drivers/vpu/aml_vpu.c - manifest_repos/u-boot - Git at Google

 /* SPDX-License-Identifier: (GPL-2.0+ OR MIT) */
 /*
  * drivers/vpu/aml_vpu.c
  *
  * Copyright (C) 2020 Amlogic, Inc. All rights reserved.
  *
  */

 #include <asm/cpu_id.h>
 #include <config.h>
 #include <linux/kernel.h>
 #ifdef CONFIG_OF_LIBFDT
 #include <libfdt.h>
 #endif
 #include <vpu.h>
 #include "aml_vpu_reg.h"
 #include "aml_vpu.h"
 #include "aml_vpu_ctrl.h"

 /* v04: add txlx support */
 /* v05: add axg support */
 /* v06: add g12a support */
 /* v20180925: add tl1 support */
 /* v20190313: add sm1 support */
 #define VPU_VERION	"v20190313"

 #ifdef CONFIG_OF_LIBFDT
 static char *dt_addr;
 #endif
 static int dts_ready = 0;

 struct vpu_conf_s vpu_conf = {
 	.data = NULL,

 	.clk_level = 0,
 	.fclk_freq = FCLK_2000M,
 };

 static struct vpu_data_s vpu_data_gxb = {
 	.chip_type = VPU_CHIP_GXBB,
 	.chip_name = "gxbb",
 	.clk_level_dft = CLK_LEVEL_DFT_GXBB,
 	.clk_level_max = CLK_LEVEL_MAX_GXBB,
 	.gp_pll_valid = 0,

 	.fclk_div_table = fclk_div_table_gxb,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_gxb,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_gxb,
 	.reset_table = vpu_reset_gx,

 	.module_init_table_cnt = 0,
 	.module_init_table = NULL,
 };

 static struct vpu_data_s vpu_data_gxtvbb = {
 	.chip_type = VPU_CHIP_GXTVBB,
 	.chip_name = "gxtvbb",
 	.clk_level_dft = CLK_LEVEL_DFT_GXTVBB,
 	.clk_level_max = CLK_LEVEL_MAX_GXTVBB,
 	.gp_pll_valid = 1,

 	.fclk_div_table = fclk_div_table_gxb,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_gxb,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_gxb,
 	.reset_table = vpu_reset_gx,

 	.module_init_table_cnt = 0,
 	.module_init_table = NULL,
 };

 static struct vpu_data_s vpu_data_gxl = {
 	.chip_type = VPU_CHIP_GXL,
 	.chip_name = "gxl",
 	.clk_level_dft = CLK_LEVEL_DFT_GXL,
 	.clk_level_max = CLK_LEVEL_MAX_GXL,
 	.gp_pll_valid = 0,

 	.fclk_div_table = fclk_div_table_gxb,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_gxb,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_gxb,
 	.reset_table = vpu_reset_gx,

 	.module_init_table_cnt = 0,
 	.module_init_table = NULL,
 };

 static struct vpu_data_s vpu_data_gxm = {
 	.chip_type = VPU_CHIP_GXM,
 	.chip_name = "gxm",
 	.clk_level_dft = CLK_LEVEL_DFT_GXM,
 	.clk_level_max = CLK_LEVEL_MAX_GXM,
 	.gp_pll_valid = 0,

 	.fclk_div_table = fclk_div_table_gxb,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_gxb,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_gxb,
 	.reset_table = vpu_reset_gx,

 	.module_init_table_cnt = sizeof(vpu_module_init_gxm) / sizeof(struct vpu_ctrl_s),
 	.module_init_table = vpu_module_init_gxm,
 };

 static struct vpu_data_s vpu_data_txl = {
 	.chip_type = VPU_CHIP_TXL,
 	.chip_name = "txl",
 	.clk_level_dft = CLK_LEVEL_DFT_TXLX,
 	.clk_level_max = CLK_LEVEL_MAX_TXLX,
 	.gp_pll_valid = 0,

 	.fclk_div_table = fclk_div_table_gxb,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_gxb,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_gxb,
 	.reset_table = vpu_reset_gx,

 	.module_init_table_cnt = 0,
 	.module_init_table = NULL,
 };

 static struct vpu_data_s vpu_data_txlx = {
 	.chip_type = VPU_CHIP_TXLX,
 	.chip_name = "txlx",
 	.clk_level_dft = CLK_LEVEL_DFT_TXLX,
 	.clk_level_max = CLK_LEVEL_MAX_TXLX,
 	.gp_pll_valid = 0,

