/*- * SPDX-License-Identifier: BSD-2-Clause-FreeBSD * * Copyright 2020 Michal Meloun * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include "tegra210_car.h" /* Bits in base register. */ #define PERLCK_AMUX_MASK 0x0F #define PERLCK_AMUX_SHIFT 16 #define PERLCK_AMUX_DIS (1 << 20) #define PERLCK_UDIV_DIS (1 << 24) #define PERLCK_ENA_MASK (1 << 28) #define PERLCK_MUX_SHIFT 29 #define PERLCK_MUX_MASK 0x07 struct periph_def { struct clknode_init_def clkdef; uint32_t base_reg; uint32_t div_width; uint32_t div_mask; uint32_t div_f_width; uint32_t div_f_mask; uint32_t flags; }; struct pgate_def { struct clknode_init_def clkdef; uint32_t idx; uint32_t flags; }; #define PLIST(x) static const char *x[] #define GATE(_id, cname, plist, _idx) \ { \ .clkdef.id = TEGRA210_CLK_##_id, \ .clkdef.name = cname, \ .clkdef.parent_names = (const char *[]){plist}, \ .clkdef.parent_cnt = 1, \ .clkdef.flags = CLK_NODE_STATIC_STRINGS, \ .idx = _idx, \ .flags = 0, \ } /* Sources for multiplexors. */ PLIST(mux_N_N_c_N_p_N_a) = {"bogus", NULL, "pllC_out0", NULL, "pllP_out0", NULL, "pllA_out0", NULL}; PLIST(mux_N_N_p_N_N_N_clkm) = {NULL, NULL, "pllP_out0", NULL, NULL, NULL, "clk_m", NULL}; PLIST(mux_N_c_p_a1_c2_c3_clkm) = {NULL, "pllC_out0", "pllP_out0", "pllA1_out0", "pllC2_out0", "pllC3_out0", "clk_m", NULL}; PLIST(mux_N_c_p_a1_c2_c3_clkm_c4) = {NULL, "pllC_out0", "pllP_out0", "pllA1_out0", "pllC2_out0", "pllC3_out0", "clk_m", "pllC4_out0"}; PLIST(mux_N_c_p_clkm_N_c4_c4o1_c4o1) = {NULL, "pllC_out0", "pllP_out0", "clk_m", NULL, "pllC4_out0", "pllC4_out1", "pllC4_out1"}; PLIST(mux_N_c_p_clkm_N_c4_c4o1_c4o2) = {NULL, "pllC_out0", "pllP_out0", "clk_m", NULL, "pllC4_out0", "pllC4_out1", "pllC4_out2"}; PLIST(mux_N_c2_c_c3_p_N_a) = {NULL, "pllC2_out0", "pllC_out0", "pllC3_out0", "pllP_out0", NULL, "pllA_out0", NULL}; PLIST(mux_N_c2_c_c3_p_clkm_a1_c4) = {NULL, "pllC2_out0", "pllC_out0", "pllC3_out0", "pllP_out0", "clk_m", "pllA1_out0", "pllC4_out0"}; PLIST(mux_N_c2_c_c3_p_N_a1_clkm) = {NULL, "pllC2_out0", "pllC_out0", "pllC3_out0", "pllP_out0", NULL, "pllA1_out0", "clk_m"}; PLIST(mux_a_N_audio_N_p_N_clkm) = {"pllA_out0", NULL, "audio", NULL, "pllP_out0", NULL, "clk_m"}; PLIST(mux_a_N_audio0_N_p_N_clkm) = {"pllA_out0", NULL, "audio0", NULL, "pllP_out0", NULL, "clk_m"}; PLIST(mux_a_N_audio1_N_p_N_clkm) = {"pllA_out0", NULL, "audio1", NULL, "pllP_out0", NULL, "clk_m"}; PLIST(mux_a_N_audio2_N_p_N_clkm) = {"pllA_out0", NULL, "audio2", NULL, "pllP_out0", NULL, "clk_m"}; PLIST(mux_a_N_audio3_N_p_N_clkm) = {"pllA_out0", NULL, "audio3", NULL, "pllP_out0", NULL, "clk_m"}; PLIST(mux_a_N_audio4_N_p_N_clkm) = {"pllA_out0", NULL, "audio4", NULL, "pllP_out0", NULL, "clk_m"}; PLIST(mux_a_audiod1_p_clkm) = {"pllA_out0", "audiod1", "pllP_out0", "clk_m", NULL, NULL, NULL, NULL}; PLIST(mux_a_audiod2_p_clkm) = {"pllA_out0", "audiod2", "pllP_out0", "clk_m", NULL, NULL, NULL, NULL}; PLIST(mux_a_audiod3_p_clkm) = {"pllA_out0", "audiod3", "pllP_out0", "clk_m", NULL, NULL, NULL, NULL}; PLIST(mux_a_c4_c_c4o1_p_N_clkm_c4o2) = {"pllA_out0", "pllC4_out0", "pllC_out0", "pllC4_out1", "pllP_out0", NULL, "clk_m", "pllC4_out2"}; PLIST(mux_a_clks_p_clkm_e) = {"pllA_out0", "clk_s", "pllP_out0", "clk_m", "pllE_out0"}; PLIST(mux_c4o1_c2_c_c4_p_clkm_a_c4) = {"pllC4_out1", "pllC2_out0", "pllC_out0", "pllC4_out0", "pllP_out0", "clk_m","pllA_out0", "pllC4_out0", }; PLIST(mux_m_c_p_clkm_mud_mbud_mb_pud) = {"pllM_out0", "pllC_out0", "pllP_out0", "clk_m", "pllM_UD", "pllMB_UD", "pllMB_out0", "pllP_UD"}; PLIST(mux_p_N_N_c4o2_c4o1_N_clkm_c4) = {"pllP_out0", NULL, NULL, "pllC4_out2", "pllC4_out1", NULL, "clk_m", "pllC4_out0"}; PLIST(mux_p_N_c_c4_c4o1_c4o2_clkm) = {"pllP_out0", NULL, "pllC_out0", "pllC4_out0", "pllC4_out1", "pllC4_out2", "clk_m"}; PLIST(mux_p_N_c_c4_N_c4o1_clkm_c4o2) = {"pllP_out0", NULL, "pllC_out0", "pllC4_out0", NULL, "pllC4_out1", "clk_m", "pllC4_out2"}; PLIST(mux_