Gitiles
Code Review Sign In
review.coreboot.org / coreboot / e33fc66fc9ddc28e4eddebc06eac5cd0ec1c3af1 / . / src / soc / qualcomm / sc7280 / clock.c
blob: 4441e480830cb4dae5c4dac68a772b40cf6fbece [file] [log] [blame]
/* SPDX-License-Identifier: GPL-2.0-only */
#include <assert.h>
#include <commonlib/helpers.h>
#include <device/mmio.h>
#include <soc/clock.h>
#include <types.h>
static struct clock_freq_config qspi_core_cfg[] = {
{
.hz = SRC_XO_HZ, /* 19.2KHz */
.src = SRC_XO_19_2MHZ,
.div = QCOM_CLOCK_DIV(1),
},
{
.hz = 100 * MHz,
.src = SRC_GPLL0_MAIN_600MHZ,
.div = QCOM_CLOCK_DIV(6),
},
{
.hz = 150 * MHz,
.src = SRC_GPLL0_MAIN_600MHZ,
.div = QCOM_CLOCK_DIV(4),
},
{
.hz = 200 * MHz,
.src = SRC_GPLL0_MAIN_600MHZ,
.div = QCOM_CLOCK_DIV(3),
},
{
.hz = 400 * MHz,
.src = SRC_GPLL0_MAIN_600MHZ,
.div = QCOM_CLOCK_DIV(1.5),
},
};
static struct clock_freq_config qupv3_wrap_cfg[] = {
{
.hz = SRC_XO_HZ, /* 19.2KHz */
.src = SRC_XO_19_2MHZ,
.div = QCOM_CLOCK_DIV(1),
},
{
.hz = 32 * MHz,
.src = SRC_GPLL0_EVEN_300MHZ,
.div = QCOM_CLOCK_DIV(1),
.m = 8,
.n = 75,
.d_2 = 75,
},
{
.hz = 48 * MHz,
.src = SRC_GPLL0_EVEN_300MHZ,
.div = QCOM_CLOCK_DIV(1),
.m = 4,
.n = 25,
.d_2 = 25,
},
{
.hz = 64 * MHz,
.src = SRC_GPLL0_EVEN_300MHZ,
.div = QCOM_CLOCK_DIV(1),
.m = 16,
.n = 75,
.d_2 = 75,
},
{
.hz = 96 * MHz,
.src = SRC_GPLL0_EVEN_300MHZ,
.div = QCOM_CLOCK_DIV(1),
.m = 8,
.n = 25,
.d_2 = 25,
},
{
.hz = 100 * MHz,
.src = SRC_GPLL0_MAIN_600MHZ,
.div = QCOM_CLOCK_DIV(6),
},
{
.hz = SRC_XO_HZ, /* 19.2KHz */
.src = SRC_XO_19_2MHZ,
.div = QCOM_CLOCK_DIV(1),
},
{
.hz = SRC_XO_HZ, /* 19.2KHz */
.src = SRC_XO_19_2MHZ,
.div = QCOM_CLOCK_DIV(1),
},
};
static struct clock_freq_config sdcc1_core_cfg[] = {
{
.hz = 100 * MHz,
.src = SRC_GPLL0_EVEN_300MHZ,
.div = QCOM_CLOCK_DIV(3),
},
{
.hz = 192 * MHz,
.src = SRC_GPLL10_MAIN_384MHZ,
.div = QCOM_CLOCK_DIV(2),
},
{
.hz = 384 * MHz,
.src = SRC_GPLL10_MAIN_384MHZ,
.div = QCOM_CLOCK_DIV(1),
},
};
static struct clock_freq_config sdcc2_core_cfg[] = {
{
.hz = 50 * MHz,
.src = SRC_GPLL0_EVEN_300MHZ,
.div = QCOM_CLOCK_DIV(6),
},
{
.hz = 202 * MHz,
.src = SRC_GPLL9_MAIN_808MHZ,