 	.fclk_div_table = fclk_div_table_gxb,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_gxb,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_gxb,
 	.reset_table = vpu_reset_gx,

 	.module_init_table_cnt = sizeof(vpu_module_init_txlx) / sizeof(struct vpu_ctrl_s),
 	.module_init_table = vpu_module_init_txlx,
 };

 static struct vpu_data_s vpu_data_axg = {
 	.chip_type = VPU_CHIP_AXG,
 	.chip_name = "axg",
 	.clk_level_dft = CLK_LEVEL_DFT_AXG,
 	.clk_level_max = CLK_LEVEL_MAX_AXG,
 	.gp_pll_valid = 0,

 	.fclk_div_table = fclk_div_table_gxb,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_axg,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_gxb,
 	.reset_table = vpu_reset_gx,

 	.module_init_table_cnt = 0,
 	.module_init_table = NULL,
 };

 static struct vpu_data_s vpu_data_txhd = {
 	.chip_type = VPU_CHIP_TXHD,
 	.chip_name = "txhd",
 	.clk_level_dft = CLK_LEVEL_DFT_TXHD,
 	.clk_level_max = CLK_LEVEL_MAX_TXHD,
 	.gp_pll_valid = 0,

 	.fclk_div_table = fclk_div_table_gxb,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_txhd,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_gxb,
 	.reset_table = vpu_reset_txhd,

 	.module_init_table_cnt = 0,
 	.module_init_table = NULL,
 };

 static struct vpu_data_s vpu_data_g12a = {
 	.chip_type = VPU_CHIP_G12A,
 	.chip_name = "g12a",
 	.clk_level_dft = CLK_LEVEL_DFT_G12A,
 	.clk_level_max = CLK_LEVEL_MAX_G12A,
 	.gp_pll_valid = 0,

 	.fclk_div_table = fclk_div_table_g12a,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_g12a,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_gxb,
 	.reset_table = vpu_reset_gx,

 	.module_init_table_cnt = sizeof(vpu_module_init_g12a) / sizeof(struct vpu_ctrl_s),
 	.module_init_table = vpu_module_init_g12a,
 };

 static struct vpu_data_s vpu_data_g12b = {
 	.chip_type = VPU_CHIP_G12B,
 	.chip_name = "g12b",
 	.clk_level_dft = CLK_LEVEL_DFT_G12A,
 	.clk_level_max = CLK_LEVEL_MAX_G12A,
 	.gp_pll_valid = 0,

 	.fclk_div_table = fclk_div_table_g12a,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_g12b,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_gxb,
 	.reset_table = vpu_reset_gx,

 	.module_init_table_cnt = sizeof(vpu_module_init_g12a) / sizeof(struct vpu_ctrl_s),
 	.module_init_table = vpu_module_init_g12a,
 };

 static struct vpu_data_s vpu_data_tl1 = {
 	.chip_type = VPU_CHIP_TL1,
 	.chip_name = "tl1",
 	.clk_level_dft = CLK_LEVEL_DFT_G12A,
 	.clk_level_max = CLK_LEVEL_MAX_G12A,
 	.gp_pll_valid = 0,

 	.fclk_div_table = fclk_div_table_g12a,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_tl1,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_gxb,
 	.reset_table = vpu_reset_tl1,

 	.module_init_table_cnt = 0,
 	.module_init_table = NULL,
 };

 static struct vpu_data_s vpu_data_sm1 = {
 	.chip_type = VPU_CHIP_SM1,
 	.chip_name = "sm1",
 	.clk_level_dft = CLK_LEVEL_DFT_G12A,
 	.clk_level_max = CLK_LEVEL_MAX_G12A,
 	.gp_pll_valid = 0,

 	.fclk_div_table = fclk_div_table_g12a,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_tl1,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_sm1,
 	.reset_table = vpu_reset_gx,

 	.module_init_table_cnt = sizeof(vpu_module_init_g12a) / sizeof(struct vpu_ctrl_s),
 	.module_init_table = vpu_module_init_g12a,

 };


 static struct vpu_data_s vpu_data_tm2 = {
 	.chip_type = VPU_CHIP_TM2,
 	.chip_name = "tm2",
 	.clk_level_dft = CLK_LEVEL_DFT_G12A,
 	.clk_level_max = CLK_LEVEL_MAX_G12A,
 	.gp_pll_valid = 0,

