// SPDX-License-Identifier: MIT /* * Copyright © 2019 Intel Corporation */ #include #include "intel_ddi.h" #include "intel_ddi_buf_trans.h" #include "intel_de.h" #include "intel_display_types.h" #include "intel_snps_phy.h" /** * DOC: Synopsis PHY support * * Synopsis PHYs are primarily programmed by looking up magic register values * in tables rather than calculating the necessary values at runtime. * * Of special note is that the SNPS PHYs include a dedicated port PLL, known as * an "MPLLB." The MPLLB replaces the shared DPLL functionality used on other * platforms and must be programming directly during the modeset sequence * since it is not handled by the shared DPLL framework as on other platforms. */ void intel_snps_phy_wait_for_calibration(struct drm_i915_private *dev_priv) { enum phy phy; for_each_phy_masked(phy, ~0) { if (!intel_phy_is_snps(dev_priv, phy)) continue; if (intel_de_wait_for_clear(dev_priv, ICL_PHY_MISC(phy), DG2_PHY_DP_TX_ACK_MASK, 25)) DRM_ERROR("SNPS PHY %c failed to calibrate after 25ms.\n", phy); } } void intel_snps_phy_update_psr_power_state(struct drm_i915_private *dev_priv, enum phy phy, bool enable) { u32 val; if (!intel_phy_is_snps(dev_priv, phy)) return; val = REG_FIELD_PREP(SNPS_PHY_TX_REQ_LN_DIS_PWR_STATE_PSR, enable ? 2 : 3); intel_uncore_rmw(&dev_priv->uncore, SNPS_PHY_TX_REQ(phy), SNPS_PHY_TX_REQ_LN_DIS_PWR_STATE_PSR, val); } void intel_snps_phy_set_signal_levels(struct intel_encoder *encoder, const struct intel_crtc_state *crtc_state) { struct drm_i915_private *dev_priv = to_i915(encoder->base.dev); const struct intel_ddi_buf_trans *trans; enum phy phy = intel_port_to_phy(dev_priv, encoder->port); int level = intel_ddi_level(encoder, crtc_state, 0); int n_entries, ln; trans = encoder->get_buf_trans(encoder, crtc_state, &n_entries); if (drm_WARN_ON_ONCE(&dev_priv->drm, !trans)) return; for (ln = 0; ln < 4; ln++) { u32 val = 0; val |= REG_FIELD_PREP(SNPS_PHY_TX_EQ_MAIN, trans->entries[level].snps.vswing); val |= REG_FIELD_PREP(SNPS_PHY_TX_EQ_PRE, trans->entries[level].snps.pre_cursor); val |= REG_FIELD_PREP(SNPS_PHY_TX_EQ_POST, trans->entries[level].snps.post_cursor); intel_de_write(dev_priv, SNPS_PHY_TX_EQ(ln, phy), val); } } /* * Basic DP link rates with 100 MHz reference clock. */ static const struct intel_mpllb_state dg2_dp_rbr_100 = { .clock = 162000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 4) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 20) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FREQ_VCO, 2), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 226), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 5), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 39321) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_REM, 3), }; static const struct intel_mpllb_state dg2_dp_hbr1_100 = { .clock = 270000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 4) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 20) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FREQ_VCO, 3), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 184), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 1), }; static const struct intel_mpllb_state dg2_dp_hbr2_100 = { .clock = 540000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 4) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 20) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FREQ_VCO, 3), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 184), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 1), }; static const struct intel_mpllb_state dg2_dp_hbr3_100 = { .clock = 810000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 4) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 19) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 292), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 1), }; static const struct intel_mpllb_state dg2_dp_uhbr10_100 = { .clock = 1000000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 4) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 21) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV_MULTIPLIER, 8) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_WORD_DIV2_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_DP2_MODE, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 368), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 1), /* * SSC will be enabled, DP UHBR has a minimum SSC requirement. */ .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_PEAK, 58982), .mpllb_sscstep = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_STEPSIZE, 76101), }; static const struct intel_mpllb_state dg2_dp_uhbr13_100 = { .clock = 1350000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 5) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 45) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV_MULTIPLIER, 8) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_WORD_DIV2_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_DP2_MODE, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 3), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 508), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 1), /* * SSC will be enabled, DP UHBR has a minimum SSC requirement. */ .