p_N_d_N_N_d2_clkm) = {"pllP_out0", NULL, "pllD_out0", NULL, NULL, "pllD2_out0", "clk_m"}; PLIST(mux_p_N_clkm_N_clks_N_E) = {"pllP_out0", NULL, "clk_m", NULL, NULL, "clk_s", NULL, "pllE_out0"}; PLIST(mux_p_c_c2_N_c2_N_clkm) = {"pllP_out0", "pllC_out0", "pllC2_out0", NULL, "pllC2_out0", NULL, "clk_m", NULL}; PLIST(mux_p_co1_c_N_c4o2_c4o1_clkm_c4) = {"pllP_out0", "pllC_out1", "pllC_out0", NULL, "pllC4_out2", "pllC4_out1" ,"clk_m", "pllC4_out0"}; PLIST(mux_p_c2_c_c3_N_a1_clkm_c4) = {"pllP_out0", "pllC2_out0", "pllC_out0", "pllC3_out0", NULL, "pllA1_out0", "clk_m", "pllC4_out0"}; PLIST(mux_p_c2_c_c3_N_N_clkm) = {"pllP_out0", "pllC2_out0", "pllC_out0", "pllC3_out0", NULL, NULL, "clk_m", NULL}; PLIST(mux_p_c2_c_c3_m_e_clkm) = {"pllP_out0", "pllC2_out0", "pllC_out0", "pllC3_out0", "pllM_out0", "pllE_out0", "clk_m"}; PLIST(mux_p_c2_c_c4_N_c4o1_clkm_c4o2) = {"pllP_out0", "pllC2_out0", "pllC4_out0", NULL, "pllC4_out1", "clk_m", "pllC4_out2"}; PLIST(mux_p_c2_c_c4_a_c4o1_clkm_c4o2) = {"pllP_out0", "pllC2_out0", "pllC_out0", "pllC4_out0", "pllA_out0", "pllC4_out1", "clk_m", "pllC4_out2"}; PLIST(mux_p_c2_c_c4o2_c4o1_clks_clkm_c4) = {"pllP_out0", "pllC2_out0", "pllC4_out2", "pllC4_out1", "clk_s", "clk_m", "pllC4_out0"}; PLIST(mux_p_c2_c_c4_c4o1_clkm_c4o2) = {"pllP_out0", "pllC2_out0", "pllC_out0", "pllC4_out0", "pllC4_out1", "clk_m", "pllC4_out2"}; PLIST(mux_p_c2_c_c4_clkm_c4o1_c4o2) = {"pllP_out0", "pllC2_out0", "pllC_out0", "pllC4_out0", "clk_m", "pllC4_out1", "pllC4_out2"}; PLIST(mux_p_c2_c_c4_clks_c4o1_clkm_c4o2) = {"pllP_out0", "pllC2_out0", "pllC_out0", "pllC4_out0", "clk_s", "pllC4_out1", "clk_m", "pllC4_out2"}; PLIST(mux_p_c2_c_c4_clkm_c4o1_clks_c4o2) = {"pllP_out0", "pllC2_out0", "pllC_out0", "pllC4_out0", "clk_m", "pllC4_out1", "clk_s", "pllC4_out2"}; PLIST(mux_p_c2_refe1_c3_m_a1_clkm_C4) = {"pllP_out0", "pllC2_out0", "pllREFE_out1", "pllC3_out0", "pllM_out0", "pllA1_out0", "clk_m", "pllC4_out0"}; PLIST(mux_p_c4_c_c4o1_N_c4o2_clkm) = {"pllP_out0", "pllC4_out0", "pllC_out0", "pllC4_out1", NULL, "pllC4_out2", "clk_m", NULL}; PLIST(mux_p_m_d_a_c_d2_clkm) = {"pllP_out0", "pllM_out0", "pllD_out0", "pllA_out0", "pllC_out0", "pllD2_out0", "clk_m"}; PLIST(mux_p_po3_clkm_clks_a) = {"pllP_out0", "pllP_out3", "clk_m", "clk_s", "pllA_out0", NULL, NULL, NULL}; PLIST(mux_po3_c_c2_clkm_p_c4_c4o1_c4o2) = {"pllP_out3", "pllC_out0", "pllC2_out0", "clk_m", "pllP_out0", "pllC4_out0", "pllC4_out1", "pllC4_out2"}; PLIST(mux_clkm_p_N_N_N_refre) = {"clk_m", "pllP_xusb", NULL, NULL, NULL, "pllREFE_out0", NULL, NULL}; PLIST(mux_clkm_N_u48_N_p_N_u480) = {"clk_m", NULL, "pllU_48", NULL, "pllP_out0", NULL, "pllU_480"}; PLIST(mux_clkm_refe_clks_u480) = {"clk_m", "pllREFE_out0", "clk_s", "pllU_480", NULL, NULL, NULL, NULL}; PLIST(mux_sep_audio) = {"pllA_out0", "pllC4_out0", "pllC_out0", "pllC4_out0", "pllP_out0", "pllC4_out0", "clk_m", NULL, "spdif_in", "i2s1", "i2s2", "i2s3", "i2s4", "i2s5", "pllA_out0", "ext_vimclk"}; static uint32_t clk_enable_reg[] = { CLK_OUT_ENB_L, CLK_OUT_ENB_H, CLK_OUT_ENB_U, CLK_OUT_ENB_V, CLK_OUT_ENB_W, CLK_OUT_ENB_X, CLK_OUT_ENB_Y, }; static uint32_t clk_reset_reg[] = { RST_DEVICES_L, RST_DEVICES_H, RST_DEVICES_U, RST_DEVICES_V, RST_DEVICES_W, RST_DEVICES_X, RST_DEVICES_Y, }; #define L(n) ((0 * 32) + (n)) #define H(n) ((1 * 32) + (n)) #define U(n) ((2 * 32) + (n)) #define V(n) ((3 * 32) + (n)) #define W(n) ((4 * 32) + (n)) #define X(n) ((5 * 32) + (n)) #define Y(n) ((6 * 32) + (n)) /* Clock IDs not yet defined in binding header file. */ #define TEGRA210_CLK_STAT_MON H(5) #define TEGRA210_CLK_IRAMA U(20) #define TEGRA210_CLK_IRAMB U(21) #define TEGRA210_CLK_IRAMC U(22) #define TEGRA210_CLK_IRAMD U(23) #define TEGRA210_CLK_CRAM2 U(24) #define TEGRA210_CLK_M_DOUBLER U(26) #define TEGRA210_CLK_DEVD2_OUT U(29) #define TEGRA210_CLK_DEVD1_OUT U(30) #define TEGRA210_CLK_CPUG V(0) #define TEGRA210_CLK_ATOMICS V(16) #define