 	.fclk_div_table = fclk_div_table_g12a,
 	.vpu_clk_table = vpu_clk_table,

 	.mem_pd_table = vpu_mem_pd_tm2,
 	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
 	.hdmi_iso_table = vpu_hdmi_iso_sm1,
 	.reset_table = vpu_reset_tl1,

 	.module_init_table_cnt = sizeof(vpu_module_init_tm2) / sizeof(struct vpu_ctrl_s),
 	.module_init_table = vpu_module_init_tm2,
 };

 static void vpu_chip_detect(void)
 {
 	unsigned int cpu_type;

 	cpu_type = get_cpu_id().family_id;
 	switch (cpu_type) {
 	case MESON_CPU_MAJOR_ID_GXBB:
 		vpu_conf.data = &vpu_data_gxb;
 		break;
 	case MESON_CPU_MAJOR_ID_GXTVBB:
 		vpu_conf.data = &vpu_data_gxtvbb;
 		break;
 	case MESON_CPU_MAJOR_ID_GXL:
 		vpu_conf.data = &vpu_data_gxl;
 		break;
 	case MESON_CPU_MAJOR_ID_GXM:
 		vpu_conf.data = &vpu_data_gxm;
 		break;
 	case MESON_CPU_MAJOR_ID_TXL:
 		vpu_conf.data = &vpu_data_txl;
 		break;
 	case MESON_CPU_MAJOR_ID_TXLX:
 		vpu_conf.data = &vpu_data_txlx;
 		break;
 	case MESON_CPU_MAJOR_ID_AXG:
 		vpu_conf.data = &vpu_data_axg;
 		break;
 	case MESON_CPU_MAJOR_ID_TXHD:
 		vpu_conf.data = &vpu_data_txhd;
 		break;
 	case MESON_CPU_MAJOR_ID_G12A:
 		vpu_conf.data = &vpu_data_g12a;
 		break;
 	case MESON_CPU_MAJOR_ID_G12B:
 		vpu_conf.data = &vpu_data_g12b;
 		break;
 	case MESON_CPU_MAJOR_ID_TL1:
 		vpu_conf.data = &vpu_data_tl1;
 		break;
 	case MESON_CPU_MAJOR_ID_SM1:
 		vpu_conf.data = &vpu_data_sm1;
 		break;
 	case MESON_CPU_MAJOR_ID_TM2:
 		vpu_conf.data = &vpu_data_tm2;
 		break;
 	default:
 		vpu_conf.data = NULL;
 		break;
 	}

 	strcpy(vpu_conf.drv_version, VPU_VERION);

 	if (vpu_conf.data == NULL) {
 		VPUERR("invalid vpu\n");
 		return ;
 	} else {
 #ifdef CONFIG_VPU_CLK_LEVEL_DFT
 		vpu_conf.data->clk_level_dft = CONFIG_VPU_CLK_LEVEL_DFT;
 #endif

 #ifdef VPU_DEBUG_PRINT
 		VPUPR("driver version: %s\n", vpu_conf.drv_version);
 		VPUPR("detect chip type: %d\n", vpu_conf.data->chip_type);
 		VPUPR("clk_level default: %d(%dHz), max: %d(%dHz)\n",
 			vpu_conf.data->clk_level_dft,
 			(vpu_conf.data->vpu_clk_table + vpu_conf.data->clk_level_dft)->freq,
 			(vpu_conf.data->clk_level_max - 1),
 			(vpu_conf.data->vpu_clk_table + (vpu_conf.data->clk_level_max - 1))->freq);
 #endif
 	}
 }

 static int vpu_check(void)
 {
 	int ret = -1;

 	if (vpu_conf.data == NULL) {
 		VPUERR("invalid vpu\n");
 		return -1;
 	}

 	switch (vpu_conf.data->chip_type) {
 	case VPU_CHIP_GXBB:
 	case VPU_CHIP_GXTVBB:
 	case VPU_CHIP_GXL:
 	case VPU_CHIP_GXM:
 	case VPU_CHIP_TXL:
 	case VPU_CHIP_TXLX:
 	case VPU_CHIP_AXG:
 	case VPU_CHIP_TXHD:
 	case VPU_CHIP_G12A:
 	case VPU_CHIP_G12B:
 	case VPU_CHIP_TL1:
 	case VPU_CHIP_SM1:
 	case VPU_CHIP_TM2:
 		ret = 0;
 		break;
 	default:
 		VPUERR("invalid vpu for current chip\n");
 		break;
 	}

 	return ret;
 }

 static unsigned int get_vpu_clk_level(unsigned int video_clk)
 {
 	unsigned clk_level;
 	int i;

