linux/drivers/clk/ti/clkt_dpll.c

372 lines
10 KiB
C
Raw Normal View History

// SPDX-License-Identifier: GPL-2.0-only
/*
* OMAP2/3/4 DPLL clock functions
*
* Copyright (C) 2005-2008 Texas Instruments, Inc.
* Copyright (C) 2004-2010 Nokia Corporation
*
* Contacts:
* Richard Woodruff <r-woodruff2@ti.com>
* Paul Walmsley
*/
#undef DEBUG
#include <linux/kernel.h>
#include <linux/errno.h>
#include <linux/clk.h>
#include <linux/clk-provider.h>
#include <linux/io.h>
#include <linux/clk/ti.h>
#include <asm/div64.h>
#include "clock.h"
/* DPLL rate rounding: minimum DPLL multiplier, divider values */
OMAP2/3/4 clock: fix DPLL multiplier value errors; also copyrights, includes, documentation The maximum DPLL multiplier (M) values for OMAP2xxx and OMAP3xxx are one increment higher than they should be. See for example the OMAP242x TRM Rev X Section 5.10.6 "Clock Generator Registers" and the OMAP36xx TRM Rev C Table 3-202 "CM_CLKSEL1_PLL". Programming a 0 into the DPLL's M register bitfield is valid for OMAP2/3 and indicates that the DPLL should enter MN-bypass mode. Also, increase the minimum multiplier (M) value for the DPLL rate rounding code from 1 to 2, to ensure that it does not inadvertently put the DPLL into bypass. Note that the register documentation in the OMAP2xxx and OMAP3xxx TRMs does not make clear that the actual DPLL divider value (the "N") is the content of the appropriate register bitfield for the N value, _plus one_. (In other words, an N register bitfield of 0 indicates a DPLL divider value of 1.) This is only clearly documented in the OMAP4430 TRM, in, for example, OMAP4430 TRM Rev A Table 3-1167 "CM_CLKSEL_DPLL_USB". While here, update copyrights, add kerneldoc for struct dpll_data, drop the unused struct dpll_data.max_tolerance field, remove some unnecessary #includes in DPLL-related code, and replace the #include of <linux/module.h> with <linux/list.h>, which is what was really needed. The OMAP4 clock autogenerator script has been updated accordingly. Signed-off-by: Paul Walmsley <paul@pwsan.com> Cc: Benoît Cousson <b-cousson@ti.com> Cc: Rajendra Nayak <rnayak@ti.com>
2010-02-23 13:09:12 +08:00
#define DPLL_MIN_MULTIPLIER 2
#define DPLL_MIN_DIVIDER 1
/* Possible error results from _dpll_test_mult */
#define DPLL_MULT_UNDERFLOW -1
/*
* Scale factor to mitigate roundoff errors in DPLL rate rounding.
* The higher the scale factor, the greater the risk of arithmetic overflow,
* but the closer the rounded rate to the target rate. DPLL_SCALE_FACTOR
* must be a power of DPLL_SCALE_BASE.
*/
#define DPLL_SCALE_FACTOR 64
#define DPLL_SCALE_BASE 2
#define DPLL_ROUNDING_VAL ((DPLL_SCALE_BASE / 2) * \
(DPLL_SCALE_FACTOR / DPLL_SCALE_BASE))
/*
* DPLL valid Fint frequency range for OMAP36xx and OMAP4xxx.
* From device data manual section 4.3 "DPLL and DLL Specifications".
*/
#define OMAP3PLUS_DPLL_FINT_JTYPE_MIN 500000
#define OMAP3PLUS_DPLL_FINT_JTYPE_MAX 2500000
/* _dpll_test_fint() return codes */
#define DPLL_FINT_UNDERFLOW -1
#define DPLL_FINT_INVALID -2
/* Private functions */
/*
* _dpll_test_fint - test whether an Fint value is valid for the DPLL
* @clk: DPLL struct clk to test
* @n: divider value (N) to test
*
* Tests whether a particular divider @n will result in a valid DPLL
* internal clock frequency Fint. See the 34xx TRM 4.7.6.2 "DPLL Jitter
* Correction". Returns 0 if OK, -1 if the enclosing loop can terminate
* (assuming that it is counting N upwards), or -2 if the enclosing loop
* should skip to the next iteration (again assuming N is increasing).
