@@ -338,6 +338,7 @@ i915-y += \
display/intel_pps.o \
display/intel_qp_tables.o \
display/intel_sdvo.o \
+ display/intel_snps_hdmi_pll.o \
display/intel_snps_phy.o \
display/intel_tv.o \
display/intel_vdsc.o \
new file mode 100644
@@ -0,0 +1,286 @@
+// SPDX-License-Identifier: MIT
+/*
+ * Copyright © 2024 Synopsys, Inc., Intel Corporation
+ */
+
+#include <linux/math.h>
+
+#include "intel_display_types.h"
+#include "intel_snps_phy.h"
+#include "intel_snps_phy_regs.h"
+#include "intel_snps_hdmi_pll.h"
+
+#define INTEL_SNPS_PHY_HDMI_4999MHZ 4999999900ULL
+#define INTEL_SNPS_PHY_HDMI_16GHZ 16000000000ULL
+#define INTEL_SNPS_PHY_HDMI_9999MHZ (2 * INTEL_SNPS_PHY_HDMI_4999MHZ)
+
+#define CURVE0_MULTIPLIER 1000000000
+#define CURVE1_MULTIPLIER 100
+#define CURVE2_MULTIPLIER 1000000000000ULL
+
+struct pll_output_params {
+ u32 ssc_up_spread;
+ u32 mpll_div5_en;
+ u32 hdmi_div;
+ u32 ana_cp_int;
+ u32 ana_cp_prop;
+ u32 refclk_postscalar;
+ u32 tx_clk_div;
+ u32 fracn_quot;
+ u32 fracn_rem;
+ u32 fracn_den;
+ u32 fracn_en;
+ u32 pmix_en;
+ u32 multiplier;
+ int mpll_ana_v2i;
+ int ana_freq_vco;
+};
+
+static s64 interp(s64 x, s64 x1, s64 x2, s64 y1, s64 y2)
+{
+ s64 dydx;
+
+ dydx = DIV_ROUND_UP_ULL((y2 - y1) * 100000, (x2 - x1));
+
+ return (y1 + DIV_ROUND_UP_ULL(dydx * (x - x1), 100000));
+}
+
+static void get_ana_cp_int_prop(u32 vco_clk,
+ u32 refclk_postscalar,
+ int mpll_ana_v2i,
+ int c, int a,
+ const u64 curve_freq_hz[2][8],
+ const u64 curve_0[2][8],
+ const u64 curve_1[2][8],
+ const u64 curve_2[2][8],
+ u32 *ana_cp_int,
+ u32 *ana_cp_prop)
+{
+ u64 vco_div_refclk_float;
+ u64 curve_0_interpolated;
+ u64 curve_2_interpolated;
+ u64 curve_1_interpolated;
+ u64 curve_2_scaled1;
+ u64 curve_2_scaled2;
+ u64 adjusted_vco_clk1;
+ u64 adjusted_vco_clk2;
+ u64 curve_2_scaled_int;
+ u64 interpolated_product;
+ u64 scaled_interpolated_sqrt;
+ u64 scaled_vco_div_refclk1;
+ u64 scaled_vco_div_refclk2;
+ u64 temp;
+
+ vco_div_refclk_float = vco_clk * DIV_ROUND_DOWN_ULL(1000000000000ULL, refclk_postscalar);
+
+ /* Interpolate curve values at the target vco_clk frequency */
+ curve_0_interpolated = interp(vco_clk, curve_freq_hz[c][a], curve_freq_hz[c][a + 1],
+ curve_0[c][a], curve_0[c][a + 1]);
+
+ curve_2_interpolated = interp(vco_clk, curve_freq_hz[c][a], curve_freq_hz[c][a + 1],
+ curve_2[c][a], curve_2[c][a + 1]);
+
+ curve_1_interpolated = interp(vco_clk, curve_freq_hz[c][a], curve_freq_hz[c][a + 1],
+ curve_1[c][a], curve_1[c][a + 1]);
+
+ curve_1_interpolated = DIV_ROUND_DOWN_ULL(curve_1_interpolated, CURVE1_MULTIPLIER);
+
+ /*
+ * Scale curve_2_interpolated based on mpll_ana_v2i, for integer part
+ * ana_cp_int and for the proportional part ana_cp_prop
+ */
+ temp = curve_2_interpolated * (4 - mpll_ana_v2i);
+ curve_2_scaled1 = DIV_ROUND_DOWN_ULL(temp, 16000);
+ curve_2_scaled2 = DIV_ROUND_DOWN_ULL(temp, 160);
+
+ /* Scale vco_div_refclk for ana_cp_int */
+ scaled_vco_div_refclk1 = 112008301 * DIV_ROUND_DOWN_ULL(vco_div_refclk_float, 100000);
+
+ adjusted_vco_clk1 = CURVE2_MULTIPLIER *