 	for (i = 0; i < vpu_conf.data->clk_level_max; i++) {
 		if (video_clk <= (vpu_conf.data->vpu_clk_table + i)->freq)
 			break;
 	}
 	clk_level = i;

 	return clk_level;
 }

 static unsigned long get_fclk_div_freq(unsigned int mux_id)
 {
 	struct fclk_div_s *fclk_div;
 	unsigned long fclk, div, clk_source = 0;
 	unsigned int i;

 	fclk = vpu_conf.fclk_freq * 1000000;

 	for (i = 0; i < FCLK_DIV_MAX; i++) {
 		fclk_div = vpu_conf.data->fclk_div_table + i;
 		if (fclk_div->fclk_id == mux_id) {
 			div = fclk_div->fclk_div;
 			clk_source = ((fclk * 100 / div) + 99) / 100;
 			break;
 		}
 		if (fclk_div->fclk_id == FCLK_DIV_MAX)
 			break;
 	}

 	return clk_source;
 }

 static unsigned int get_vpu_clk_mux_id(void)
 {
 	struct fclk_div_s *fclk_div;
 	unsigned int i, mux, mux_id;

 	mux = vpu_hiu_getb(HHI_VPU_CLK_CNTL, 9, 3);
 	mux_id = mux;
 	for (i = 0; i < FCLK_DIV_MAX; i++) {
 		fclk_div = vpu_conf.data->fclk_div_table + i;
 		if (fclk_div->fclk_mux == mux) {
 			mux_id = fclk_div->fclk_id;
 			break;
 		}
 		if (fclk_div->fclk_id == FCLK_DIV_MAX)
 			break;
 	}

 	return mux_id;
 }

 static unsigned int get_vpu_clk_mux(unsigned int mux_id)
 {
 	struct fclk_div_s *fclk_div;
 	unsigned int i, mux;

 	mux = mux_id;
 	for (i = 0; i < FCLK_DIV_MAX; i++) {
 		fclk_div = vpu_conf.data->fclk_div_table + i;
 		if (fclk_div->fclk_id == mux_id) {
 			mux = fclk_div->fclk_mux;
 			break;
 		}
 		if (fclk_div->fclk_id == FCLK_DIV_MAX)
 			break;
 	}

 	return mux;
 }

 static unsigned int get_vpu_clk(void)
 {
 	unsigned long clk_freq;
 	unsigned long clk_source, div;
 	unsigned int mux_id;

 	mux_id = get_vpu_clk_mux_id();
 	switch (mux_id) {
 	case FCLK_DIV4:
 	case FCLK_DIV3:
 	case FCLK_DIV5:
 	case FCLK_DIV7:
 		clk_source = get_fclk_div_freq(mux_id);
 		break;
 	case GPLL_CLK:
 		clk_source = (vpu_conf.data->vpu_clk_table + 8)->freq;
 		break;
 	default:
 		clk_source = 0;
 		break;
 	}

 	div = vpu_hiu_getb(HHI_VPU_CLK_CNTL, 0, 7) + 1;
 	clk_freq = ((clk_source * 100 / div) + 99) / 100;

 	return (unsigned int)clk_freq;
 }

 static int switch_gp1_pll_gxtvbb(int flag)
 {
 	int cnt = 100;
 	int ret = 0;

 	if (flag) { /* enable gp1_pll */
 		/* GP1 DPLL 696MHz output*/
 		vpu_hiu_write(HHI_GP1_PLL_CNTL2, 0x69c80000);
 		vpu_hiu_write(HHI_GP1_PLL_CNTL3, 0x0a5590c4);
 		vpu_hiu_write(HHI_GP1_PLL_CNTL4, 0x0000500d);
 		vpu_hiu_write(HHI_GP1_PLL_CNTL, 0x6a01023a);
 		vpu_hiu_write(HHI_GP1_PLL_CNTL, 0x4a01023a);
 		do {
 			udelay(10);
 			vpu_hiu_setb(HHI_GP1_PLL_CNTL, 1, 29, 1); /* reset */
 			udelay(50);
 			/* release reset */
 			vpu_hiu_setb(HHI_GP1_PLL_CNTL, 0, 29, 1);
 			udelay(50);
 			cnt--;
 			if (cnt == 0)
 				break;
 		} while (vpu_hiu_getb(HHI_GP1_PLL_CNTL, 31, 1) == 0);
 		if (vpu_hiu_getb(HHI_GP1_PLL_CNTL, 31, 1) == 0) {
 			ret = -1;
 			vpu_hiu_setb(HHI_GP1_PLL_CNTL, 0, 30, 1);
 			VPUERR("GP1_PLL lock failed\n");
 		}
 	} else { /* disable gp1_pll */
 		vpu_hiu_setb(HHI_GP1_PLL_CNTL, 0, 30, 1);
 	}