*/
static int _dpll_test_fint(struct clk_hw_omap *clk, unsigned int n)
{
struct dpll_data *dd;
long fint, fint_min, fint_max;
int ret = 0;
dd = clk->dpll_data;
/* DPLL divider must result in a valid jitter correction val */
fint = clk_hw_get_rate(clk_hw_get_parent(&clk->hw)) / n;
if (dd->flags & DPLL_J_TYPE) {
fint_min = OMAP3PLUS_DPLL_FINT_JTYPE_MIN;
fint_max = OMAP3PLUS_DPLL_FINT_JTYPE_MAX;
} else {
fint_min = ti_clk_get_features()->fint_min;
fint_max = ti_clk_get_features()->fint_max;
}
if (!fint_min || !fint_max) {
WARN(1, "No fint limits available!\n");
return DPLL_FINT_INVALID;
}
if (fint < ti_clk_get_features()->fint_min) {
pr_debug("rejecting n=%d due to Fint failure, lowering max_divider\n",
n);
dd->max_divider = n;
ret = DPLL_FINT_UNDERFLOW;
} else if (fint > ti_clk_get_features()->fint_max) {
pr_debug("rejecting n=%d due to Fint failure, boosting min_divider\n",
n);
dd->min_divider = n;
ret = DPLL_FINT_INVALID;
} else if (fint > ti_clk_get_features()->fint_band1_max &&
fint < ti_clk_get_features()->fint_band2_min) {
pr_debug("rejecting n=%d due to Fint failure\n", n);
ret = DPLL_FINT_INVALID;
}
return ret;
}
static unsigned long _dpll_compute_new_rate(unsigned long parent_rate,
unsigned int m, unsigned int n)
{
unsigned long long num;
num = (unsigned long long)parent_rate * m;
do_div(num, n);
return num;
}
/*
* _dpll_test_mult - test a DPLL multiplier value
* @m: pointer to the DPLL m (multiplier) value under test
* @n: current DPLL n (divider) value under test
* @new_rate: pointer to storage for the resulting rounded rate
* @target_rate: the desired DPLL rate
* @parent_rate: the DPLL's parent clock rate
*
* This code tests a DPLL multiplier value, ensuring that the
* resulting rate will not be higher than the target_rate, and that
* the multiplier value itself is valid for the DPLL. Initially, the
* integer pointed to by the m argument should be prescaled by
* multiplying by DPLL_SCALE_FACTOR. The code will replace this with
* a non-scaled m upon return. This non-scaled m will result in a
* new_rate as close as possible to target_rate (but not greater than
* target_rate) given the current (parent_rate, n, prescaled m)
* triple. Returns DPLL_MULT_UNDERFLOW in the event that the
* non-scaled m attempted to underflow, which can allow the calling
* function to bail out early; or 0 upon success.
*/
static int _dpll_test_mult(int *m, int n, unsigned long *new_rate,
unsigned long target_rate,
unsigned long parent_rate)
{
int r = 0, carry = 0;
/* Unscale m and round if necessary */
if (*m % DPLL_SCALE_FACTOR >= DPLL_ROUNDING_VAL)
carry = 1;
*m = (*m / DPLL_SCALE_FACTOR) + carry;
/*
* The new rate must be <= the target rate to avoid programming
* a rate that is impossible for the hardware to handle
*/
*new_rate = _dpll_compute_new_rate(parent_rate, *m, n);
if (*new_rate > target_rate) {
(*m)--;
*new_rate = 0;
}
/* Guard against m underflow */
if (*m < DPLL_MIN_MULTIPLIER) {
*m = DPLL_MIN_MULTIPLIER;
*new_rate = 0;
r = DPLL_MULT_UNDERFLOW;
}
if (*new_rate == 0)
*new_rate = _dpll_compute_new_rate(parent_rate, *m, n);
return r;
}
/**
* _omap2_dpll_is_in_bypass - check if DPLL is in bypass mode or not
* @v: bitfield value of the DPLL enable
*
* Checks given DPLL enable bitfield to see whether the DPLL is in bypass
* mode or not. Returns 1 if the DPLL is in bypass, 0 otherwise.
*/
static int _omap2_dpll_is_in_bypass(u32 v)
{
u8 mask, val;
mask = ti_clk_get_features()->dpll_bypass_vals;
/*
* Each set bit in the mask corresponds to a bypass value equal
* to the bitshift. Go through each set-bit in the mask and
* compare against the given register value.
*/
while (mask) {
val = __ffs(mask);
mask ^= (1 << val);
if (v == val)
return 1;
}
return 0;
}
/* Public functions */
u8 omap2_init_dpll_parent(struct clk_hw *hw)
{
struct clk_hw_omap *clk = to_clk_hw_omap(hw);
u32 v;
struct dpll_data *dd;
dd = clk->dpll_data;
if (!dd)
return -EINVAL;
v = ti_clk_ll_ops->clk_readl(&dd->control_reg);
v &= dd->enable_mask;
v >>= __ffs(dd->enable_mask);
/* Reparent the struct clk in case the dpll is in bypass */
if (_omap2_dpll_is_in_bypass(v))
return 1;
return 0;
}
/**
* omap2_get_dpll_rate - returns the current DPLL CLKOUT rate
* @clk: struct clk * of a DPLL
*
* DPLLs can be locked or bypassed - basically, enabled or disabled.