+ DIV_ROUND_DOWN_ULL(scaled_vco_div_refclk1, (curve_0_interpolated *
+ DIV_ROUND_DOWN_ULL(curve_1_interpolated, CURVE0_MULTIPLIER)));
+
+ *ana_cp_int = DIV_ROUND_CLOSEST_ULL(DIV_ROUND_DOWN_ULL(adjusted_vco_clk1, curve_2_scaled1),
+ CURVE2_MULTIPLIER);
+ *ana_cp_int = max(1, min(*ana_cp_int, 127));
+
+ curve_2_scaled_int = curve_2_scaled1 * (*ana_cp_int);
+
+ interpolated_product = curve_1_interpolated *
+ (curve_2_scaled_int * DIV_ROUND_DOWN_ULL(curve_0_interpolated,
+ CURVE0_MULTIPLIER));
+
+ scaled_interpolated_sqrt =
+ int_sqrt(DIV_ROUND_UP_ULL(interpolated_product, vco_div_refclk_float) *
+ DIV_ROUND_DOWN_ULL(1000000000000ULL, 55));
+
+ /* Scale vco_div_refclk for ana_cp_int */
+ scaled_vco_div_refclk2 = DIV_ROUND_UP_ULL(vco_div_refclk_float, 1000000);
+ adjusted_vco_clk2 = 1460281 * DIV_ROUND_UP_ULL(scaled_interpolated_sqrt *
+ scaled_vco_div_refclk2,
+ curve_1_interpolated);
+
+ *ana_cp_prop = DIV_ROUND_UP_ULL(adjusted_vco_clk2, curve_2_scaled2);
+ *ana_cp_prop = max(1, min(*ana_cp_prop, 127));
+}
+
+static void compute_hdmi_tmds_pll(u64 pixel_clock, u32 refclk,
+ u32 ref_range,
+ u32 ana_cp_int_gs,
+ u32 ana_cp_prop_gs,
+ const u64 curve_freq_hz[2][8],
+ const u64 curve_0[2][8],
+ const u64 curve_1[2][8],
+ const u64 curve_2[2][8],
+ u32 prescaler_divider,
+ struct pll_output_params *pll_params)
+{
+ /* datarate 10khz */
+ u64 datarate = pixel_clock * 10000;
+ u32 ssc_up_spread = 1;
+ u32 mpll_div5_en = 1;
+ u32 hdmi_div = 1;
+ u32 ana_cp_int;
+ u32 ana_cp_prop;
+ u32 refclk_postscalar = refclk >> prescaler_divider;
+ u32 tx_clk_div;
+ u64 vco_clk;
+ u64 vco_clk_do_div;
+ u32 vco_div_refclk_integer;
+ u32 vco_div_refclk_fracn;
+ u32 fracn_quot;
+ u32 fracn_rem;
+ u32 fracn_den;
+ u32 fracn_en;
+ u32 pmix_en;
+ u32 multiplier;
+ int mpll_ana_v2i;
+ int ana_freq_vco = 0;
+ int c, a = 0;
+ int i;
+
+ /* Select appropriate v2i point */
+ if (datarate <= INTEL_SNPS_PHY_HDMI_9999MHZ) {
+ mpll_ana_v2i = 2;
+ tx_clk_div = ilog2(DIV_ROUND_DOWN_ULL(INTEL_SNPS_PHY_HDMI_9999MHZ, datarate));
+ } else {
+ mpll_ana_v2i = 3;
+ tx_clk_div = ilog2(DIV_ROUND_DOWN_ULL(INTEL_SNPS_PHY_HDMI_16GHZ, datarate));
+ }
+ vco_clk = (datarate << tx_clk_div) >> 1;
+
+ vco_div_refclk_integer = DIV_ROUND_DOWN_ULL(vco_clk, refclk_postscalar);
+ vco_clk_do_div = do_div(vco_clk, refclk_postscalar);
+ vco_div_refclk_fracn = DIV_ROUND_DOWN_ULL(vco_clk_do_div << 32, refclk_postscalar);
+
+ fracn_quot = vco_div_refclk_fracn >> 16;
+ fracn_rem = vco_div_refclk_fracn & 0xffff;
+ fracn_rem = fracn_rem - (fracn_rem >> 15);
+ fracn_den = 0xffff;
+ fracn_en = (fracn_quot != 0 || fracn_rem != 0) ? 1 : 0;
+ pmix_en = fracn_en;
+ multiplier = (vco_div_refclk_integer - 16) * 2;
+ /* Curve selection for ana_cp_* calculations. One curve hardcoded per v2i range */
+ c = mpll_ana_v2i - 2;
+
+ /* Find the right segment of the table */
+ for (i = 0; i < 8; i += 2) {
+ if (vco_clk <= curve_freq_hz[c][i + 1]) {
+ a = i;
+ ana_freq_vco = 3 - (a >> 1);
+ break;
+ }
+ }
+
+ get_ana_cp_int_prop(vco_clk, refclk_postscalar, mpll_ana_v2i, c, a,