TEGRA210_CLK_PCIERX0 W(2) #define TEGRA210_CLK_PCIERX1 W(3) #define TEGRA210_CLK_PCIERX2 W(4) #define TEGRA210_CLK_PCIERX3 W(5) #define TEGRA210_CLK_PCIERX4 W(6) #define TEGRA210_CLK_PCIERX5 W(7) #define TEGRA210_CLK_PCIE2_IOBIST W(9) #define TEGRA210_CLK_EMC_IOBIST W(10) #define TEGRA210_CLK_SATA_IOBIST W(12) #define TEGRA210_CLK_MIPI_IOBIST W(13) #define TEGRA210_CLK_EMC_LATENCY W(29) #define TEGRA210_CLK_MC1 W(30) #define TEGRA210_CLK_ETR X(3) #define TEGRA210_CLK_CAM_MCLK X(4) #define TEGRA210_CLK_CAM_MCLK2 X(5) #define TEGRA210_CLK_MC_CAPA X(7) #define TEGRA210_CLK_MC_CBPA X(8) #define TEGRA210_CLK_MC_CPU X(9) #define TEGRA210_CLK_MC_BBC X(10) #define TEGRA210_CLK_EMC_DLL X(14) #define TEGRA210_CLK_UART_FST_MIPI_CAL X(17) #define TEGRA210_CLK_HPLL_ADSP X(26) #define TEGRA210_CLK_PLLP_ADSP X(27) #define TEGRA210_CLK_PLLA_ADSP X(28) #define TEGRA210_CLK_PLLG_REF X(29) #define TEGRA210_CLK_AXIAP Y(4) #define TEGRA210_CLK_MC_CDPA Y(8) #define TEGRA210_CLK_MC_CCPA Y(9) static struct pgate_def pgate_def[] = { /* bank L -> 0-31 */ GATE(ISPB, "ispb", "clk_m", L(3)), GATE(RTC, "rtc", "clk_s", L(4)), GATE(TIMER, "timer", "clk_m", L(5)), GATE(UARTA, "uarta", "pc_uarta" , L(6)), GATE(UARTB, "uartb", "pc_uartb", L(7)), GATE(GPIO, "gpio", "clk_m", L(8)), GATE(SDMMC2, "sdmmc2", "pc_sdmmc2", L(9)), GATE(SPDIF_OUT, "spdif_out", "pc_spdif_out", L(10)), GATE(SPDIF_IN, "spdif_in", "pc_spdif_in", L(10)), GATE(I2S1, "i2s2", "pc_i2s2", L(11)), GATE(I2C1, "i2c1", "pc_i2c1", L(12)), GATE(SDMMC1, "sdmmc1", "pc_sdmmc1", L(14)), GATE(SDMMC4, "sdmmc4", "pc_sdmmc4", L(15)), GATE(PWM, "pwm", "pc_pwm", L(17)), GATE(I2S2, "i2s3", "pc_i2s3", L(18)), GATE(VI, "vi", "pc_vi", L(20)), GATE(USBD, "usbd", "clk_m", L(22)), GATE(ISP, "isp", "pc_isp", L(23)), GATE(DISP2, "disp2", "pc_disp2", L(26)), GATE(DISP1, "disp1", "pc_disp1", L(27)), GATE(HOST1X, "host1x", "pc_host1x", L(28)), GATE(I2S0, "i2s1", "pc_i2s1", L(30)), /* bank H -> 32-63 */ GATE(MC, "mem", "clk_m", H(0)), GATE(AHBDMA, "ahbdma", "clk_m", H(1)), GATE(APBDMA, "apbdma", "clk_m", H(2)), GATE(STAT_MON, "stat_mon", "clk_s", H(5)), GATE(PMC, "pmc", "clk_s", H(6)), GATE(FUSE, "fuse", "clk_m", H(7)), GATE(KFUSE, "kfuse", "clk_m", H(8)), GATE(SBC1, "spi1", "pc_spi1", H(9)), GATE(SBC2, "spi2", "pc_spi2", H(12)), GATE(SBC3, "spi3", "pc_spi3", H(14)), GATE(I2C5, "i2c5", "pc_i2c5", H(15)), GATE(DSIA, "dsia", "pllD_dsi_csi", H(16)), GATE(CSI, "csi", "pllP_out3", H(20)), GATE(I2C2, "i2c2", "pc_i2c2", H(22)), GATE(UARTC, "uartc", "pc_uartc", H(23)), GATE(MIPI_CAL, "mipi_cal", "clk_m", H(24)), GATE(EMC, "emc", "pc_emc", H(25)), GATE(USB2, "usb2", "clk_m", H(26)), GATE(BSEV, "bsev", "clk_m", H(31)), /* bank U -> 64-95 */ GATE(UARTD, "uartd", "pc_uartd", U(1)), GATE(I2C3, "i2c3", "pc_i2c3", U(3)), GATE(SBC4, "spi4", "pc_spi4", U(4)), GATE(SDMMC3, "sdmmc3", "pc_sdmmc3", U(5)), GATE(PCIE, "pcie", "clk_m", U(6)), GATE(AFI, "afi", "clk_m", U(8)), GATE(CSITE, "csite", "pc_csite", U(9)), GATE(SOC_THERM, "soc_therm", "pc_soc_therm", U(14)), GATE(DTV, "dtv", "clk_m", U(15)), GATE(I2CSLOW, "i2c_slow", "pc_i2c_slow", U(17)), GATE(DSIB, "dsib", "pllD_dsi_csi", U(18)), GATE(TSEC, "tsec", "pc_tsec", U(19)), GATE(IRAMA, "irama", "clk_m", U(20)), GATE(IRAMB, "iramb", "clk_m", U(21)), GATE(IRAMC, "iramc", "clk_m", U(22)), GATE(IRAMD, "iramd", "clk_m", U(23)), GATE(CRAM2, "cram2", "clk_m", U(24)), GATE(XUSB_HOST, "xusb_host", "pc_xusb_core_host", U(25)), GATE(M_DOUBLER, "m_doubler", "clk_m", U(26)), GATE(CSUS, "sus_out", "clk_m", U(28)), GATE(DEVD2_OUT, "devd2_out", "clk_m", U(29)), GATE(DEVD1_OUT, "devd1_out", "clk_m", U(30)), GATE(XUSB_DEV, "xusb_core_dev", "pc_xusb_core_dev", U(31)), /* bank V -> 96-127 */ GATE(CPUG, "cpug", "clk_m", V(0)), GATE(MSELECT, "mselect", "pc_mselect", V(3)), GATE(TSENSOR, "tsensor", "pc_tsensor", V(4)), GATE(I2S4, "i2s5", "pc_i2s5", V(5)), GATE(I2S3, "i2s4", "pc_i2s4", V(6)), GATE(I2C4, "i2c4", "pc_i2c4", V(7)), GATE(D_AUDIO, "ahub", "pc_ahub", V(10)), GATE(APB2APE, "apb2ape", "clk_m", V(11)), GATE(HDA2CODEC_2X, "hda2codec_2x", "pc_hda2codec_2x", V(15)), GATE(ATOMICS, "atomics", "clk_m", V(16)), GATE(SPDIF_2X, "spdif_doubler", "clk_m", V(22)), GATE(ACTMON, "actmon", "pc_actmon", V(23)), GATE(EXTERN1, "extperiph1", "pc_extperiph1", V(24)), GATE(EXTERN2, "extperiph2", "pc_extperiph2", V(25)), GATE(EXTERN3, "extperiph3", "pc_extperiph3", V(26)), GATE(SATA_OOB, "sata_oob", "pc_sata_oob", V(27)), GATE(SATA, "sata", "pc_sata", V(28)), GATE(HDA, "hda", "pc_hda", V(29)), /* bank W -> 128-159*/ GATE(HDA2HDMI, "hda2hdmi", "clk_m", W(0)), /* GATE(SATA_COLD, "sata_cold", "clk_m", W(1)),*/ /* Reset only */ GATE(PCIERX0, "pcierx0", "clk_m", W(2)), GATE(PCIERX1, "pcierx1", "clk_m", W(3)), GATE(PCIERX2, "pcierx2", "clk_m", W(4)), GATE(PCIERX3, "pcierx3", "clk_m", W(5)), GATE(PCIERX4, "pcierx4", "clk_m", W(6)), GATE(PCIERX5, "pcierx5", "clk_m", W(7)), GATE(CEC, "cec", "clk_m", W(8)), GATE(PCIE2_IOBIST, "pcie2_iobist", "clk_m", W(9)), GATE(EMC_IOBIST, "emc_iobist", "clk_m", W(10)), GATE(SATA_IOBIST, "sata_iobist", "clk_m", W(12)), GATE(MIPI_IOBIST, "mipi_iobist", "clk_m", W(13)), GATE(XUSB_GATE, "xusb_gate", "clk_m", W(15)), GATE(CILAB, "cilab", "pc_cilab", W(16)), GATE(CILCD, "cilcd", "pc_cilcd", W(17)), GATE(CILE, "cilef", "pc_cilef", W(18)), GATE(DSIALP, "dsia_lp", "pc_dsia_lp", W(19)), GATE(DSIBLP, "dsib_lp", "pc_dsib_lp", W(20)), GATE(ENTROPY, "entropy", "pc_entropy", W(21)), GATE(DFLL_REF, "dvfs_ref", "pc_dvfs_ref", W(27)), GATE(DFLL_SOC, "dvfs_soc", "pc_dvfs_soc", W(27)), GATE(XUSB_SS, "xusb_ss", "pc_xusb_ss", W(28)), GATE(EMC_LATENCY, "emc_latency", "pc_emc_latency", W(29)), GATE(MC1, "mc1", "clk_m", W(30)), /* bank X -> 160-191*/ /*GATE(SPARE, "spare", "clk_m", X(0)), */ GATE(DMIC1, "dmic1", "clk_m", X(1)), GATE(DMIC2, "dmic2", "clk_m", X(2)), GATE(ETR, "etr", "clk_m", X(3)), GATE(CAM_MCLK, "CAM_MCLK", "clk_m", X(4)), GATE(CAM_MCLK2, "CAM_MCLK2", "clk_m", X(5)), GATE(I2C6, "i2c6", "pc_i2c6", X(6)), GATE(MC_CAPA, "mc_capa", "clk_m", X(7)), GATE(MC_CBPA, "mc_cbpa", "clk_m", X(8)), GATE(MC_CPU, "mc_cpu", "clk_m", X(9)), GATE(MC_BBC, "mc_bbc", "clk_m", X(10)), GATE(VIM2_CLK, "vim2_clk", "clk_m", X(11)), GATE(MIPIBIF, "mipibif", "clk_m", X(13)), GATE(EMC_DLL, "emc_dll", "pc_emc_dll", X(14)), GATE(UART_FST_MIPI_CAL, "uart_fst_mipi_cal", "clk_m", X(17)), GATE(VIC03, "vic", "pc_vic", X(18)), GATE(DPAUX, "dpaux", "dpaux_div", X(21)), GATE(SOR0, "sor0", "pc_sor0", X(22)), GATE(SOR1, "sor1", "pc_sor1", X(23)), GATE(GPU, "gpu", "osc_div_clk", X(24)), GATE(DBGAPB, "dbgapb", "clk_m", X(25)), GATE(HPLL_ADSP, "hpll_adsp", "clk_m", X(26)), GATE(PLLP_ADSP, "pllp_adsp", "clk_m", X(27)), GATE(PLLA_ADSP, "plla_adsp", "clk_m", X(28)), GATE(PLLG_REF, "pllg_ref", "clk_m", X(29)), /* bank Y -> 192-224*/ /* GATE(SPARE1, "spare1", "clk_m", Y(0)), */ GATE(SDMMC_LEGACY, "sdmmc_legacy_tm", "pc_sdmmc_legacy_tm", Y(1)), GATE(NVDEC, "nvdec", "pc_nvdec", Y(2)), GATE(NVJPG, "nvjpg", "clk_m", Y(3)), GATE(AXIAP, "axiap", "clk_m", Y(4)), GATE(DMIC3, "dmic3", "clk_m", Y(5)), GATE(APE, "ape", "clk_m", Y(6)), GATE(ADSP, "adsp", "clk_m", Y(7)), GATE(MC_CDPA, "mc_cdpa", "clk_m", Y(8)), GATE(MC_CCPA, "mc_ccpa", "clk_m", Y(9)), GATE(MAUD, "mc_maud", "clk_m", Y(10)), GATE(TSECB, "tsecb", "clk_m", Y(14)), GATE(DPAUX1, "dpaux1", "dpaux1_div", Y(15)), GATE(VI_I2C, "vi_i2c", "clk_m", Y(16)), GATE(HSIC_TRK, "hsic_trk", "clk_m", Y(17)), GATE(USB2_TRK, "usb2_trk", "clk_m", Y(18)), GATE(QSPI, "qspi", "clk_m", Y(19)), GATE(UARTAPE, "uarape", "clk_m", Y(20)), GATE(ADSP_NEON, "adspneon", "clk_m", Y(26)), GATE(NVENC, "nvenc", "clk_m", Y(27)), GATE(IQC2, "iqc2", "clk_m", Y(28)), GATE(IQC1, "iqc1", "clk_m", Y(29)), GATE(SOR_SAFE, "sor_safe", "sor_safe_div", Y(30)), GATE(PLL_P_OUT_CPU, "pllp_out_cpu", "clk_m", Y(31)), }; /* Peripheral clock clock */ #define DCF_HAVE_MUX 0x0100 /* Block with multipexor */ #define DCF_HAVE_ENA 0x0200 /* Block with enable bit */ #define DCF_HAVE_DIV 0x0400 /* Block with divider */ /* Mark block with additional bits / functionality. */ #define DCF_IS_MASK 0x00FF #define DCF_IS_UART 0x0001 #define DCF_IS_VI 0x0002 #define DCF_IS_HOST1X 0x0003 #define DCF_IS_XUSB_SS 0x0004 #define DCF_IS_EMC_DLL 0x0005 #define DCF_IS_SATA 0x0006 #define DCF_IS_VIC 0x0007 #define DCF_IS_AHUB 0x0008 #define DCF_IS_SOR0 0x0009 #define DCF_IS_EMC 0x000A #define DCF_IS_QSPI 0x000B #define DCF_IS_EMC_SAFE 0x000C /* Basic pheripheral clock */ #define PER_CLK(_id, cn, pl, r, diw, fiw, f) \ { \ .clkdef.id = _id, \ .clkdef.name = cn, \ .clkdef.parent_names = pl, \ .clkdef.parent_cnt = nitems(pl), \ .clkdef.flags = CLK_NODE_STATIC_STRINGS, \ .base_reg = r, \ .div_width = diw, \ .div_f_width = fiw, \ .flags = f, \ } /* Mux with fractional 8.1 divider. */ #define CLK_8_1(id, cn, pl, r, f) \ PER_CLK(id, cn, pl, r, 8, 1, (f) | DCF_HAVE_MUX | DCF_HAVE_DIV) /* Mux with integer 8bits divider. */ #define CLK_8_0(id, cn, pl, r, f) \ PER_CLK(id, cn, pl, r, 8, 0, (f) | DCF_HAVE_MUX | DCF_HAVE_DIV) /* Mux with fractional 16.1 divider. */ #define CLK16_1(id, cn, pl, r, f) \ PER_CLK(id, cn, pl, r, 16, 1, (f) | DCF_HAVE_MUX | DCF_HAVE_DIV) /* Mux with integer 16bits divider. */ #define CLK16_0(id, cn, pl, r, f) \ PER_CLK(id, cn, pl, r, 16, 0, (f) | DCF_HAVE_MUX | DCF_HAVE_DIV) /* Mux wihout divider. */ #define CLK_0_0(id, cn, pl, r, f) \ PER_CLK(id, cn, pl, r, 0, 0, (f) | DCF_HAVE_MUX) static struct periph_def periph_def[] = { CLK_8_1(0, "pc_i2s2", mux_a_N_audio1_N_p_N_clkm, CLK_SOURCE_I2S2, DCF_HAVE_ENA), CLK_8_1(0, "pc_i2s3", mux_a_N_audio2_N_p_N_clkm, CLK_SOURCE_I2S3, DCF_HAVE_ENA), CLK_8_1(0, "pc_spdif_out", mux_a_N_audio_N_p_N_clkm, CLK_SOURCE_SPDIF_OUT, 0), CLK_8_1(0, "pc_spdif_in", mux_p_c2_c_c4_clkm_c4o1_c4o2, CLK_SOURCE_SPDIF_IN, 0), CLK_8_1(0, "pc_pwm", mux_p_c2_c_c4_clks_c4o1_clkm_c4o2, CLK_SOURCE_PWM, 0), CLK_8_1(0, "pc_spi2", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_SPI2, 0), CLK_8_1(0, "pc_spi3", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_SPI3, 0), CLK16_0(0, "pc_i2c1", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_I2C1, 0), CLK16_0(0, "pc_i2c5", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_I2C5, 0), CLK_8_1(0, "pc_spi1", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_SPI1, 0), CLK_0_0(0, "pc_disp1", mux_p_N_d_N_N_d2_clkm, CLK_SOURCE_DISP1, 0), CLK_0_0(0, "pc_disp2", mux_p_N_d_N_N_d2_clkm, CLK_SOURCE_DISP2, 0), CLK_8_1(0, "pc_isp", mux_N_c_p_a1_c2_c3_clkm_c4, CLK_SOURCE_ISP, 0), CLK_8_1(0, "pc_vi", mux_N_c2_c_c3_p_clkm_a1_c4, CLK_SOURCE_VI, DCF_IS_VI), CLK_8_1(0, "pc_sdmmc1", mux_p_N_N_c4o2_c4o1_N_clkm_c4, CLK_SOURCE_SDMMC1, 0), CLK_8_1(0, "pc_sdmmc2", mux_p_N_N_c4o2_c4o1_N_clkm_c4, CLK_SOURCE_SDMMC2, 0), CLK_8_1(0, "pc_sdmmc4", mux_p_N_N_c4o2_c4o1_N_clkm_c4, CLK_SOURCE_SDMMC4, 0), CLK16_1(0, "pc_uarta", mux_p_c2_c_c4_c4o1_clkm_c4o2, CLK_SOURCE_UARTA, DCF_IS_UART), CLK16_1(0, "pc_uartb", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_UARTB, DCF_IS_UART), CLK_8_1(0, "pc_host1x", mux_c4o1_c2_c_c4_p_clkm_a_c4, CLK_SOURCE_HOST1X, DCF_IS_HOST1X), CLK16_0(0, "pc_i2c2", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_I2C2, 0), CLK_8_1(0, "pc_emc", mux_m_c_p_clkm_mud_mbud_mb_pud, CLK_SOURCE_EMC, DCF_IS_EMC), CLK16_1(0, "pc_uartc", mux_p_c2_c_c4_c4o1_clkm_c4o2, CLK_SOURCE_UARTC, DCF_IS_UART), CLK_8_1(0, "pc_vi_sensor", mux_N_c2_c_c3_p_N_a, CLK_SOURCE_VI_SENSOR, 0), CLK_8_1(0, "pc_spi4", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_SPI4, 0), CLK16_0(0, "pc_i2c3", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_I2C3, 0), CLK_8_1(0, "pc_sdmmc3", mux_p_c2_c_c3_m_e_clkm, CLK_SOURCE_SDMMC3, 0), CLK16_1(0, "pc_uartd", mux_p_c2_c_c4_c4o1_clkm_c4o2, CLK_SOURCE_UARTD, DCF_IS_UART), CLK_8_1(0, "pc_csite", mux_p_c2_refe1_c3_m_a1_clkm_C4, CLK_SOURCE_CSITE, 