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_PEAK, 79626), .mpllb_sscstep = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_STEPSIZE, 102737), }; static const struct intel_mpllb_state * const dg2_dp_100_tables[] = { &dg2_dp_rbr_100, &dg2_dp_hbr1_100, &dg2_dp_hbr2_100, &dg2_dp_hbr3_100, &dg2_dp_uhbr10_100, &dg2_dp_uhbr13_100, NULL, }; /* * Basic DP link rates with 38.4 MHz reference clock. */ static const struct intel_mpllb_state dg2_dp_rbr_38_4 = { .clock = 162000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 1), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 5) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 25) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FREQ_VCO, 2), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 304), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 1), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 49152), }; static const struct intel_mpllb_state dg2_dp_hbr1_38_4 = { .clock = 270000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 1), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 5) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 25) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FREQ_VCO, 3), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 248), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 1), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 40960), }; static const struct intel_mpllb_state dg2_dp_hbr2_38_4 = { .clock = 540000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 1), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 5) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 25) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FREQ_VCO, 3), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 248), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 1), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 40960), }; static const struct intel_mpllb_state dg2_dp_hbr3_38_4 = { .clock = 810000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 1), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 6) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 26) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 388), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 1), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 61440), }; static const struct intel_mpllb_state dg2_dp_uhbr10_38_4 = { .clock = 1000000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 1), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 5) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 26) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV_MULTIPLIER, 8) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_WORD_DIV2_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_DP2_MODE, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 488), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 3), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_REM, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 27306), /* * SSC will be enabled, DP UHBR has a minimum SSC requirement. */ .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_PEAK, 76800), .mpllb_sscstep = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_STEPSIZE, 129024), }; static const struct intel_mpllb_state dg2_dp_uhbr13_38_4 = { .clock = 1350000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 1), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 6) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 56) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV_MULTIPLIER, 8) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_WORD_DIV2_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_DP2_MODE, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 3), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 670), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 1), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 36864), /* * SSC will be enabled, DP UHBR has a minimum SSC requirement. */ .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_PEAK, 103680), .mpllb_sscstep = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_STEPSIZE, 174182), }; static const struct intel_mpllb_state * const dg2_dp_38_4_tables[] = { &dg2_dp_rbr_38_4, &dg2_dp_hbr1_38_4, &dg2_dp_hbr2_38_4, &dg2_dp_hbr3_38_4, &dg2_dp_uhbr10_38_4, &dg2_dp_uhbr13_38_4, NULL, }; /* * eDP link rates with 100 MHz reference clock. */ static const struct intel_mpllb_state dg2_edp_r216 = { .clock = 216000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 4) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 19) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 312), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 5), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 52428) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_REM, 4), .