.div = QCOM_CLOCK_DIV(4),
},
};
static struct pcie pcie_cfg[] = {
[PCIE_1_GDSC] = {
.gdscr = &gcc->pcie_1.gdscr,
},
[PCIE_1_SLV_Q2A_AXI_CLK] = {
.clk = &gcc->pcie_1.slv_q2a_axi_cbcr,
.clk_br_en = &gcc->apcs_clk_br_en,
.vote_bit = PCIE_1_SLV_Q2A_AXI_CLK_ENA,
},
[PCIE_1_SLV_AXI_CLK] = {
.clk = &gcc->pcie_1.slv_axi_cbcr,
.clk_br_en = &gcc->apcs_clk_br_en,
.vote_bit = PCIE_1_SLV_AXI_CLK_ENA,
},
[PCIE_1_MSTR_AXI_CLK] = {
.clk = &gcc->pcie_1.mstr_axi_cbcr,
.clk_br_en = &gcc->apcs_clk_br_en,
.vote_bit = PCIE_1_MSTR_AXI_CLK_ENA,
},
[PCIE_1_CFG_AHB_CLK] = {
.clk = &gcc->pcie_1.cfg_ahb_cbcr,
.clk_br_en = &gcc->apcs_clk_br_en,
.vote_bit = PCIE_1_CFG_AHB_CLK_ENA,
},
[PCIE_1_AUX_CLK] = {
.clk = &gcc->pcie_1.aux_cbcr,
.clk_br_en = &gcc->apcs_clk_br_en,
.vote_bit = PCIE_1_AUX_CLK_ENA,
},
[AGGRE_NOC_PCIE_TBU_CLK] = {
.clk = &gcc->aggre_noc_pcie_tbu_cbcr,
.clk_br_en = &gcc->apcs_clk_br_en,
.vote_bit = AGGRE_NOC_PCIE_TBU_CLK_ENA,
},
[AGGRE_NOC_PCIE_1_AXI_CLK] = {
.clk = &gcc->pcie_1.aggre_noc_pcie_axi_cbcr,
.clk_br_en = &gcc->apcs_clk_br_en,
.vote_bit = AGGRE_NOC_PCIE_1_AXI_CLK_ENA,
},
[DDRSS_PCIE_SF_CLK] = {
.clk = &gcc->pcie_1.ddrss_pcie_sf_cbcr,
.clk_br_en = &gcc->apcs_clk_br_en,
.vote_bit = DDRSS_PCIE_SF_CLK_ENA,
},
[PCIE1_PHY_RCHNG_CLK] = {
.clk = &gcc->pcie_1.phy_rchng_cbcr,
.clk_br_en = &gcc->apcs_clk_br_en,
.vote_bit = PCIE1_PHY_RCHNG_CLK_ENA,
},
[AGGRE_NOC_PCIE_CENTER_SF_AXI_CLK] = {
.clk = &gcc->pcie_1.aggre_noc_pcie_center_sf_axi_cbcr,
.clk_br_en = &gcc->apcs_clk_br_en1,
.vote_bit = AGGRE_NOC_PCIE_CENTER_SF_AXI_CLK_ENA,
},
[PCIE_1_PIPE_CLK] = {
.clk = &gcc->pcie_1.pipe_cbcr,
.clk_br_en = &gcc->apcs_clk_br_en,
.vote_bit = PCIE_1_PIPE_CLK_ENA,
},
[PCIE_CLKREF_EN] = {
.clk = &gcc->pcie_clkref_en,
.vote_bit = NO_VOTE_BIT,
},
[GCC_PCIE_1_PIPE_MUXR] = {
.clk = &gcc->pcie_1.pipe_muxr,
.vote_bit = NO_VOTE_BIT,
},
};
static struct clock_freq_config mdss_mdp_cfg[] = {
{
.hz = 200 * MHz,
.src = SRC_GCC_DISP_GPLL0_CLK,
.div = QCOM_CLOCK_DIV(3),
},
{
.hz = 300 * MHz,
.src = SRC_GCC_DISP_GPLL0_CLK,
.div = QCOM_CLOCK_DIV(2),
},
{
.hz = 400 * MHz,
.src = SRC_GCC_DISP_GPLL0_CLK,
.div = QCOM_CLOCK_DIV(1.5),