+ curve_freq_hz, curve_0, curve_1, curve_2,
+ &ana_cp_int, &ana_cp_prop);
+
+ pll_params->ssc_up_spread = ssc_up_spread;
+ pll_params->mpll_div5_en = mpll_div5_en;
+ pll_params->hdmi_div = hdmi_div;
+ pll_params->ana_cp_int = ana_cp_int;
+ pll_params->refclk_postscalar = refclk_postscalar;
+ pll_params->tx_clk_div = tx_clk_div;
+ pll_params->fracn_quot = fracn_quot;
+ pll_params->fracn_rem = fracn_rem;
+ pll_params->fracn_den = fracn_den;
+ pll_params->fracn_en = fracn_en;
+ pll_params->pmix_en = pmix_en;
+ pll_params->multiplier = multiplier;
+ pll_params->ana_cp_prop = ana_cp_prop;
+ pll_params->mpll_ana_v2i = mpll_ana_v2i;
+ pll_params->ana_freq_vco = ana_freq_vco;
+}
+
+void intel_snps_hdmi_pll_compute_mpllb(struct intel_mpllb_state *pll_state, u64 pixel_clock)
+{
+ /* x axis frequencies. One curve in each array per v2i point */
+ static const u64 dg2_curve_freq_hz[2][8] = {
+ { 2500000000ULL, 3000000000ULL, 3000000000ULL, 3500000000ULL, 3500000000ULL,
+ 4000000000ULL, 4000000000ULL, 5000000000ULL },
+ { 4000000000ULL, 4600000000ULL, 4601000000ULL, 5400000000ULL, 5401000000ULL,
+ 6600000000ULL, 6601000000ULL, 8001000000ULL }
+ };
+
+ /* y axis heights multiplied with 1000000000 */
+ static const u64 dg2_curve_0[2][8] = {
+ { 34149871, 39803269, 36034544, 40601014, 35646940, 40016109, 35127987, 41889522 },
+ { 70000000, 78770454, 70451838, 80427119, 70991400, 84230173, 72945921, 87064218 }
+ };
+
+ /* Multiplied with 100 */
+ static const u64 dg2_curve_1[2][8] = {
+ { 85177000000000ULL, 79385227160000ULL, 95672603580000ULL, 88857207160000ULL,
+ 109379790900000ULL, 103528193900000ULL, 131941242400000ULL, 117279000000000ULL },
+ { 60255000000000ULL, 55569000000000ULL, 72036000000000ULL, 69509000000000ULL,
+ 81785000000000ULL, 731030000000000ULL, 96591000000000ULL, 69077000000000ULL }
+ };
+
+ /* Multiplied with 1000000000000 */
+ static const u64 dg2_curve_2[2][8] = {
+ { 2186930000ULL, 2835287134ULL, 2395395343ULL, 2932270687ULL, 2351887545ULL,
+ 2861031697ULL, 2294149152ULL, 3091730000ULL },
+ { 4560000000ULL, 5570000000ULL, 4610000000ULL, 5770000000ULL, 4670000000ULL,
+ 6240000000ULL, 4890000000ULL, 6600000000ULL }
+ };
+
+ struct pll_output_params pll_params;
+ u32 refclk = 100000000;
+ u32 prescaler_divider = 1;
+ u32 ref_range = 3;
+ u32 ana_cp_int_gs = 64;
+ u32 ana_cp_prop_gs = 124;
+
+ compute_hdmi_tmds_pll(pixel_clock, refclk, ref_range, ana_cp_int_gs, ana_cp_prop_gs,
+ dg2_curve_freq_hz, dg2_curve_0, dg2_curve_1, dg2_curve_2,
+ prescaler_divider, &pll_params);
+
+ pll_state->clock = pixel_clock;
+ pll_state->ref_control =
+ REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, ref_range);
+ pll_state->mpllb_cp =
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, pll_params.ana_cp_int) |
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, pll_params.ana_cp_prop) |
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, ana_cp_int_gs) |
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, ana_cp_prop_gs);