0), CLK_8_1(0, "pc_i2s1", mux_a_N_audio0_N_p_N_clkm, CLK_SOURCE_I2S1, 0), /* DTV xxx */ CLK_8_1(0, "pc_tsec", mux_p_c2_c_c3_N_a1_clkm_c4, CLK_SOURCE_TSEC, 0), /* SPARE2 */ CLK_8_1(0, "pc_mselect", mux_p_c2_c_c4o2_c4o1_clks_clkm_c4, CLK_SOURCE_MSELECT, 0), CLK_8_1(0, "pc_tsensor", mux_p_c2_c_c4_clkm_c4o1_clks_c4o2, CLK_SOURCE_TSENSOR, 0), CLK_8_1(0, "pc_i2s4", mux_a_N_audio3_N_p_N_clkm, CLK_SOURCE_I2S3, DCF_HAVE_ENA), CLK_8_1(0, "pc_i2s5", mux_a_N_audio4_N_p_N_clkm, CLK_SOURCE_I2S4, DCF_HAVE_ENA), CLK16_0(0, "pc_i2c4", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_I2C4, 0), CLK_8_1(0, "pc_ahub", mux_sep_audio, CLK_SOURCE_AHUB, DCF_IS_AHUB), CLK_8_1(0, "pc_hda2codec_2x", mux_p_c2_c_c4_a_c4o1_clkm_c4o2, CLK_SOURCE_HDA2CODEC_2X, 0), CLK_8_1(0, "pc_actmon", mux_p_c2_c_c4_clks_c4o1_clkm_c4o2, CLK_SOURCE_ACTMON, 0), CLK_8_1(0, "pc_extperiph1", mux_a_clks_p_clkm_e, CLK_SOURCE_EXTPERIPH1, 0), CLK_8_1(0, "pc_extperiph2", mux_a_clks_p_clkm_e, CLK_SOURCE_EXTPERIPH2, 0), CLK_8_1(0, "pc_extperiph3", mux_a_clks_p_clkm_e, CLK_SOURCE_EXTPERIPH3, 0), CLK_8_1(0, "pc_i2c_slow", mux_p_c2_c_c4_clks_c4o1_clkm_c4o2, CLK_SOURCE_I2C_SLOW, 0), /* SYS */ CLK_8_1(0, "pc_ispb", mux_N_N_c_N_p_N_a, CLK_SOURCE_ISPB, 0), CLK_8_1(0, "pc_sor1", mux_p_N_d_N_N_d2_clkm, CLK_SOURCE_SOR1, DCF_IS_SOR0), CLK_8_1(0, "pc_sor0", mux_p_m_d_a_c_d2_clkm, CLK_SOURCE_SOR0, DCF_IS_SOR0), CLK_8_1(0, "pc_sata_oob", mux_p_c4_c_c4o1_N_c4o2_clkm, CLK_SOURCE_SATA_OOB, 0), CLK_8_1(0, "pc_sata", mux_p_N_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_SATA, DCF_IS_SATA), CLK_8_1(0, "pc_hda", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_HDA, 0), CLK_8_1(TEGRA210_CLK_XUSB_HOST_SRC, "pc_xusb_core_host", mux_clkm_p_N_N_N_refre, CLK_SOURCE_XUSB_CORE_HOST, 0), CLK_8_1(TEGRA210_CLK_XUSB_FALCON_SRC, "pc_xusb_falcon", mux_clkm_p_N_N_N_refre, CLK_SOURCE_XUSB_FALCON, 0), CLK_8_1(TEGRA210_CLK_XUSB_FS_SRC, "pc_xusb_fs", mux_clkm_N_u48_N_p_N_u480, CLK_SOURCE_XUSB_FS, 0), CLK_8_1(TEGRA210_CLK_XUSB_DEV_SRC, "pc_xusb_core_dev", mux_clkm_p_N_N_N_refre, CLK_SOURCE_XUSB_CORE_DEV, 0), CLK_8_1(TEGRA210_CLK_XUSB_SS_SRC, "pc_xusb_ss", mux_clkm_refe_clks_u480, CLK_SOURCE_XUSB_SS, DCF_IS_XUSB_SS), CLK_8_1(0, "pc_cilab", mux_p_N_c_c4_c4o1_c4o2_clkm, CLK_SOURCE_CILAB, 0), CLK_8_1(0, "pc_cilcd", mux_p_N_c_c4_c4o1_c4o2_clkm, CLK_SOURCE_CILCD, 0), CLK_8_1(0, "pc_cilef", mux_p_N_c_c4_c4o1_c4o2_clkm, CLK_SOURCE_CILEF, 0), CLK_8_1(0, "pc_dsia_lp", mux_p_N_c_c4_c4o1_c4o2_clkm, CLK_SOURCE_DSIA_LP, 0), CLK_8_1(0, "pc_dsib_lp", mux_p_N_c_c4_c4o1_c4o2_clkm, CLK_SOURCE_DSIB_LP, 0), CLK_8_1(0, "pc_entropy", mux_p_N_clkm_N_clks_N_E, CLK_SOURCE_ENTROPY, 0), CLK_8_1(0, "pc_dvfs_ref", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_DVFS_REF, DCF_HAVE_ENA), CLK_8_1(0, "pc_dvfs_soc", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_DVFS_SOC, DCF_HAVE_ENA), CLK_8_1(0, "pc_emc_latency", mux_N_c_p_clkm_N_c4_c4o1_c4o2, CLK_SOURCE_EMC_LATENCY, 0), CLK_8_1(0, "pc_soc_therm", mux_N_c_p_clkm_N_c4_c4o1_c4o1, CLK_SOURCE_SOC_THERM, 0), CLK_8_1(0, "pc_dmic1", mux_a_audiod1_p_clkm, CLK_SOURCE_DMIC1, 0), CLK_8_1(0, "pc_dmic2", mux_a_audiod2_p_clkm, CLK_SOURCE_DMIC2, 0), CLK_8_1(0, "pc_vi_sensor2", mux_N_c2_c_c3_p_N_a, CLK_SOURCE_VI_SENSOR2, 0), CLK16_0(0, "pc_i2c6", mux_p_c2_c_c4_N_c4o1_clkm_c4o2, CLK_SOURCE_I2C6, 0), /* MIPIBIF */ CLK_8_1(0, "pc_emc_dll", mux_m_c_p_clkm_mud_mbud_mb_pud, CLK_SOURCE_EMC_DLL, DCF_IS_EMC_DLL), CLK_8_1(0, "pc_uart_fst_mipi_cal", mux_p_c_c2_N_c2_N_clkm, CLK_SOURCE_UART_FST_MIPI_CAL, 0), CLK_8_1(0, "pc_vic", mux_N_c_p_a1_c2_c3_clkm, CLK_SOURCE_VIC, DCF_IS_VIC), CLK_8_1(0, "pc_sdmmc_legacy_tm", mux_po3_c_c2_clkm_p_c4_c4o1_c4o2, CLK_SOURCE_SDMMC_LEGACY_TM, 0), CLK_8_1(0, "pc_nvdec", mux_N_c2_c_c3_p_N_a1_clkm, CLK_SOURCE_NVDEC, 0), CLK_8_1(0, "pc_nvjpg", mux_N_c2_c_c3_p_N_a1_clkm, CLK_SOURCE_NVJPG, 