},
};
static struct clock_rcg *mdss_clock[MDSS_CLK_COUNT] = {
[MDSS_CLK_MDP] = &mdss->mdp,
[MDSS_CLK_VSYNC] = &mdss->vsync,
[MDSS_CLK_ESC0] = &mdss->esc0,
[MDSS_CLK_BYTE0] = &mdss->byte0,
[MDSS_CLK_BYTE0_INTF] = &mdss->byte0,
[MDSS_CLK_AHB] = &mdss->mdss_ahb,
[MDSS_CLK_EDP_LINK] = &mdss->edp_link,
[MDSS_CLK_EDP_LINK_INTF] = &mdss->edp_link,
[MDSS_CLK_EDP_AUX] = &mdss->edp_aux,
};
static struct clock_rcg_mnd *mdss_clock_mnd[MDSS_CLK_COUNT] = {
[MDSS_CLK_PCLK0] = &mdss->pclk0,
[MDSS_CLK_EDP_PIXEL] = &mdss->edp_pixel,
};
static u32 *mdss_cbcr[MDSS_CLK_COUNT] = {
[GCC_DISP_AHB] = &gcc->disp_ahb_cbcr,
[GCC_DISP_HF_AXI] = &gcc->disp_hf_axi_cbcr,
[GCC_DISP_SF_AXI] = &gcc->disp_sf_axi_cbcr,
[GCC_EDP_CLKREF_EN] = &gcc->edp_clkref_en,
[MDSS_CLK_PCLK0] = &mdss->pclk0_cbcr,
[MDSS_CLK_MDP] = &mdss->mdp_cbcr,
[MDSS_CLK_VSYNC] = &mdss->vsync_cbcr,
[MDSS_CLK_BYTE0] = &mdss->byte0_cbcr,
[MDSS_CLK_BYTE0_INTF] = &mdss->byte0_intf_cbcr,
[MDSS_CLK_ESC0] = &mdss->esc0_cbcr,
[MDSS_CLK_AHB] = &mdss->ahb_cbcr,
[MDSS_CLK_EDP_PIXEL] = &mdss->edp_pixel_cbcr,
[MDSS_CLK_EDP_LINK] = &mdss->edp_link_cbcr,
[MDSS_CLK_EDP_LINK_INTF] = &mdss->edp_link_intf_cbcr,
[MDSS_CLK_EDP_AUX] = &mdss->edp_aux_cbcr,
};
static u32 *gdsc[MAX_GDSC] = {
[PCIE_1_GDSC] = &gcc->pcie_1.gdscr,
[MDSS_CORE_GDSC] = &mdss->core_gdsc,
};
static enum cb_err clock_configure_gpll0(void)
{
struct alpha_pll_reg_val_config gpll0_cfg = {0};
gpll0_cfg.reg_user_ctl = &gcc->gpll0.user_ctl;
gpll0_cfg.user_ctl_val = (1 << PLL_POST_DIV_EVEN_SHFT |
3 << PLL_POST_DIV_ODD_SHFT |
1 << PLL_PLLOUT_EVEN_SHFT |
1 << PLL_PLLOUT_MAIN_SHFT |
1 << PLL_PLLOUT_ODD_SHFT);
return clock_configure_enable_gpll(&gpll0_cfg, false, 0);
}
void clock_configure_qspi(uint32_t hz)
{
clock_configure(&gcc->qspi_core,
qspi_core_cfg, hz,
ARRAY_SIZE(qspi_core_cfg));
clock_enable(&gcc->qspi_cnoc_ahb_cbcr);
clock_enable(&gcc->qspi_core_cbcr);
}
void clock_enable_qup(int qup)
{
struct qupv3_clock *qup_clk;
int s = qup % QUP_WRAP1_S0, clk_en_off;
qup_clk = qup < QUP_WRAP1_S0 ?
&gcc->qup_wrap0_s[s] : &gcc->qup_wrap1_s[s];
if (qup < QUP_WRAP1_S6) {
clk_en_off = qup < QUP_WRAP1_S0 ?