 	return ret;
 }

 static int switch_gp_pll(int flag)
 {
 	int ret = -1;

 	if (vpu_conf.data->gp_pll_valid == 0)
 		return ret;

 	switch (vpu_conf.data->chip_type) {
 	case VPU_CHIP_GXTVBB:
 		ret = switch_gp1_pll_gxtvbb(flag);
 		break;
 	default:
 		break;
 	}

 	return ret;
 }

 /* unit: MHz */
 #define VPU_CLKB_MAX    350
 static int adjust_vpu_clk(unsigned int clk_level)
 {
 	struct vpu_clk_s *clk_table;
 	unsigned int vpu_clk;
 	unsigned int mux, div;
 	int ret = 0;

 	/* vpu clk */
 	clk_table = vpu_conf.data->vpu_clk_table + clk_level;
 	mux = get_vpu_clk_mux(clk_table->mux);
 	if (mux == GPLL_CLK) {
 		ret = switch_gp_pll(1);
 		if (ret) {
 			clk_level = vpu_conf.data->clk_level_dft;
 			VPUERR("adjust_vpu_clk: gp pll error, use default clk\n");
 		}
 	}
 	vpu_conf.clk_level = clk_level;
 	clk_table = vpu_conf.data->vpu_clk_table + clk_level;

 	vpu_clk = clk_table->freq;
 	mux = get_vpu_clk_mux(clk_table->mux);
 	div = clk_table->div;

 	vpu_hiu_write(HHI_VPU_CLK_CNTL, ((mux << 9) | (div << 0)));
 	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 1, 8, 1);

 	/* vpu clkb if needed */
 	switch (vpu_conf.data->chip_type) {
 	case VPU_CHIP_GXBB:
 	case VPU_CHIP_GXTVBB:
 	case VPU_CHIP_GXL:
 	case VPU_CHIP_GXM:
 	case VPU_CHIP_TXL:
 		if (vpu_clk >= (VPU_CLKB_MAX * 1000000))
 			vpu_hiu_write(HHI_VPU_CLKB_CNTL, ((1 << 8) | (1 << 0)));
 		else
 			vpu_hiu_write(HHI_VPU_CLKB_CNTL, ((1 << 8) | (0 << 0)));
 		break;
 	default:
 		break;
 	}

 	/* vapb clk */
 	if (vpu_clk >= 250000000) {
 		vpu_hiu_write(HHI_VAPBCLK_CNTL, (1 << 30) | /* turn on ge2d clock */
 						(0 << 9)  | /* clk_sel    //250Mhz */
 						(1 << 0));  /* clk_div */
 	} else {
 		vpu_hiu_write(HHI_VAPBCLK_CNTL, (1 << 30) | /* turn on ge2d clock */
 						(clk_table->mux << 9)  | /* clk_sel */
 						(div << 0));  /* clk_div */
 	}
 	vpu_hiu_setb(HHI_VAPBCLK_CNTL, 1, 8, 1);

 	VPUPR("set clk: %uHz, readback: %uHz(0x%x)\n",
 		vpu_clk, get_vpu_clk(), (vpu_hiu_read(HHI_VPU_CLK_CNTL)));
 	return ret;
 }

 static int set_vpu_clk(unsigned int vclk)
 {
 	int ret = 0;
 	unsigned int clk_level;

 #ifdef VPU_DEBUG_PRINT
 	VPUPR("%s\n", __func__);
 #endif

 	if (vclk >= 100) /* regard as vpu_clk */
 		clk_level = get_vpu_clk_level(vclk);
 	else /* regard as clk_level */
 		clk_level = vclk;

 	if (clk_level >= vpu_conf.data->clk_level_max) {
 		clk_level = vpu_conf.data->clk_level_dft;
 		VPUPR("clk out of supported range, set to default\n");
 	}

 	ret = adjust_vpu_clk(clk_level);