0), CLK_8_1(0, "pc_nvenc", mux_N_c2_c_c3_p_N_a1_clkm, CLK_SOURCE_NVENC, 0), CLK_8_1(0, "pc_dmic3", mux_a_audiod3_p_clkm, CLK_SOURCE_DMIC3, 0), CLK_8_1(0, "pc_ape", mux_a_c4_c_c4o1_p_N_clkm_c4o2, CLK_SOURCE_APE, 0), CLK_8_1(0, "pc_qspi", mux_p_co1_c_N_c4o2_c4o1_clkm_c4, CLK_SOURCE_QSPI, DCF_IS_QSPI), CLK_8_1(0, "pc_vi_i2c", mux_p_c2_c_c3_N_N_clkm, CLK_SOURCE_VI_I2C, 0), /* USB2_HSIC_TRK */ CLK_8_0(0, "pc_maud", mux_p_po3_clkm_clks_a, CLK_SOURCE_MAUD, 0), CLK_8_1(0, "pc_tsecb", mux_p_c2_c_c3_N_a1_clkm_c4, CLK_SOURCE_TSECB, 0), CLK_8_1(0, "pc_uartape", mux_p_c2_c_c3_N_N_clkm, CLK_SOURCE_UARTAPE, 0), CLK_8_1(0, "pc_dbgapb", mux_N_N_p_N_N_N_clkm, CLK_SOURCE_DBGAPB, 0), CLK_8_1(0, "pc_emc_safe", mux_m_c_p_clkm_mud_mbud_mb_pud, CLK_SOURCE_EMC_SAFE, DCF_IS_EMC_SAFE), }; static int periph_init(struct clknode *clk, device_t dev); static int periph_recalc(struct clknode *clk, uint64_t *freq); static int periph_set_freq(struct clknode *clk, uint64_t fin, uint64_t *fout, int flags, int *stop); static int periph_set_mux(struct clknode *clk, int idx); struct periph_sc { device_t clkdev; uint32_t base_reg; uint32_t div_shift; uint32_t div_width; uint32_t div_mask; uint32_t div_f_width; uint32_t div_f_mask; uint32_t flags; uint32_t divider; int mux; }; static clknode_method_t periph_methods[] = { /* Device interface */ CLKNODEMETHOD(clknode_init, periph_init), CLKNODEMETHOD(clknode_recalc_freq, periph_recalc), CLKNODEMETHOD(clknode_set_freq, periph_set_freq), CLKNODEMETHOD(clknode_set_mux, periph_set_mux), CLKNODEMETHOD_END }; DEFINE_CLASS_1(tegra210_periph, tegra210_periph_class, periph_methods, sizeof(struct periph_sc), clknode_class); static int periph_init(struct clknode *clk, device_t dev) { struct periph_sc *sc; uint32_t reg; sc = clknode_get_softc(clk); DEVICE_LOCK(sc); if (sc->flags & DCF_HAVE_ENA) MD4(sc, sc->base_reg, PERLCK_ENA_MASK, PERLCK_ENA_MASK); RD4(sc, sc->base_reg, ®); DEVICE_UNLOCK(sc); /* Stnadard mux. */ if (sc->flags & DCF_HAVE_MUX) sc->mux = (reg >> PERLCK_MUX_SHIFT) & PERLCK_MUX_MASK; else sc->mux = 0; if (sc->flags & DCF_HAVE_DIV) sc->divider = (reg & sc->div_mask) + 2; else sc->divider = 1; if ((sc->flags & DCF_IS_MASK) == DCF_IS_UART) { if (!(reg & PERLCK_UDIV_DIS)) sc->divider = 2; } /* AUDIO MUX */ if ((sc->flags & DCF_IS_MASK) == DCF_IS_AHUB) { if (!(reg & PERLCK_AMUX_DIS) && (sc->mux == 7)) { sc->mux = 8 + ((reg >> PERLCK_AMUX_SHIFT) & PERLCK_MUX_MASK); } } clknode_init_parent_idx(clk, sc->mux); return(0); } static int periph_set_mux(struct clknode *clk, int idx) { struct periph_sc *sc; uint32_t reg; sc = clknode_get_softc(clk); if (!(sc->flags & DCF_HAVE_MUX)) return (ENXIO); sc->mux = idx; DEVICE_LOCK(sc); RD4(sc, sc->base_reg, ®); reg &= ~(PERLCK_MUX_MASK << PERLCK_MUX_SHIFT); if ((sc->flags & DCF_IS_MASK) == DCF_IS_AHUB) { reg &= ~PERLCK_AMUX_DIS; reg &= ~(PERLCK_MUX_MASK << PERLCK_AMUX_SHIFT); if (idx <= 7) { reg |= idx << PERLCK_MUX_SHIFT; } else { reg |= 7 << PERLCK_MUX_SHIFT; reg |= (idx - 8) << PERLCK_AMUX_SHIFT; } } else { reg |= idx << PERLCK_MUX_SHIFT; } WR4(sc, sc->base_reg, reg); DEVICE_UNLOCK(sc); return(0); } static int periph_recalc(struct clknode *clk, uint64_t *freq) { struct periph_sc *sc; uint32_t reg; sc = clknode_get_softc(clk); if (sc->flags & DCF_HAVE_DIV) { DEVICE_LOCK(sc); RD4(sc, sc->base_reg, ®); DEVICE_UNLOCK(sc); *freq = (*freq << sc->div_f_width) / sc->divider; } return (0); } static int periph_set_freq(struct clknode *clk, uint64_t fin, uint64_t *fout, int flags, int *stop) { struct periph_sc *sc; uint64_t tmp, divider; sc = clknode_get_softc(clk); if (!