QUPV3_WRAP0_CLK_ENA_S(s) : QUPV3_WRAP1_CLK_ENA_S(s);
clock_enable_vote(&qup_clk->cbcr, &gcc->apcs_clk_br_en1,
clk_en_off);
} else {
clk_en_off = QUPV3_WRAP1_CLK_ENA_1_S(s);
clock_enable_vote(&qup_clk->cbcr, &gcc->apcs_clk_br_en,
clk_en_off);
}
}
void clock_configure_sdcc1(uint32_t hz)
{
if (hz > CLK_100MHZ) {
struct alpha_pll_reg_val_config gpll10_cfg = {0};
gpll10_cfg.reg_mode = &gcc->gpll10.mode;
gpll10_cfg.reg_opmode = &gcc->gpll10.opmode;
gpll10_cfg.reg_l = &gcc->gpll10.l;
gpll10_cfg.l_val = 0x14;
gpll10_cfg.reg_cal_l = &gcc->gpll10.cal_l;
gpll10_cfg.cal_l_val = 0x44;
gpll10_cfg.fsm_enable = true;
gpll10_cfg.reg_apcs_pll_br_en = &gcc->apcs_pll_br_en;
clock_configure_enable_gpll(&gpll10_cfg, true, 9);
}
clock_configure((struct clock_rcg *)&gcc->sdcc1, sdcc1_core_cfg,
hz, ARRAY_SIZE(sdcc1_core_cfg));
clock_enable(&gcc->sdcc1_ahb_cbcr);
clock_enable(&gcc->sdcc1_apps_cbcr);
}
void clock_configure_sdcc2(uint32_t hz)
{
if (hz > CLK_100MHZ) {
struct alpha_pll_reg_val_config gpll9_cfg = {0};
gpll9_cfg.reg_mode = &gcc->gpll9.mode;
gpll9_cfg.reg_opmode = &gcc->gpll9.opmode;
gpll9_cfg.reg_alpha = &gcc->gpll9.alpha;
gpll9_cfg.alpha_val = 0x1555;
gpll9_cfg.reg_l = &gcc->gpll9.l;
gpll9_cfg.l_val = 0x2A;
gpll9_cfg.reg_cal_l = &gcc->gpll9.cal_l;
gpll9_cfg.cal_l_val = 0x44;
gpll9_cfg.fsm_enable = true;
gpll9_cfg.reg_apcs_pll_br_en = &gcc->apcs_pll_br_en;
clock_configure_enable_gpll(&gpll9_cfg, true, 8);
}
clock_configure((struct clock_rcg *)&gcc->sdcc2, sdcc2_core_cfg,
hz, ARRAY_SIZE(sdcc2_core_cfg));
clock_enable(&gcc->sdcc2_ahb_cbcr);
clock_enable(&gcc->sdcc2_apps_cbcr);
}
void clock_configure_dfsr(int qup)
{
clock_configure_dfsr_table(qup, qupv3_wrap_cfg,
ARRAY_SIZE(qupv3_wrap_cfg));
}
static enum cb_err pll_init_and_set(struct sc7280_apss_clock *apss, u32 l_val)
{
struct alpha_pll_reg_val_config pll_cfg = {0};
int ret;
u32 gfmux_val, regval;
pll_cfg.reg_l = &apss->pll.l;
pll_cfg.l_val = l_val;
pll_cfg.reg_config_ctl = &apss->pll.config_ctl_lo;
pll_cfg.reg_config_ctl_hi = &apss->pll.config_ctl_hi;
pll_cfg.reg_config_ctl_hi1 = &apss->pll.config_ctl_u1;
regval = read32(&apss->pll.config_ctl_lo);
pll_cfg.config_ctl_val = regval &
(~(0x2 << K_P_SHFT | 0x2 << K_I_SHFT));
regval = read32(&apss->pll.config_ctl_hi);
pll_cfg.config_ctl_hi_val = (regval | (BIT(KLSB_SHFT) |
BIT(RON_MODE_SHFT))) & (~(0x4 << KLSB_SHFT));
regval = read32(&apss->pll.config_ctl_u1);
pll_cfg.config_ctl_hi1_val = (regval | BIT(FAST_LOCK_LOW_L_SHFT)) &
~BIT(DCO_BIAS_ADJ_SHFT);
ret = clock_configure_enable_gpll(&pll_cfg, false, 0);
if (ret != CB_SUCCESS)
return CB_ERR;
pll_cfg.reg_mode = &apss->pll.mode;
pll_cfg.reg_opmode = &apss->pll.opmode;
pll_cfg.reg_user_ctl = &apss->pll.user_ctl;
ret = zonda_pll_enable(&pll_cfg);
if (ret != CB_SUCCESS)
return CB_ERR;
gfmux_val = read32(&apss->cfg_gfmux) & ~GFMUX_SRC_SEL_BMSK;
gfmux_val |= APCS_SRC_EARLY;
write32(&apss->cfg_gfmux, gfmux_val);
return CB_SUCCESS;
}
enum cb_err clock_enable_gdsc(enum clk_gdsc gdsc_type)
{