 #ifdef VPU_DEBUG_PRINT
 	VPUPR("%s finish\n", __func__);
 #endif

 	return ret;
 }

 static int get_vpu_config(void)
 {
 #ifdef CONFIG_OF_LIBFDT
 	int nodeoffset;
 	char *propdata;
 #endif

 	if (dts_ready == 1) {
 #ifdef CONFIG_OF_LIBFDT
 		nodeoffset = fdt_path_offset(dt_addr, "/vpu");
 		if (nodeoffset < 0) {
 			VPUERR("not find /vpu node in dts %s\n", fdt_strerror(nodeoffset));
 			return -1;
 		}

 		propdata = (char *)fdt_getprop(dt_addr, nodeoffset, "clk_level", NULL);
 		if (propdata == NULL) {
 			vpu_conf.clk_level = vpu_conf.data->clk_level_dft;
 			VPUERR("don't find clk_level in dts, set to default\n");
 		} else {
 			vpu_conf.clk_level = (unsigned short)(be32_to_cpup((u32*)propdata));
 			if (vpu_conf.clk_level >= vpu_conf.data->clk_level_max) {
 				VPUERR("clk_level in dts is out of support, set to default\n");
 				vpu_conf.clk_level = vpu_conf.data->clk_level_dft;
 			}
 		}
 		VPUPR("clk_level in dts: %u\n", vpu_conf.clk_level);
 #endif
 	} else {
 		vpu_conf.clk_level = vpu_conf.data->clk_level_dft;
 		VPUPR("clk_level = %u\n", vpu_conf.clk_level);
 	}

 	return 0;
 }

 int vpu_probe(void)
 {
 	int ret;

 	dts_ready = 0;
 #ifdef CONFIG_OF_LIBFDT
 #ifdef CONFIG_DTB_MEM_ADDR
 	dt_addr = (char *)CONFIG_DTB_MEM_ADDR;
 #else
 	dt_addr = (char *)0x01000000;
 #endif
 	ret = fdt_check_header((const void *)dt_addr);
 	if (ret < 0) {
 		VPUERR("vpu: check dts: %s, load default parameters\n",
 			fdt_strerror(ret));
 	} else {
 		dts_ready = 1;
 	}
 #endif

 	vpu_chip_detect();
 	if (vpu_check())
 		return -1;

 	ret = get_vpu_config();
 	vpu_power_on();
 	set_vpu_clk(vpu_conf.clk_level);
 	//vpu_power_on();

 	/* vpu module init off, for power save, and special module init */
 	vpu_mem_pd_init_off();
 	vpu_module_init_config();

 	return ret;
 }

 int vpu_remove(void)
 {
 	if (vpu_check())
 		return -1;

 	VPUPR("vpu remove\n");
 	vpu_power_off();
 	return 0;
 }

 static void vpu_clk_switch(void)
 {
 	struct vpu_clk_s *clk_table;
 	unsigned int mux, div;

 	/* step 1: switch to 2nd vpu clk patch */
 	clk_table = vpu_conf.data->vpu_clk_table + vpu_conf.data->clk_level_dft;
 	mux = get_vpu_clk_mux(clk_table->mux);
 	vpu_hiu_setb(HHI_VPU_CLK_CNTL, mux, 25, 3);
 	div = clk_table->div;
 	vpu_hiu_setb(HHI_VPU_CLK_CNTL, div, 16, 7);
 	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 1, 24, 1);
 	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 1, 31, 1);
 	udelay(10);
 	/* step 2: adjust 1st vpu clk frequency */
 	clk_table = vpu_conf.data->vpu_clk_table + vpu_conf.clk_level;
 	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 0, 8, 1);
 	mux = get_vpu_clk_mux(clk_table->mux);
 	vpu_hiu_setb(HHI_VPU_CLK_CNTL, mux, 9, 3);
 	div = clk_table->div;
 	vpu_hiu_setb(HHI_VPU_CLK_CNTL, div, 0, 7);
 	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 1, 8, 1);
 	udelay(20);
 	/* step 3: switch back to 1st vpu clk patch */
 	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 0, 31, 1);
 	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 0, 24, 1);
 }

 int vpu_clk_change(int level)
 {
 	struct vpu_clk_s *clk_table;
 	unsigned int vpu_clk;

 	if (vpu_check())
 		return -1;

 	if (level >= 100) /* regard as vpu_clk */
 		level = get_vpu_clk_level(level);

 	if (level >= vpu_conf.data->clk_level_max) {
 		clk_table = vpu_conf.data->vpu_clk_table + (vpu_conf.data->clk_level_max - 1);
 		VPUPR("clk out of supported range\n");
 		VPUPR("clk max level: %u(%uHz)\n",
 			(vpu_conf.data->clk_level_max - 1),
 			clk_table->freq);
 		return -1;
 	}

 	vpu_conf.clk_level = level;
 	clk_table = vpu_conf.data->vpu_clk_table + vpu_conf.clk_level;
 	vpu_clk = clk_table->freq;

 	vpu_clk_switch();