(sc->flags & DCF_HAVE_DIV)) { *stop = 0; return (0); } tmp = fin << sc->div_f_width; divider = tmp / *fout; if ((tmp % *fout) != 0) divider++; if (divider < (1 << sc->div_f_width)) divider = 1 << (sc->div_f_width - 1); if (flags & CLK_SET_DRYRUN) { if (((flags & (CLK_SET_ROUND_UP | CLK_SET_ROUND_DOWN)) == 0) && (*fout != (tmp / divider))) return (ERANGE); } else { DEVICE_LOCK(sc); MD4(sc, sc->base_reg, sc->div_mask, (divider - (1 << sc->div_f_width))); DEVICE_UNLOCK(sc); sc->divider = divider; } *fout = tmp / divider; *stop = 1; return (0); } static int periph_register(struct clkdom *clkdom, struct periph_def *clkdef) { struct clknode *clk; struct periph_sc *sc; clk = clknode_create(clkdom, &tegra210_periph_class, &clkdef->clkdef); if (clk == NULL) return (1); sc = clknode_get_softc(clk); sc->clkdev = clknode_get_device(clk); sc->base_reg = clkdef->base_reg; sc->div_width = clkdef->div_width; sc->div_mask = (1 <div_width) - 1; sc->div_f_width = clkdef->div_f_width; sc->div_f_mask = (1 <div_f_width) - 1; sc->flags = clkdef->flags; clknode_register(clkdom, clk); return (0); } /* -------------------------------------------------------------------------- */ static int pgate_init(struct clknode *clk, device_t dev); static int pgate_set_gate(struct clknode *clk, bool enable); struct pgate_sc { device_t clkdev; uint32_t idx; uint32_t flags; uint32_t enabled; }; static clknode_method_t pgate_methods[] = { /* Device interface */ CLKNODEMETHOD(clknode_init, pgate_init), CLKNODEMETHOD(clknode_set_gate, pgate_set_gate), CLKNODEMETHOD_END }; DEFINE_CLASS_1(tegra210_pgate, tegra210_pgate_class, pgate_methods, sizeof(struct pgate_sc), clknode_class); static uint32_t get_enable_reg(int idx) { KASSERT(idx / 32 < nitems(clk_enable_reg), ("Invalid clock index for enable: %d", idx)); return (clk_enable_reg[idx / 32]); } static uint32_t get_reset_reg(int idx) { KASSERT(idx / 32 < nitems(clk_reset_reg), ("Invalid clock index for reset: %d", idx)); return (clk_reset_reg[idx / 32]); } static int pgate_init(struct clknode *clk, device_t dev) { struct pgate_sc *sc; uint32_t ena_reg, rst_reg, mask; sc = clknode_get_softc(clk); mask = 1 << (sc->idx % 32); DEVICE_LOCK(sc); RD4(sc, get_enable_reg(sc->idx), &ena_reg); RD4(sc, get_reset_reg(sc->idx), &rst_reg); DEVICE_UNLOCK(sc); sc->enabled = ena_reg & mask ? 1 : 0; clknode_init_parent_idx(clk, 0); return(0); } static int pgate_set_gate(struct clknode *clk, bool enable) { struct pgate_sc *sc; uint32_t reg, mask, base_reg; sc = clknode_get_softc(clk); mask = 1 << (sc->idx % 32); sc->enabled = enable; base_reg = get_enable_reg(sc->idx); DEVICE_LOCK(sc); MD4(sc, base_reg, mask, enable ? mask : 0); RD4(sc, base_reg, ®); DEVICE_UNLOCK(sc); DELAY(2); return(0); } int tegra210_hwreset_by_idx(struct tegra210_car_softc *sc, intptr_t idx, bool reset) { uint32_t reg, mask, reset_reg; CLKDEV_DEVICE_LOCK(sc->dev); if (idx == TEGRA210_RST_DFLL_DVCO) { CLKDEV_MODIFY_4(sc->dev, DFLL_BASE, DFLL_BASE_DVFS_DFLL_RESET, reset ? DFLL_BASE_DVFS_DFLL_RESET : 0); CLKDEV_READ_4(sc->dev, DFLL_BASE, ®); } if (idx == TEGRA210_RST_ADSP) { reset_reg = (reset) ? RST_DEV_Y_SET: RST_DEV_Y_CLR; mask = (0x1F << 22) |(1 << 7); CLKDEV_WRITE_4(sc->dev, reset_reg, mask); CLKDEV_READ_4(sc->dev, reset_reg, ®); } else { mask = 1 << (idx % 32); reset_reg = get_reset_reg(idx); CLKDEV_MODIFY_4(sc->dev, reset_reg, mask, reset ? mask : 0); CLKDEV_READ_4(sc->dev, reset_reg, ®); } CLKDEV_DEVICE_UNLOCK(sc->dev); return(0); } static int pgate_register(struct clkdom *clkdom, struct pgate_def *clkdef) { struct clknode *clk; struct pgate_sc *sc; clk = clknode_create(clkdom, &tegra210_pgate_class, &clkdef->clkdef); if (clk == NULL) return (1); sc = clknode_get_softc(clk); sc->clkdev = clknode_get_device(clk); sc->idx = clkdef->idx; sc->flags = clkdef->flags; clknode_register(clkdom, clk); return (0); } void tegra210_periph_clock(struct tegra210_car_softc *sc) { int i, rv; for (i = 0; i < nitems(periph_def); i++) { rv = periph_register(sc->clkdom, &periph_def[i]); if (rv != 0) panic("tegra210_periph_register failed"); } for (i = 0; i < nitems(pgate_def); i++) { rv = pgate_register(sc->clkdom, &pgate_def[i]); if (rv != 0) panic("tegra210_pgate_register failed"); } }