1c942fddfSThomas Gleixner // SPDX-License-Identifier: GPL-2.0-or-later
2460d0d44SMaxime Ripard /*
3460d0d44SMaxime Ripard * Copyright 2013 Emilio López
4460d0d44SMaxime Ripard * Emilio López <emilio@elopez.com.ar>
5460d0d44SMaxime Ripard *
6460d0d44SMaxime Ripard * Copyright 2015 Maxime Ripard
7460d0d44SMaxime Ripard * Maxime Ripard <maxime.ripard@free-electrons.com>
8460d0d44SMaxime Ripard */
9460d0d44SMaxime Ripard
10460d0d44SMaxime Ripard #include <linux/clk-provider.h>
1162e59c4eSStephen Boyd #include <linux/io.h>
12460d0d44SMaxime Ripard #include <linux/of.h>
13460d0d44SMaxime Ripard #include <linux/of_address.h>
14460d0d44SMaxime Ripard #include <linux/slab.h>
15460d0d44SMaxime Ripard
16460d0d44SMaxime Ripard #include <dt-bindings/clock/sun4i-a10-pll2.h>
17460d0d44SMaxime Ripard
18460d0d44SMaxime Ripard #define SUN4I_PLL2_ENABLE 31
19460d0d44SMaxime Ripard
20460d0d44SMaxime Ripard #define SUN4I_PLL2_PRE_DIV_SHIFT 0
21460d0d44SMaxime Ripard #define SUN4I_PLL2_PRE_DIV_WIDTH 5
22460d0d44SMaxime Ripard #define SUN4I_PLL2_PRE_DIV_MASK GENMASK(SUN4I_PLL2_PRE_DIV_WIDTH - 1, 0)
23460d0d44SMaxime Ripard
24460d0d44SMaxime Ripard #define SUN4I_PLL2_N_SHIFT 8
25460d0d44SMaxime Ripard #define SUN4I_PLL2_N_WIDTH 7
26460d0d44SMaxime Ripard #define SUN4I_PLL2_N_MASK GENMASK(SUN4I_PLL2_N_WIDTH - 1, 0)
27460d0d44SMaxime Ripard
28460d0d44SMaxime Ripard #define SUN4I_PLL2_POST_DIV_SHIFT 26
29460d0d44SMaxime Ripard #define SUN4I_PLL2_POST_DIV_WIDTH 4
30460d0d44SMaxime Ripard #define SUN4I_PLL2_POST_DIV_MASK GENMASK(SUN4I_PLL2_POST_DIV_WIDTH - 1, 0)
31460d0d44SMaxime Ripard
32460d0d44SMaxime Ripard #define SUN4I_PLL2_POST_DIV_VALUE 4
33460d0d44SMaxime Ripard
34460d0d44SMaxime Ripard #define SUN4I_PLL2_OUTPUTS 4
35460d0d44SMaxime Ripard
36460d0d44SMaxime Ripard static DEFINE_SPINLOCK(sun4i_a10_pll2_lock);
37460d0d44SMaxime Ripard
sun4i_pll2_setup(struct device_node * node,int post_div_offset)38eb662f85SMaxime Ripard static void __init sun4i_pll2_setup(struct device_node *node,
3959f0ec23SMaxime Ripard int post_div_offset)
40460d0d44SMaxime Ripard {
41460d0d44SMaxime Ripard const char *clk_name = node->name, *parent;
42460d0d44SMaxime Ripard struct clk **clks, *base_clk, *prediv_clk;
43460d0d44SMaxime Ripard struct clk_onecell_data *clk_data;
44460d0d44SMaxime Ripard struct clk_multiplier *mult;
45460d0d44SMaxime Ripard struct clk_gate *gate;
46460d0d44SMaxime Ripard void __iomem *reg;
47460d0d44SMaxime Ripard u32 val;
48460d0d44SMaxime Ripard
49460d0d44SMaxime Ripard reg = of_io_request_and_map(node, 0, of_node_full_name(node));
50460d0d44SMaxime Ripard if (IS_ERR(reg))
51460d0d44SMaxime Ripard return;
52460d0d44SMaxime Ripard
53460d0d44SMaxime Ripard clk_data = kzalloc(sizeof(*clk_data), GFP_KERNEL);
54460d0d44SMaxime Ripard if (!clk_data)
55460d0d44SMaxime Ripard goto err_unmap;
56460d0d44SMaxime Ripard
57460d0d44SMaxime Ripard clks = kcalloc(SUN4I_PLL2_OUTPUTS, sizeof(struct clk *), GFP_KERNEL);
58460d0d44SMaxime Ripard if (!clks)
59460d0d44SMaxime Ripard goto err_free_data;
60460d0d44SMaxime Ripard
61460d0d44SMaxime Ripard parent = of_clk_get_parent_name(node, 0);
62460d0d44SMaxime Ripard prediv_clk = clk_register_divider(NULL, "pll2-prediv",
63460d0d44SMaxime Ripard parent, 0, reg,
64460d0d44SMaxime Ripard SUN4I_PLL2_PRE_DIV_SHIFT,
65460d0d44SMaxime Ripard SUN4I_PLL2_PRE_DIV_WIDTH,
6659f0ec23SMaxime Ripard CLK_DIVIDER_ONE_BASED | CLK_DIVIDER_ALLOW_ZERO,