 	VPUPR("set clk: %uHz, readback: %uHz(0x%x)\n",
 		vpu_clk, get_vpu_clk(), vpu_hiu_read(HHI_VPU_CLK_CNTL));
 	return 0;
 }

 void vpu_clk_get(void)
 {
 	if (vpu_check())
 		return;

 	VPUPR("clk_level: %u, clk: %uHz, reg: 0x%x\n",
 		vpu_conf.clk_level, get_vpu_clk(),
 		vpu_hiu_read(HHI_VPU_CLK_CNTL));
 }

 void vpu_info_print(void)
 {
 	if (vpu_check())
 		return;

 	printf("vpu driver version: %s\n", vpu_conf.drv_version);
 	printf("detect chip type: %d(%s)\n",
 		vpu_conf.data->chip_type,
 		vpu_conf.data->chip_name);
 	printf("clk_level:         %d(%dHz)\n"
 		"clk_level default: %d(%dHz)\n"
 		"clk_level max:     %d(%dHz)\n",
 		vpu_conf.clk_level,
 		(vpu_conf.data->vpu_clk_table + vpu_conf.clk_level)->freq,
 		vpu_conf.data->clk_level_dft,
 		(vpu_conf.data->vpu_clk_table + vpu_conf.data->clk_level_dft)->freq,
 		(vpu_conf.data->clk_level_max - 1),
 		(vpu_conf.data->vpu_clk_table + (vpu_conf.data->clk_level_max - 1))->freq);
 }

 static unsigned int vcbus_reg[] = {
 	0x1b7f, /* VENC_VDAC_TST_VAL */
 	0x1c30, /* ENCP_DVI_HSO_BEGIN */
 	0x1d00, /* VPP_DUMMY_DATA */
 	0x2730, /* VPU_VPU_PWM_V0 */
 };

 void vcbus_test(void)
 {
 	unsigned int val;
 	unsigned int temp;
 	int i,j;

 	if (vpu_check())
 		return;

 	VPUPR("vcbus test:\n");
 	for (i = 0; i < ARRAY_SIZE(vcbus_reg); i++) {
 		for (j = 0; j < 24; j++) {
 			val = vpu_vcbus_read(vcbus_reg[i]);
 			printf("%02d read 0x%04x=0x%08x\n", j, vcbus_reg[i], val);
 		}
 		printf("\n");
 	}
 	temp = 0x5a5a5a5a;
 	for (i = 0; i < ARRAY_SIZE(vcbus_reg); i++) {
 		vpu_vcbus_write(vcbus_reg[i], temp);
 		val = vpu_vcbus_read(vcbus_reg[i]);
 		printf("write 0x%04x=0x%08x, readback: 0x%08x\n", vcbus_reg[i], temp, val);
 	}
 	for (i = 0; i < ARRAY_SIZE(vcbus_reg); i++) {
 		for (j = 0; j < 24; j++) {
 			val = vpu_vcbus_read(vcbus_reg[i]);
 			printf("%02d read 0x%04x=0x%08x\n", j, vcbus_reg[i], val);
 		}
 		printf("\n");
 	}
 }
	/* SPDX-License-Identifier: (GPL-2.0+ OR MIT) */
	/*
	* drivers/vpu/aml_vpu.c
	*
	* Copyright (C) 2020 Amlogic, Inc. All rights reserved.
	*
	*/

	#include <asm/cpu_id.h>
	#include <config.h>
	#include <linux/kernel.h>
	#ifdef CONFIG_OF_LIBFDT
	#include <libfdt.h>
	#endif
	#include <vpu.h>
	#include "aml_vpu_reg.h"
	#include "aml_vpu.h"
	#include "aml_vpu_ctrl.h"

	/* v04: add txlx support */
	/* v05: add axg support */
	/* v06: add g12a support */
	/* v20180925: add tl1 support */
	/* v20190313: add sm1 support */
	#define VPU_VERION "v20190313"

