrian Chadd . * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include #include "qcom_clk_freqtbl.h" #include "qcom_clk_rcg2.h" #include "qcom_clk_rcg2_reg.h" #include "clkdev_if.h" #if 0 #define DPRINTF(dev, msg...) device_printf(dev, msg); #else #define DPRINTF(dev, msg...) #endif #define QCOM_CLK_RCG2_CFG_OFFSET(sc) \ ((sc)->cmd_rcgr + (sc)->cfg_offset + QCOM_CLK_RCG2_CFG_REG) #define QCOM_CLK_RCG2_CMD_REGISTER(sc) \ ((sc)->cmd_rcgr + QCOM_CLK_RCG2_CMD_REG) #define QCOM_CLK_RCG2_M_OFFSET(sc) \ ((sc)->cmd_rcgr + (sc)->cfg_offset + QCOM_CLK_RCG2_M_REG) #define QCOM_CLK_RCG2_N_OFFSET(sc) \ ((sc)->cmd_rcgr + (sc)->cfg_offset + QCOM_CLK_RCG2_N_REG) #define QCOM_CLK_RCG2_D_OFFSET(sc) \ ((sc)->cmd_rcgr + (sc)->cfg_offset + QCOM_CLK_RCG2_D_REG) struct qcom_clk_rcg2_sc { struct clknode *clknode; uint32_t cmd_rcgr; uint32_t hid_width; uint32_t mnd_width; int32_t safe_src_idx; uint32_t cfg_offset; int safe_pre_parent_idx; uint32_t flags; const struct qcom_clk_freq_tbl *freq_tbl; }; /* * Finish a clock update. * * This instructs the configuration to take effect. */ static bool qcom_clk_rcg2_update_config_locked(struct qcom_clk_rcg2_sc *sc) { uint32_t reg, count; /* * Send "update" to the controller. */ CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_CMD_REGISTER(sc), ®); reg |= QCOM_CLK_RCG2_CMD_UPDATE; CLKDEV_WRITE_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_CMD_REGISTER(sc), reg); wmb(); /* * Poll for completion of update. */ for (count = 0; count < 1000; count++) { CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_CMD_REGISTER(sc), ®); if ((reg & QCOM_CLK_RCG2_CMD_UPDATE) == 0) { return (true); } DELAY(10); rmb(); } CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_CMD_REGISTER(sc), ®); DPRINTF(clknode_get_device(sc->clknode), "%s: failed; reg=0x%08x\n", __func__, reg); return (false); } /* * Calculate the output frequency given an input frequency and the m/n:d * configuration. */ static uint64_t qcom_clk_rcg2_calc_rate(uint64_t rate, uint32_t mode, uint32_t m, uint32_t n, uint32_t hid_div) { if (hid_div != 0) { rate = rate * 2; rate = rate / (hid_div + 1); } /* Note: assume n is not 0 here; bad things happen if it is */ if (mode != 0) { rate = (rate * m) / n; } return (rate); } /* * The inverse of calc_rate() - calculate the required input frequency * given the desired output freqency and m/n:d configuration. */ static uint64_t qcom_clk_rcg2_calc_input_freq(uint64_t freq, uint32_t m, uint32_t n, uint32_t hid_div) { if (hid_div != 0) { freq = freq / 2; freq = freq * (hid_div + 1); } if (n != 0) { freq = (freq * n) / m; } return (freq); } static int qcom_clk_rcg2_recalc(struct clknode *clk, uint64_t *freq) { struct qcom_clk_rcg2_sc *sc; uint32_t cfg, m = 0, n = 0, hid_div = 0; uint32_t mode = 0, mask; sc = clknode_get_softc(clk); /* Read the MODE, CFG, M and N parameters */ CLKDEV_DEVICE_LOCK(clknode_get_device(sc->clknode)); CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_CFG_OFFSET(sc), &cfg); if (sc->mnd_width != 0) { mask = (1U << sc->mnd_width) - 1; CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_M_OFFSET(sc), &m); CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_N_OFFSET(sc), &n); m = m & mask; n = ~ n; n = n & mask; n = n + m; mode = (cfg & QCOM_CLK_RCG2_CFG_MODE_MASK) >> QCOM_CLK_RCG2_CFG_MODE_SHIFT; } CLKDEV_DEVICE_UNLOCK(clknode_get_device(sc->clknode)); /* Fetch the divisor */ mask = (1U << sc->hid_width) - 1; hid_div = (cfg >> QCOM_CLK_RCG2_CFG_SRC_DIV_SHIFT) & mask; /* Calculate the rate based on the parent rate and config */ *freq = qcom_clk_rcg2_calc_rate(*freq, mode, m, n, hid_div); return (0); } /* * configure the mn:d divisor, pre-divisor, and parent. */ static void qcom_clk_rcg2_set_config_locked(struct qcom_clk_rcg2_sc *sc, const struct qcom_clk_freq_tbl *f, int parent_idx) { uint32_t mask, reg; /* If we have MN:D, then update it */ if (sc->mnd_width != 0 && f->n != 0) { mask = (1U << sc->mnd_width) - 1; CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_M_OFFSET(sc), ®); reg &= ~mask; reg |= (f->m & mask); CLKDEV_WRITE_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_M_OFFSET(sc), reg); CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_N_OFFSET(sc), ®); reg &= ~mask; reg |= ((~(f->n - f->m)) & mask); CLKDEV_WRITE_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_N_OFFSET(sc), reg); CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_D_OFFSET(sc), ®); reg &= ~mask; reg |= ((~f->n) & mask); CLKDEV_WRITE_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_D_OFFSET(sc), reg); } mask = (1U << sc->hid_width) - 1; /* * Mask out register fields we're going to modify along with * the pre-divisor. */ mask |= QCOM_CLK_RCG2_CFG_SRC_SEL_MASK | QCOM_CLK_RCG2_CFG_MODE_MASK | QCOM_CLK_RCG2_CFG_HW_CLK_CTRL_MASK; CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_CFG_OFFSET(sc), ®); reg &= ~mask; /* Configure pre-divisor */ reg = reg | ((f->pre_div) << QCOM_CLK_RCG2_CFG_SRC_DIV_SHIFT); /* Configure parent clock */ reg = reg | (((parent_idx << QCOM_CLK_RCG2_CFG_SRC_SEL_SHIFT) & QCOM_CLK_RCG2_CFG_SRC_SEL_MASK)); /* Configure dual-edge if needed */ if (sc->mnd_width != 0 && f->n != 0 && (f->m != f->n)) reg |= QCOM_CLK_RCG2_CFG_MODE_DUAL_EDGE; CLKDEV_WRITE_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_CFG_OFFSET(sc), reg); } static int qcom_clk_rcg2_init(struct clknode *clk, device_t dev) { struct qcom_clk_rcg2_sc *sc; uint32_t reg; uint32_t idx; bool enabled __unused; sc = clknode_get_softc(clk); /* * Read the mux setting to set the right parent. * Whilst here, read the config to get whether we're enabled * or not. */ CLKDEV_DEVICE_LOCK(clknode_get_device(sc->clknode)); /* check if rcg2 root clock is enabled */ CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_CMD_REGISTER(sc), ®); if (reg & QCOM_CLK_RCG2_CMD_ROOT_OFF) enabled = false; else enabled = true; /* mux settings */ CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_CFG_OFFSET(sc), ®); CLKDEV_DEVICE_UNLOCK(clknode_get_device(sc->clknode)); idx = (reg & QCOM_CLK_RCG2_CFG_SRC_SEL_MASK) >> QCOM_CLK_RCG2_CFG_SRC_SEL_SHIFT; DPRINTF(clknode_get_device(sc->clknode), "%s: mux index %u, enabled=%d\n", __func__, idx, enabled); clknode_init_parent_idx(clk, idx); /* * If we could be sure our parent clocks existed here in the tree, * we could calculate our current frequency by fetching the parent * frequency and then do our divider math. Unfortunately that * currently isn't the case. */ return(0); } static int qcom_clk_rcg2_set_gate(struct clknode *clk, bool enable) { /* * For now this isn't supported; there's some support for * "shared" rcg2 nodes in the Qualcomm/upstream Linux trees but * it's not currently needed for the supported platforms. */ return (0); } /* * Program the parent index. * * This doesn't do the update. It also must be called with the device * lock held. */ static void qcom_clk_rcg2_set_parent_index_locked(struct qcom_clk_rcg2_sc *sc, uint32_t index) { uint32_t reg; CLKDEV_READ_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_CFG_OFFSET(sc), ®); reg = reg & ~QCOM_CLK_RCG2_CFG_SRC_SEL_MASK; reg = reg | (((index << QCOM_CLK_RCG2_CFG_SRC_SEL_SHIFT) & QCOM_CLK_RCG2_CFG_SRC_SEL_MASK)); CLKDEV_WRITE_4(clknode_get_device(sc->clknode), QCOM_CLK_RCG2_CFG_OFFSET(sc), reg); } /* * Set frequency * * fin - the parent frequency, if exists * fout - starts as the requested frequency, ends with the configured * or dry-run frequency * Flags - CLK_SET_DRYRUN, CLK_SET_ROUND_UP, CLK_SET_ROUND_DOWN * retval - 0, ERANGE */ static int qcom_clk_rcg2_set_freq(struct clknode *clk, uint64_t fin, uint64_t *fout, int flags, int *stop) { struct qcom_clk_rcg2_sc *sc; const struct qcom_clk_freq_tbl *f; const char **parent_names; uint64_t p_freq, p_clk_freq; int parent_cnt; struct clknode *p_clk; int i; sc = clknode_get_softc(clk); /* * Find a suitable frequency in the frequency table. * * TODO: should pay attention to ROUND_UP / ROUND_DOWN and add * a freqtbl method to handle both accordingly. */ f = qcom_clk_freq_tbl_lookup(sc->freq_tbl, *fout); if (f == NULL) { device_printf(clknode_get_device(sc->clknode), "%s: no suitable freqtbl entry found for freq %llu\n", __func__, *fout); return (ERANGE); } /* * Find the parent index for the given parent clock. * Abort if we can't actually find it. * * XXX TODO: this should be a clk API call! */ parent_cnt = clknode_get_parents_num(clk); parent_names = clknode_get_parent_names(clk); for (i = 0; i < parent_cnt; i++) { if (parent_names[i] == NULL) continue; if (strcmp(parent_names[i], f->parent) == 0) break; } if (i >= parent_cnt) { device_printf(clknode_get_device(sc->clknode), "%s: couldn't find suitable parent?\n", __func__); return (ENXIO); } /* * If we aren't setting the parent clock, then we need * to just program the new parent clock in and update. * (or for DRYRUN just skip that and return the new * frequency.) */ if ((sc->flags & QCOM_CLK_RCG2_FLAGS_SET_RATE_PARENT) == 0) { if (flags & CLK_SET_DRYRUN) { *fout = f->freq; return (0); } if (sc->safe_pre_parent_idx > -1) { DPRINTF(clknode_get_device(sc->clknode), "%s: setting to safe parent idx %d\n", __func__, sc->safe_pre_parent_idx); CLKDEV_DEVICE_LOCK(clknode_get_device(sc->clknode)); qcom_clk_rcg2_set_parent_index_locked(sc, sc->safe_pre_parent_idx); DPRINTF(clknode_get_device(sc->clknode), "%s: safe parent: updating config\n", __func__); if (! qcom_clk_rcg2_update_config_locked(sc)) { CLKDEV_DEVICE_UNLOCK(clknode_get_device(sc->clknode)); DPRINTF(clknode_get_device(sc->clknode), "%s: error updating config\n", __func__); return (ENXIO); } CLKDEV_DEVICE_UNLOCK(clknode_get_device(sc->clknode)); DPRINTF(clknode_get_device(sc->clknode), "%s: safe parent: done\n", __func__); clknode_set_parent_by_idx(sc->clknode, sc->safe_pre_parent_idx); } /* Program parent index, then schedule update */ CLKDEV_DEVICE_LOCK(clknode_get_device(sc->clknode)); qcom_clk_rcg2_set_parent_index_locked(sc, i); if (! qcom_clk_rcg2_update_config_locked(sc)) { CLKDEV_DEVICE_UNLOCK(clknode_get_device(sc->clknode)); device_printf(clknode_get_device(sc->clknode), "%s: couldn't program in parent idx %u!\n", __func__, i); return (ENXIO); } CLKDEV_DEVICE_UNLOCK(clknode_get_device(sc->clknode)); clknode_set_parent_by_idx(sc->clknode, i); *fout = f->freq; return (0); } /* * If we /are/ setting the parent clock, then we need * to determine what frequency we need the parent to * be, and then reconfigure the parent to the new * frequency, and then change our parent. * * (Again, if we're doing DRYRUN, just skip that * and return the new frequency.) */ p_clk = clknode_find_by_name(f->parent); if (p_clk == NULL) { device_printf(clknode_get_device(sc->clknode), "%s: couldn't find parent clk (%s)\n", __func__, f->parent); return (ENXIO); } /* * Calculate required frequency from said parent clock to * meet the needs of our target clock. */ p_freq = qcom_clk_rcg2_calc_input_freq(f->freq, f->m, f->n, f->pre_div); DPRINTF(clknode_get_device(sc->clknode), "%s: request %llu, parent %s freq %llu, parent freq %llu\n", __func__, *fout, f->parent, f->freq, p_freq); /* * To ensure glitch-free operation on some clocks, set it to * a safe parent before programming our divisor and the parent * clock configuration. Then once it's done, flip the parent * to the new parent. * * If we're doing a dry-run then we don't need to re-parent the * clock just yet! */ if (((flags & CLK_SET_DRYRUN) == 0) && (sc->safe_pre_parent_idx > -1)) { DPRINTF(clknode_get_device(sc->clknode), "%s: setting to safe parent idx %d\n", __func__, sc->safe_pre_parent_idx); CLKDEV_DEVICE_LOCK(clknode_get_device(sc->clknode)); qcom_clk_rcg2_set_parent_index_locked(sc, sc->safe_pre_parent_idx); DPRINTF(clknode_get_device(sc->clknode), "%s: safe parent: updating config\n", __func__); if (! qcom_clk_rcg2_update_config_locked(sc)) { CLKDEV_DEVICE_UNLOCK(clknode_get_device(sc->clknode)); DPRINTF(clknode_get_device(sc->clknode), "%s: error updating config\n", __func__); return (ENXIO); } CLKDEV_DEVICE_UNLOCK(clknode_get_device(sc->clknode)); DPRINTF(clknode_get_device(sc->clknode), "%s: safe parent: done\n", __func__); clknode_set_parent_by_idx(sc->clknode, sc->safe_pre_parent_idx); } /* * Set the parent frequency before we change our mux and divisor * configuration. */ if (clknode_get_freq(p_clk, &p_clk_freq) != 0) { device_printf(clknode_get_device(sc->clknode), "%s: couldn't get freq for parent clock %s\n", __func__, f->parent); return (ENXIO); } if (p_clk_freq != p_freq) { uint64_t n_freq; int rv; /* * If we're doing a dryrun then call test_freq() not set_freq(). * That way we get the frequency back that we would be set to. * * If we're not doing a dry run then set the frequency, then * call get_freq to get what it was set to. */ if (flags & CLK_SET_DRYRUN) { n_freq = p_freq; rv = clknode_test_freq(p_clk, n_freq, flags, 0, &p_freq); } else { rv = clknode_set_freq(p_clk, p_freq, flags, 0); } if (rv != 0) { device_printf(clknode_get_device(sc->clknode), "%s: couldn't set parent clock %s frequency to " "%llu\n", __func__, f->parent, p_freq); return (ENXIO); } /* Frequency was set, fetch what it was set to */ if ((flags & CLK_SET_DRYRUN) == 0) { rv = clknode_get_freq(p_clk, &p_freq); if (rv != 0) { device_printf(clknode_get_device(sc->clknode), "%s: couldn't get parent frequency", __func__); return (ENXIO); } } } DPRINTF(clknode_get_device(sc->clknode), - "%s: requsted freq=%llu, target freq=%llu," + "%s: requested freq=%llu, target freq=%llu," " parent choice=%s, parent_freq=%llu\n", __func__, *fout, f->freq, f->parent, p_freq); /* * Set the parent node, the parent programming and the divisor * config. Because they're done together, we don't go via * a mux method on this node. */ /* * Program the divisor and parent. */ if ((flags & CLK_SET_DRYRUN) == 0) { CLKDEV_DEVICE_LOCK(clknode_get_device(sc->clknode)); qcom_clk_rcg2_set_config_locked(sc, f, i); if (! qcom_clk_rcg2_update_config_locked(sc)) { CLKDEV_DEVICE_UNLOCK(clknode_get_device(sc->clknode)); device_printf(clknode_get_device(sc->clknode), "%s: couldn't program in divisor, help!\n", __func__); return (ENXIO); } CLKDEV_DEVICE_UNLOCK(clknode_get_device(sc->clknode)); clknode_set_parent_by_idx(sc->clknode, i); } /* * p_freq is now the frequency that the parent /is/ set to. * (Or would be set to for a dry run.) * * Calculate what the eventual frequency would be, we'll want * this to return when we're done - and again, if it's a dryrun, * don't set anything up. This doesn't rely on the register * contents. */ *fout = qcom_clk_rcg2_calc_rate(p_freq, (f->n == 0 ? 0 : 1), f->m, f->n, f->pre_div); return (0); } static clknode_method_t qcom_clk_rcg2_methods[] = { /* Device interface */ CLKNODEMETHOD(clknode_init, qcom_clk_rcg2_init), CLKNODEMETHOD(clknode_recalc_freq, qcom_clk_rcg2_recalc), CLKNODEMETHOD(clknode_set_gate, qcom_clk_rcg2_set_gate), CLKNODEMETHOD(clknode_set_freq, qcom_clk_rcg2_set_freq), CLKNODEMETHOD_END }; DEFINE_CLASS_1(qcom_clk_fepll, qcom_clk_rcg2_class, qcom_clk_rcg2_methods, sizeof(struct qcom_clk_rcg2_sc), clknode_class); int qcom_clk_rcg2_register(struct clkdom *clkdom, struct qcom_clk_rcg2_def *clkdef) { struct clknode *clk; struct qcom_clk_rcg2_sc *sc; /* * Right now the rcg2 code isn't supporting turning off the clock * or limiting it to the lowest parent clock. But, do set the * flags appropriately. */ if (clkdef->flags & QCOM_CLK_RCG2_FLAGS_CRITICAL) clkdef->clkdef.flags |= CLK_NODE_CANNOT_STOP; clk = clknode_create(clkdom, &qcom_clk_rcg2_class, &clkdef->clkdef); if (clk == NULL) return (1); sc = clknode_get_softc(clk); sc->clknode = clk; sc->cmd_rcgr = clkdef->cmd_rcgr; sc->hid_width = clkdef->hid_width; sc->mnd_width = clkdef->mnd_width; sc->safe_src_idx = clkdef->safe_src_idx; sc->safe_pre_parent_idx = clkdef->safe_pre_parent_idx; sc->cfg_offset = clkdef->cfg_offset; sc->flags = clkdef->flags; sc->freq_tbl = clkdef->freq_tbl; clknode_register(clkdom, clk); return (0); }