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_PEAK, 50961), .mpllb_sscstep = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_STEPSIZE, 65752), }; static const struct intel_mpllb_state dg2_edp_r243 = { .clock = 243000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 4) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 20) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 356), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 5), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 26214) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_REM, 2), .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_PEAK, 57331), .mpllb_sscstep = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_STEPSIZE, 73971), }; static const struct intel_mpllb_state dg2_edp_r324 = { .clock = 324000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 4) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 20) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FREQ_VCO, 2), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 226), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 5), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 39321) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_REM, 3), .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_PEAK, 38221), .mpllb_sscstep = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_STEPSIZE, 49314), }; static const struct intel_mpllb_state dg2_edp_r432 = { .clock = 432000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 4) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 19) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 65) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 127), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 312), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 5), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 52428) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_REM, 4), .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_PEAK, 50961), .mpllb_sscstep = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_STEPSIZE, 65752), }; static const struct intel_mpllb_state * const dg2_edp_tables[] = { &dg2_dp_rbr_100, &dg2_edp_r216, &dg2_edp_r243, &dg2_dp_hbr1_100, &dg2_edp_r324, &dg2_edp_r432, &dg2_dp_hbr2_100, &dg2_dp_hbr3_100, NULL, }; /* * HDMI link rates with 100 MHz reference clock. */ static const struct intel_mpllb_state dg2_hdmi_25_175 = { .clock = 25175, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 5) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 15) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 64) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 124), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, 5) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 128) | REG_FIELD_PREP(SNPS_PHY_MPLLB_HDMI_DIV, 1), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 143), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 36663) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_REM, 71), .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_UP_SPREAD, 1), }; static const struct intel_mpllb_state dg2_hdmi_27_0 = { .clock = 27000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 5) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 15) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 64) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 124), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, 5) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 140) | REG_FIELD_PREP(SNPS_PHY_MPLLB_HDMI_DIV, 1), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 5), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 26214) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_REM, 2), .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_UP_SPREAD, 1), }; static const struct intel_mpllb_state dg2_hdmi_74_25 = { .clock = 74250, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 4) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 15) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 64) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 124), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, 3) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FREQ_VCO, 3), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 86) | REG_FIELD_PREP(SNPS_PHY_MPLLB_HDMI_DIV, 1), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 5), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 26214) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_REM, 2), .