67460d0d44SMaxime Ripard &sun4i_a10_pll2_lock);
687e196aa1SWei Yongjun if (IS_ERR(prediv_clk)) {
69460d0d44SMaxime Ripard pr_err("Couldn't register the prediv clock\n");
70460d0d44SMaxime Ripard goto err_free_array;
71460d0d44SMaxime Ripard }
72460d0d44SMaxime Ripard
73460d0d44SMaxime Ripard /* Setup the gate part of the PLL2 */
74460d0d44SMaxime Ripard gate = kzalloc(sizeof(struct clk_gate), GFP_KERNEL);
75460d0d44SMaxime Ripard if (!gate)
76460d0d44SMaxime Ripard goto err_unregister_prediv;
77460d0d44SMaxime Ripard
78460d0d44SMaxime Ripard gate->reg = reg;
79460d0d44SMaxime Ripard gate->bit_idx = SUN4I_PLL2_ENABLE;
80460d0d44SMaxime Ripard gate->lock = &sun4i_a10_pll2_lock;
81460d0d44SMaxime Ripard
82460d0d44SMaxime Ripard /* Setup the multiplier part of the PLL2 */
83460d0d44SMaxime Ripard mult = kzalloc(sizeof(struct clk_multiplier), GFP_KERNEL);
84460d0d44SMaxime Ripard if (!mult)
85460d0d44SMaxime Ripard goto err_free_gate;
86460d0d44SMaxime Ripard
87460d0d44SMaxime Ripard mult->reg = reg;
88460d0d44SMaxime Ripard mult->shift = SUN4I_PLL2_N_SHIFT;
89460d0d44SMaxime Ripard mult->width = 7;
90460d0d44SMaxime Ripard mult->flags = CLK_MULTIPLIER_ZERO_BYPASS |
91460d0d44SMaxime Ripard CLK_MULTIPLIER_ROUND_CLOSEST;
92460d0d44SMaxime Ripard mult->lock = &sun4i_a10_pll2_lock;
93460d0d44SMaxime Ripard
94460d0d44SMaxime Ripard parent = __clk_get_name(prediv_clk);
95460d0d44SMaxime Ripard base_clk = clk_register_composite(NULL, "pll2-base",
96460d0d44SMaxime Ripard &parent, 1,
97460d0d44SMaxime Ripard NULL, NULL,
98460d0d44SMaxime Ripard &mult->hw, &clk_multiplier_ops,
99460d0d44SMaxime Ripard &gate->hw, &clk_gate_ops,
100460d0d44SMaxime Ripard CLK_SET_RATE_PARENT);
1017e196aa1SWei Yongjun if (IS_ERR(base_clk)) {
102460d0d44SMaxime Ripard pr_err("Couldn't register the base multiplier clock\n");
103460d0d44SMaxime Ripard goto err_free_multiplier;
104460d0d44SMaxime Ripard }
105460d0d44SMaxime Ripard
106460d0d44SMaxime Ripard parent = __clk_get_name(base_clk);
107460d0d44SMaxime Ripard
108460d0d44SMaxime Ripard /*
109460d0d44SMaxime Ripard * PLL2-1x
110460d0d44SMaxime Ripard *
111460d0d44SMaxime Ripard * This is supposed to have a post divider, but we won't need
112460d0d44SMaxime Ripard * to use it, we just need to initialise it to 4, and use a
113460d0d44SMaxime Ripard * fixed divider.
114460d0d44SMaxime Ripard */
115460d0d44SMaxime Ripard val = readl(reg);
116460d0d44SMaxime Ripard val &= ~(SUN4I_PLL2_POST_DIV_MASK << SUN4I_PLL2_POST_DIV_SHIFT);
11759f0ec23SMaxime Ripard val |= (SUN4I_PLL2_POST_DIV_VALUE - post_div_offset) << SUN4I_PLL2_POST_DIV_SHIFT;
118460d0d44SMaxime Ripard writel(val, reg);
119460d0d44SMaxime Ripard
120460d0d44SMaxime Ripard of_property_read_string_index(node, "clock-output-names",
121460d0d44SMaxime Ripard SUN4I_A10_PLL2_1X, &clk_name);
122460d0d44SMaxime Ripard clks[SUN4I_A10_PLL2_1X] = clk_register_fixed_factor(NULL, clk_name,
123460d0d44SMaxime Ripard parent,
124460d0d44SMaxime Ripard CLK_SET_RATE_PARENT,
125460d0d44SMaxime Ripard 1,
126460d0d44SMaxime Ripard SUN4I_PLL2_POST_DIV_VALUE);
127460d0d44SMaxime Ripard WARN_ON(IS_ERR(clks[SUN4I_A10_PLL2_1X]));
128460d0d44SMaxime Ripard
129460d0d44SMaxime Ripard /*
130460d0d44SMaxime Ripard * PLL2-2x
131460d0d44SMaxime Ripard *
132460d0d44SMaxime Ripard * This clock doesn't use the post divider, and really is just
133460d0d44SMaxime Ripard * a fixed divider from the PLL2 base clock.