* When locked, the DPLL output depends on the M and N values. When
* bypassed, on OMAP2xxx, the output rate is either the 32KiHz clock
* or sys_clk. Bypass rates on OMAP3 depend on the DPLL: DPLLs 1 and
* 2 are bypassed with dpll1_fclk and dpll2_fclk respectively
* (generated by DPLL3), while DPLL 3, 4, and 5 bypass rates are sys_clk.
* Returns the current DPLL CLKOUT rate (*not* CLKOUTX2) if the DPLL is
* locked, or the appropriate bypass rate if the DPLL is bypassed, or 0
* if the clock @clk is not a DPLL.
*/
unsigned long omap2_get_dpll_rate(struct clk_hw_omap *clk)
{
u64 dpll_clk;
u32 dpll_mult, dpll_div, v;
struct dpll_data *dd;
dd = clk->dpll_data;
if (!dd)
return 0;
/* Return bypass rate if DPLL is bypassed */
v = ti_clk_ll_ops->clk_readl(&dd->control_reg);
v &= dd->enable_mask;
v >>= __ffs(dd->enable_mask);
if (_omap2_dpll_is_in_bypass(v))
return clk_hw_get_rate(dd->clk_bypass);
v = ti_clk_ll_ops->clk_readl(&dd->mult_div1_reg);
dpll_mult = v & dd->mult_mask;
dpll_mult >>= __ffs(dd->mult_mask);
dpll_div = v & dd->div1_mask;
dpll_div >>= __ffs(dd->div1_mask);
dpll_clk = (u64)clk_hw_get_rate(dd->clk_ref) * dpll_mult;
do_div(dpll_clk, dpll_div + 1);
return dpll_clk;
}
/* DPLL rate rounding code */
/**
* omap2_dpll_round_rate - round a target rate for an OMAP DPLL
* @hw: struct clk_hw containing the struct clk * for a DPLL
* @target_rate: desired DPLL clock rate
* @parent_rate: parent's DPLL clock rate
*
* Given a DPLL and a desired target rate, round the target rate to a
* possible, programmable rate for this DPLL. Attempts to select the
* minimum possible n. Stores the computed (m, n) in the DPLL's
* dpll_data structure so set_rate() will not need to call this
* (expensive) function again. Returns ~0 if the target rate cannot
* be rounded, or the rounded rate upon success.
*/
long omap2_dpll_round_rate(struct clk_hw *hw, unsigned long target_rate,
unsigned long *parent_rate)
{
struct clk_hw_omap *clk = to_clk_hw_omap(hw);
int m, n, r, scaled_max_m;
int min_delta_m = INT_MAX, min_delta_n = INT_MAX;
unsigned long scaled_rt_rp;
unsigned long new_rate = 0;
struct dpll_data *dd;
unsigned long ref_rate;
long delta;
long prev_min_delta = LONG_MAX;
const char *clk_name;
if (!clk || !clk->dpll_data)
return ~0;
dd = clk->dpll_data;
if (dd->max_rate && target_rate > dd->max_rate)
target_rate = dd->max_rate;
ref_rate = clk_hw_get_rate(dd->clk_ref);
clk_name = clk_hw_get_name(hw);
pr_debug("clock: %s: starting DPLL round_rate, target rate %lu\n",
clk_name, target_rate);
scaled_rt_rp = target_rate / (ref_rate / DPLL_SCALE_FACTOR);
scaled_max_m = dd->max_multiplier * DPLL_SCALE_FACTOR;
dd->last_rounded_rate = 0;
for (n = dd->min_divider; n <= dd->max_divider; n++) {
/* Is the (input clk, divider) pair valid for the DPLL? */
r = _dpll_test_fint(clk, n);
if (r == DPLL_FINT_UNDERFLOW)
break;
else if (r == DPLL_FINT_INVALID)
continue;
/* Compute the scaled DPLL multiplier, based on the divider */
m = scaled_rt_rp * n;
/*
* Since we're counting n up, a m overflow means we
* can bail out completely (since as n increases in
* the next iteration, there's no way that m can
* increase beyond the current m)
*/
if (m > scaled_max_m)
break;
r = _dpll_test_mult(&m, n, &new_rate, target_rate,
ref_rate);
/* m can't be set low enough for this n - try with a larger n */
if (r == DPLL_MULT_UNDERFLOW)
continue;
/* skip rates above our target rate */
delta = target_rate - new_rate;
if (delta < 0)
continue;
if (delta < prev_min_delta) {
prev_min_delta = delta;
min_delta_m = m;
min_delta_n = n;
}
pr_debug("clock: %s: m = %d: n = %d: new_rate = %lu\n",
clk_name, m, n, new_rate);
if (delta == 0)
break;
}
if (prev_min_delta == LONG_MAX) {
pr_debug("clock: %s: cannot round to rate %lu\n",
clk_name, target_rate);
return ~0;
}
dd->last_rounded_m = min_delta_m;
dd->last_rounded_n = min_delta_n;
dd->last_rounded_rate = target_rate - prev_min_delta;
return dd->last_rounded_rate;
}