+ pll_state->mpllb_div =
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, pll_params.mpll_div5_en) |
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, pll_params.tx_clk_div) |
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, pll_params.pmix_en) |
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, pll_params.mpll_ana_v2i) |
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_FREQ_VCO, pll_params.ana_freq_vco);
+ pll_state->mpllb_div2 =
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, prescaler_divider) |
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, pll_params.multiplier) |
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_HDMI_DIV, pll_params.hdmi_div);
+ pll_state->mpllb_fracn1 =
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) |
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, pll_params.fracn_en) |
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, pll_params.fracn_den);
+ pll_state->mpllb_fracn2 =
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, pll_params.fracn_quot) |
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_REM, pll_params.fracn_rem);
+ pll_state->mpllb_sscen =
+ REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_UP_SPREAD, pll_params.ssc_up_spread);
+}
new file mode 100644
@@ -0,0 +1,15 @@
+/* SPDX-License-Identifier: MIT */
+/*
+ * Copyright © 2024 Synopsys, Inc., Intel Corporation
+ */
+
+#ifndef __INTEL_SNPS_HDMI_PLL_H__
+#define __INTEL_SNPS_HDMI_PLL_H__
+
+#include <linux/types.h>
+
+struct intel_mpllb_state;
+
+void intel_snps_hdmi_pll_compute_mpllb(struct intel_mpllb_state *pll_state, u64 pixel_clock);
+
+#endif /* __INTEL_SNPS_HDMI_PLL_H__ */
@@ -258,6 +258,7 @@ xe-$(CONFIG_DRM_XE_DISPLAY) += \
i915-display/intel_psr.o \
i915-display/intel_qp_tables.o \
i915-display/intel_quirks.o \
+ i915-display/intel_snps_hdmi_pll.o \
i915-display/intel_snps_phy.o \
i915-display/intel_tc.o \
i915-display/intel_vblank.o \
Add helpers to calculate the necessary parameters for configuring the HDMI PLL for SNPS MPLLB and C10 PHY. The pll parameters are computed for desired pixel clock, curve data and other inputs used for interpolation and finally stored in the pll_state. Bspec:54032 Currently the helper is used to compute PLLs for DG2 SNPS PHY. Support for computing Plls for C10 PHY is added in subsequent patches. v2: -Used kernel types instead of C99 types. (Jani) -Fixed styling issues and renamed few variables to more meaningful names. (Jani) -Added Xe make file changes. (Jani) -Fixed build errors reported by kernel test robot v3: -Renamed helper to align with file name. (Jani) Signed-off-by: Ankit Nautiyal <ankit.k.nautiyal@intel.com> --- drivers/gpu/drm/i915/Makefile | 1 + .../drm/i915/display/intel_snps_hdmi_pll.c | 286 ++++++++++++++++++ .../drm/i915/display/intel_snps_hdmi_pll.h | 15 + drivers/gpu/drm/xe/Makefile | 1 + 4 files changed, 303 insertions(+) create mode 100644 drivers/gpu/drm/i915/display/intel_snps_hdmi_pll.c create mode 100644 drivers/gpu/drm/i915/display/intel_snps_hdmi_pll.h