134460d0d44SMaxime Ripard */
135460d0d44SMaxime Ripard of_property_read_string_index(node, "clock-output-names",
136460d0d44SMaxime Ripard SUN4I_A10_PLL2_2X, &clk_name);
137460d0d44SMaxime Ripard clks[SUN4I_A10_PLL2_2X] = clk_register_fixed_factor(NULL, clk_name,
138460d0d44SMaxime Ripard parent,
139460d0d44SMaxime Ripard CLK_SET_RATE_PARENT,
140460d0d44SMaxime Ripard 1, 2);
141460d0d44SMaxime Ripard WARN_ON(IS_ERR(clks[SUN4I_A10_PLL2_2X]));
142460d0d44SMaxime Ripard
143460d0d44SMaxime Ripard /* PLL2-4x */
144460d0d44SMaxime Ripard of_property_read_string_index(node, "clock-output-names",
145460d0d44SMaxime Ripard SUN4I_A10_PLL2_4X, &clk_name);
146460d0d44SMaxime Ripard clks[SUN4I_A10_PLL2_4X] = clk_register_fixed_factor(NULL, clk_name,
147460d0d44SMaxime Ripard parent,
148460d0d44SMaxime Ripard CLK_SET_RATE_PARENT,
149460d0d44SMaxime Ripard 1, 1);
150460d0d44SMaxime Ripard WARN_ON(IS_ERR(clks[SUN4I_A10_PLL2_4X]));
151460d0d44SMaxime Ripard
152460d0d44SMaxime Ripard /* PLL2-8x */
153460d0d44SMaxime Ripard of_property_read_string_index(node, "clock-output-names",
154460d0d44SMaxime Ripard SUN4I_A10_PLL2_8X, &clk_name);
155460d0d44SMaxime Ripard clks[SUN4I_A10_PLL2_8X] = clk_register_fixed_factor(NULL, clk_name,
156460d0d44SMaxime Ripard parent,
157460d0d44SMaxime Ripard CLK_SET_RATE_PARENT,
158460d0d44SMaxime Ripard 2, 1);
159460d0d44SMaxime Ripard WARN_ON(IS_ERR(clks[SUN4I_A10_PLL2_8X]));
160460d0d44SMaxime Ripard
161460d0d44SMaxime Ripard clk_data->clks = clks;
162460d0d44SMaxime Ripard clk_data->clk_num = SUN4I_PLL2_OUTPUTS;
163460d0d44SMaxime Ripard of_clk_add_provider(node, of_clk_src_onecell_get, clk_data);
164460d0d44SMaxime Ripard
165460d0d44SMaxime Ripard return;
166460d0d44SMaxime Ripard
167460d0d44SMaxime Ripard err_free_multiplier:
168460d0d44SMaxime Ripard kfree(mult);
169460d0d44SMaxime Ripard err_free_gate:
170460d0d44SMaxime Ripard kfree(gate);
171460d0d44SMaxime Ripard err_unregister_prediv:
172460d0d44SMaxime Ripard clk_unregister_divider(prediv_clk);
173460d0d44SMaxime Ripard err_free_array:
174460d0d44SMaxime Ripard kfree(clks);
175460d0d44SMaxime Ripard err_free_data:
176460d0d44SMaxime Ripard kfree(clk_data);
177460d0d44SMaxime Ripard err_unmap:
178460d0d44SMaxime Ripard iounmap(reg);
179460d0d44SMaxime Ripard }
180eb662f85SMaxime Ripard
sun4i_a10_pll2_setup(struct device_node * node)181eb662f85SMaxime Ripard static void __init sun4i_a10_pll2_setup(struct device_node *node)
182eb662f85SMaxime Ripard {
18359f0ec23SMaxime Ripard sun4i_pll2_setup(node, 0);
184eb662f85SMaxime Ripard }
185eb662f85SMaxime Ripard
186eb662f85SMaxime Ripard CLK_OF_DECLARE(sun4i_a10_pll2, "allwinner,sun4i-a10-pll2-clk",
187eb662f85SMaxime Ripard sun4i_a10_pll2_setup);
188eb662f85SMaxime Ripard
sun5i_a13_pll2_setup(struct device_node * node)189eb662f85SMaxime Ripard static void __init sun5i_a13_pll2_setup(struct device_node *node)
190eb662f85SMaxime Ripard {
19159f0ec23SMaxime Ripard sun4i_pll2_setup(node, 1);
192eb662f85SMaxime Ripard }
193eb662f85SMaxime Ripard
194eb662f85SMaxime Ripard CLK_OF_DECLARE(sun5i_a13_pll2, "allwinner,sun5i-a13-pll2-clk",
195eb662f85SMaxime Ripard sun5i_a13_pll2_setup);
196