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_UP_SPREAD, 1), }; static const struct intel_mpllb_state dg2_hdmi_148_5 = { .clock = 148500, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 4) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 15) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 64) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 124), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_TX_CLK_DIV, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FREQ_VCO, 3), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 86) | REG_FIELD_PREP(SNPS_PHY_MPLLB_HDMI_DIV, 1), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 5), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 26214) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_REM, 2), .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_UP_SPREAD, 1), }; static const struct intel_mpllb_state dg2_hdmi_594 = { .clock = 594000, .ref_control = REG_FIELD_PREP(SNPS_PHY_REF_CONTROL_REF_RANGE, 3), .mpllb_cp = REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT, 4) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP, 15) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_INT_GS, 64) | REG_FIELD_PREP(SNPS_PHY_MPLLB_CP_PROP_GS, 124), .mpllb_div = REG_FIELD_PREP(SNPS_PHY_MPLLB_DIV5_CLK_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_PMIX_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_V2I, 2) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FREQ_VCO, 3), .mpllb_div2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_REF_CLK_DIV, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_MULTIPLIER, 86) | REG_FIELD_PREP(SNPS_PHY_MPLLB_HDMI_DIV, 1), .mpllb_fracn1 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_CGG_UPDATE_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_EN, 1) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_DEN, 5), .mpllb_fracn2 = REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_QUOT, 26214) | REG_FIELD_PREP(SNPS_PHY_MPLLB_FRACN_REM, 2), .mpllb_sscen = REG_FIELD_PREP(SNPS_PHY_MPLLB_SSC_UP_SPREAD, 1), }; static const struct intel_mpllb_state * const dg2_hdmi_tables[] = { &dg2_hdmi_25_175, &dg2_hdmi_27_0, &dg2_hdmi_74_25, &dg2_hdmi_148_5, &dg2_hdmi_594, NULL, }; static const struct intel_mpllb_state * const * intel_mpllb_tables_get(struct intel_crtc_state *crtc_state, struct intel_encoder *encoder) { if (intel_crtc_has_type(crtc_state, INTEL_OUTPUT_EDP)) { return dg2_edp_tables; } else if (intel_crtc_has_dp_encoder(crtc_state)) { /* * FIXME: Initially we're just enabling the "combo" outputs on * port A-D. The MPLLB for those ports takes an input from the * "Display Filter PLL" which always has an output frequency * of 100 MHz, hence the use of the _100 tables below. * * Once we enable port TC1 it will either use the same 100 MHz * "Display Filter PLL" (when strapped to support a native * display connection) or different 38.4 MHz "Filter PLL" when * strapped to support a USB connection, so we'll need to check * that to determine which table to use. */ if (0) return dg2_dp_38_4_tables; else return dg2_dp_100_tables; } else if (intel_crtc_has_type(crtc_state, INTEL_OUTPUT_HDMI)) { return dg2_hdmi_tables; } MISSING_CASE(encoder->type); return NULL; } int intel_mpllb_calc_state(struct intel_crtc_state *crtc_state, struct intel_encoder *encoder) { const struct intel_mpllb_state * const *tables; int i; if (intel_crtc_has_type(crtc_state, INTEL_OUTPUT_HDMI)) { if (intel_snps_phy_check_hdmi_link_rate(crtc_state->port_clock) != MODE_OK) { /* * FIXME: Can only support fixed HDMI frequencies * until we have a proper algorithm under a valid * license. */ DRM_DEBUG_KMS("Can't support HDMI link rate %d\n", crtc_state->port_clock); return -EINVAL; } } tables = intel_mpllb_tables_get(crtc_state, encoder); if (!tables) return -EINVAL; for (i = 0; tables[i]; i++) { if (crtc_state->port_clock <= tables[i]->clock) { crtc_state->mpllb_state = *tables[i]; return 0; } } return -EINVAL; } void intel_mpllb_enable(struct intel_encoder *encoder, const struct intel_crtc_state *crtc_state) { struct drm_i915_private *dev_priv = to_i915(encoder->base.dev); const struct intel_mpllb_state *pll_state = &crtc_state->mpllb_state; enum phy phy = intel_port_to_phy(dev_priv, encoder->port); i915_reg_t enable_reg = (phy <= PHY_D ? DG2_PLL_ENABLE(phy) : MG_PLL_ENABLE(0)); /* * 3. Software programs the following PLL registers for the desired * frequency. */ intel_de_write(dev_priv, SNPS_PHY_MPLLB_CP(phy), pll_state->mpllb_cp); intel_de_write(dev_priv, SNPS_PHY_MPLLB_DIV(phy), pll_state->mpllb_div); intel_de_write(dev_priv, SNPS_PHY_MPLLB_DIV2(phy), pll_state->mpllb_div2); intel_de_write(dev_priv, SNPS_PHY_MPLLB_SSCEN(phy), pll_state->mpllb_sscen); intel_de_write(dev_priv, SNPS_PHY_MPLLB_SSCSTEP(phy), pll_state->mpllb_sscstep); intel_de_write(dev_priv, SNPS_PHY_MPLLB_FRACN1(phy), pll_state->mpllb_fracn1); intel_de_write(dev_priv, SNPS_PHY_MPLLB_FRACN2(phy), pll_state->mpllb_fracn2); /* * 4. If the frequency will result in a change to the voltage * requirement, follow the Display Voltage Frequency Switching - * Sequence Before Frequency Change. * * We handle this step in bxt_set_cdclk(). */ /* 5. Software