if (gdsc_type > MAX_GDSC)
return CB_ERR;
return enable_and_poll_gdsc_status(gdsc[gdsc_type]);
}
enum cb_err mdss_clock_configure(enum clk_mdss clk_type, uint32_t hz,
uint32_t source, uint32_t divider, uint32_t m,
uint32_t n, uint32_t d_2)
{
struct clock_freq_config mdss_clk_cfg;
uint32_t idx;
if (clk_type >= MDSS_CLK_COUNT)
return CB_ERR;
/* Initialize it with received arguments */
mdss_clk_cfg.div = divider ? QCOM_CLOCK_DIV(divider) : 0;
mdss_clk_cfg.src = source;
mdss_clk_cfg.m = m;
mdss_clk_cfg.n = n;
mdss_clk_cfg.d_2 = d_2;
mdss_clk_cfg.hz = hz;
if (clk_type == MDSS_CLK_MDP) {
for (idx = 0; idx < ARRAY_SIZE(mdss_mdp_cfg); idx++) {
if (hz <= mdss_mdp_cfg[idx].hz) {
mdss_clk_cfg.src = mdss_mdp_cfg[idx].src;
mdss_clk_cfg.div = mdss_mdp_cfg[idx].div;
mdss_clk_cfg.hz = mdss_mdp_cfg[idx].hz;
mdss_clk_cfg.m = 0;
break;
}
}
}
switch (clk_type) {
case MDSS_CLK_EDP_PIXEL:
case MDSS_CLK_PCLK0:
return clock_configure((struct clock_rcg *)
mdss_clock_mnd[clk_type],
&mdss_clk_cfg, mdss_clk_cfg.hz, 1);
default:
return clock_configure(mdss_clock[clk_type],
&mdss_clk_cfg, mdss_clk_cfg.hz, 1);
}
}
enum cb_err mdss_clock_enable(enum clk_mdss clk_type)
{
if (clk_type >= MDSS_CLK_COUNT)
return CB_ERR;
/* Enable clock */
return clock_enable(mdss_cbcr[clk_type]);
}
enum cb_err clock_enable_pcie(enum clk_pcie clk_type)
{
int clk_vote_bit;
if (clk_type >= PCIE_CLK_COUNT)
return CB_ERR;
clk_vote_bit = pcie_cfg[clk_type].vote_bit;
if (clk_vote_bit < 0)
return clock_enable(pcie_cfg[clk_type].clk);
clock_enable_vote(pcie_cfg[clk_type].clk,
pcie_cfg[clk_type].clk_br_en,
pcie_cfg[clk_type].vote_bit);
return CB_SUCCESS;
}
enum cb_err clock_configure_mux(enum clk_pcie clk_type, u32 src_type)
{
if (clk_type >= PCIE_CLK_COUNT)
return CB_ERR;
/* Set clock src */
write32(pcie_cfg[clk_type].clk, src_type);
return CB_SUCCESS;
}
static void speed_up_boot_cpu(void)
{
/* 1516.8 MHz */
if (!pll_init_and_set(apss_silver, L_VAL_1516P8MHz))
printk(BIOS_DEBUG, "Silver Frequency bumped to 1.5168(GHz)\n");
/* 1190.4 MHz */
if (!pll_init_and_set(apss_l3, L_VAL_1190P4MHz))
printk(BIOS_DEBUG, "L3 Frequency bumped to 1.1904(GHz)\n");
}
void clock_init(void)
{
clock_configure_gpll0();
clock_enable_vote(&gcc->qup_wrap0_core_2x_cbcr,
&gcc->apcs_clk_br_en1,
QUPV3_WRAP0_CORE_2X_CLK_ENA);
clock_enable_vote(&gcc->qup_wrap0_core_cbcr,
&gcc->apcs_clk_br_en1,
QUPV3_WRAP0_CORE_CLK_ENA);
clock_enable_vote(&gcc->qup_wrap0_m_ahb_cbcr,
&gcc->apcs_clk_br_en1,
QUPV3_WRAP_0_M_AHB_CLK_ENA);
clock_enable_vote(&gcc->qup_wrap0_s_ahb_cbcr,
&gcc->apcs_clk_br_en1,
QUPV3_WRAP_0_S_AHB_CLK_ENA);
clock_enable_vote(&gcc->qup_wrap1_core_2x_cbcr,
&gcc->apcs_clk_br_en1,
QUPV3_WRAP1_CORE_2X_CLK_ENA);
clock_enable_vote(&gcc->qup_wrap1_core_cbcr,
&gcc->apcs_clk_br_en1,
QUPV3_WRAP1_CORE_CLK_ENA);
clock_enable_vote(&gcc->qup_wrap1_m_ahb_cbcr,
&gcc->apcs_clk_br_en1,
QUPV3_WRAP_1_M_AHB_CLK_ENA);
clock_enable_vote(&gcc->qup_wrap1_s_ahb_cbcr,
&gcc->apcs_clk_br_en1,
QUPV3_WRAP_1_S_AHB_CLK_ENA);
speed_up_boot_cpu();
}