sets DPLL_ENABLE [PLL Enable] to "1". */ intel_uncore_rmw(&dev_priv->uncore, enable_reg, 0, PLL_ENABLE); /* * 9. Software sets SNPS_PHY_MPLLB_DIV dp_mpllb_force_en to "1". This * will keep the PLL running during the DDI lane programming and any * typeC DP cable disconnect. Do not set the force before enabling the * PLL because that will start the PLL before it has sampled the * divider values. */ intel_de_write(dev_priv, SNPS_PHY_MPLLB_DIV(phy), pll_state->mpllb_div | SNPS_PHY_MPLLB_FORCE_EN); /* * 10. Software polls on register DPLL_ENABLE [PLL Lock] to confirm PLL * is locked at new settings. This register bit is sampling PHY * dp_mpllb_state interface signal. */ if (intel_de_wait_for_set(dev_priv, enable_reg, PLL_LOCK, 5)) DRM_ERROR("Port %c PLL not locked\n", phy_name(phy)); /* * 11. If the frequency will result in a change to the voltage * requirement, follow the Display Voltage Frequency Switching - * Sequence After Frequency Change. * * We handle this step in bxt_set_cdclk(). */ } void intel_mpllb_disable(struct intel_encoder *encoder) { struct drm_i915_private *dev_priv = to_i915(encoder->base.dev); enum phy phy = intel_port_to_phy(dev_priv, encoder->port); i915_reg_t enable_reg = (phy <= PHY_D ? DG2_PLL_ENABLE(phy) : MG_PLL_ENABLE(0)); /* * 1. If the frequency will result in a change to the voltage * requirement, follow the Display Voltage Frequency Switching - * Sequence Before Frequency Change. * * We handle this step in bxt_set_cdclk(). */ /* 2. Software programs DPLL_ENABLE [PLL Enable] to "0" */ intel_uncore_rmw(&dev_priv->uncore, enable_reg, PLL_ENABLE, 0); /* * 4. Software programs SNPS_PHY_MPLLB_DIV dp_mpllb_force_en to "0". * This will allow the PLL to stop running. */ intel_uncore_rmw(&dev_priv->uncore, SNPS_PHY_MPLLB_DIV(phy), SNPS_PHY_MPLLB_FORCE_EN, 0); /* * 5. Software polls DPLL_ENABLE [PLL Lock] for PHY acknowledgment * (dp_txX_ack) that the new transmitter setting request is completed. */ if (intel_de_wait_for_clear(dev_priv, enable_reg, PLL_LOCK, 5)) DRM_ERROR("Port %c PLL not locked\n", phy_name(phy)); /* * 6. If the frequency will result in a change to the voltage * requirement, follow the Display Voltage Frequency Switching - * Sequence After Frequency Change. * * We handle this step in bxt_set_cdclk(). */ } int intel_mpllb_calc_port_clock(struct intel_encoder *encoder, const struct intel_mpllb_state *pll_state) { unsigned int frac_quot = 0, frac_rem = 0, frac_den = 1; unsigned int multiplier, tx_clk_div, refclk; bool frac_en; if (0) refclk = 38400; else refclk = 100000; refclk >>= REG_FIELD_GET(SNPS_PHY_MPLLB_REF_CLK_DIV, pll_state->mpllb_div2) - 1; frac_en = REG_FIELD_GET(SNPS_PHY_MPLLB_FRACN_EN, pll_state->mpllb_fracn1); if (frac_en) { frac_quot = REG_FIELD_GET(SNPS_PHY_MPLLB_FRACN_QUOT, pll_state->mpllb_fracn2); frac_rem = REG_FIELD_GET(SNPS_PHY_MPLLB_FRACN_REM, pll_state->mpllb_fracn2); frac_den = REG_FIELD_GET(SNPS_PHY_MPLLB_FRACN_DEN, pll_state->mpllb_fracn1); } multiplier = REG_FIELD_GET(SNPS_PHY_MPLLB_MULTIPLIER, pll_state->mpllb_div2) / 2 + 16; tx_clk_div = REG_FIELD_GET(SNPS_PHY_MPLLB_TX_CLK_DIV, pll_state->mpllb_div); return DIV_ROUND_CLOSEST_ULL(mul_u32_u32(refclk, (multiplier << 16) + frac_quot) + DIV_ROUND_CLOSEST(refclk * frac_rem, frac_den), 10 << (tx_clk_div + 16)); } void intel_mpllb_readout_hw_state(struct intel_encoder *encoder, struct intel_mpllb_state *pll_state) { struct drm_i915_private *dev_priv = to_i915(encoder->base.dev); enum phy phy = intel_port_to_phy(dev_priv, encoder->port); pll_state->mpllb_cp = intel_de_read(dev_priv, SNPS_PHY_MPLLB_CP(phy)); pll_state->mpllb_div = intel_de_read(dev_priv, SNPS_PHY_MPLLB_DIV(phy)); pll_state->mpllb_div2 = intel_de_read(dev_priv, SNPS_PHY_MPLLB_DIV2(phy)); pll_state->mpllb_sscen = intel_de_read(dev_priv, SNPS_PHY_MPLLB_SSCEN(phy)); pll_state->mpllb_sscstep = intel_de_read(dev_priv, SNPS_PHY_MPLLB_SSCSTEP(phy)); pll_state->mpllb_fracn1 = intel_de_read(dev_priv, SNPS_PHY_MPLLB_FRACN1(phy)); pll_state->mpllb_fracn2 = intel_de_read(dev_priv, SNPS_PHY_MPLLB_FRACN2(phy)); /* * REF_CONTROL is under firmware control and never programmed by the * driver; we read it only for sanity checking purposes. The bspec * only tells us the expected value for one field in this register, * so we'll only read out those specific bits here. */ pll_state->ref_control = intel_de_read(dev_priv, SNPS_PHY_REF_CONTROL(phy)) & SNPS_PHY_REF_CONTROL_REF_RANGE; /* * MPLLB_DIV is programmed twice, once with the software-computed * state, then again with the MPLLB_FORCE_EN bit added. Drop that * extra bit during readout so that we return the actual expected * software state. */ pll_state->mpllb_div &= ~SNPS_PHY_MPLLB_FORCE_EN; } int intel_snps_phy_check_hdmi_link_rate(int clock) { const struct intel_mpllb_state * const *tables = dg2_hdmi_tables; int i; for (i = 0; tables[i]; i++) { if (clock == tables[i]->clock) return MODE_OK; } return MODE_CLOCK_RANGE; }