	#ifdef CONFIG_OF_LIBFDT
	static char *dt_addr;
	#endif
	static int dts_ready = 0;

	struct vpu_conf_s vpu_conf = {
	.data = NULL,

	.clk_level = 0,
	.fclk_freq = FCLK_2000M,
	};

	static struct vpu_data_s vpu_data_gxb = {
	.chip_type = VPU_CHIP_GXBB,
	.chip_name = "gxbb",
	.clk_level_dft = CLK_LEVEL_DFT_GXBB,
	.clk_level_max = CLK_LEVEL_MAX_GXBB,
	.gp_pll_valid = 0,

	.fclk_div_table = fclk_div_table_gxb,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_gxb,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_gxb,
	.reset_table = vpu_reset_gx,

	.module_init_table_cnt = 0,
	.module_init_table = NULL,
	};

	static struct vpu_data_s vpu_data_gxtvbb = {
	.chip_type = VPU_CHIP_GXTVBB,
	.chip_name = "gxtvbb",
	.clk_level_dft = CLK_LEVEL_DFT_GXTVBB,
	.clk_level_max = CLK_LEVEL_MAX_GXTVBB,
	.gp_pll_valid = 1,

	.fclk_div_table = fclk_div_table_gxb,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_gxb,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_gxb,
	.reset_table = vpu_reset_gx,

	.module_init_table_cnt = 0,
	.module_init_table = NULL,
	};

	static struct vpu_data_s vpu_data_gxl = {
	.chip_type = VPU_CHIP_GXL,
	.chip_name = "gxl",
	.clk_level_dft = CLK_LEVEL_DFT_GXL,
	.clk_level_max = CLK_LEVEL_MAX_GXL,
	.gp_pll_valid = 0,

	.fclk_div_table = fclk_div_table_gxb,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_gxb,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_gxb,
	.reset_table = vpu_reset_gx,

	.module_init_table_cnt = 0,
	.module_init_table = NULL,
	};

	static struct vpu_data_s vpu_data_gxm = {
	.chip_type = VPU_CHIP_GXM,
	.chip_name = "gxm",
	.clk_level_dft = CLK_LEVEL_DFT_GXM,
	.clk_level_max = CLK_LEVEL_MAX_GXM,
	.gp_pll_valid = 0,

	.fclk_div_table = fclk_div_table_gxb,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_gxb,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_gxb,
	.reset_table = vpu_reset_gx,

	.module_init_table_cnt = sizeof(vpu_module_init_gxm) / sizeof(struct vpu_ctrl_s),
	.module_init_table = vpu_module_init_gxm,
	};

	static struct vpu_data_s vpu_data_txl = {
	.chip_type = VPU_CHIP_TXL,
	.chip_name = "txl",
	.clk_level_dft = CLK_LEVEL_DFT_TXLX,
	.clk_level_max = CLK_LEVEL_MAX_TXLX,
	.gp_pll_valid = 0,

	.fclk_div_table = fclk_div_table_gxb,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_gxb,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_gxb,
	.reset_table = vpu_reset_gx,

	.module_init_table_cnt = 0,
	.module_init_table = NULL,
	};

	static struct vpu_data_s vpu_data_txlx = {
	.chip_type = VPU_CHIP_TXLX,
	.chip_name = "txlx",
	.clk_level_dft = CLK_LEVEL_DFT_TXLX,
	.clk_level_max = CLK_LEVEL_MAX_TXLX,
	.gp_pll_valid = 0,

	.fclk_div_table = fclk_div_table_gxb,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_gxb,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_gxb,
	.reset_table = vpu_reset_gx,

	.module_init_table_cnt = sizeof(vpu_module_init_txlx) / sizeof(struct vpu_ctrl_s),
	.module_init_table = vpu_module_init_txlx,
	};

	static struct vpu_data_s vpu_data_axg = {
	.chip_type = VPU_CHIP_AXG,
	.chip_name = "axg",
	.clk_level_dft = CLK_LEVEL_DFT_AXG,
	.clk_level_max = CLK_LEVEL_MAX_AXG,
	.gp_pll_valid = 0,

	.fclk_div_table = fclk_div_table_gxb,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_axg,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_gxb,
	.reset_table = vpu_reset_gx,

	.module_init_table_cnt = 0,
	.module_init_table = NULL,
	};

	static struct vpu_data_s vpu_data_txhd = {
	.chip_type = VPU_CHIP_TXHD,
	.chip_name = "txhd",
	.clk_level_dft = CLK_LEVEL_DFT_TXHD,
	.clk_level_max = CLK_LEVEL_MAX_TXHD,
	.gp_pll_valid = 0,

	.fclk_div_table = fclk_div_table_gxb,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_txhd,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_gxb,
	.reset_table = vpu_reset_txhd,

	.module_init_table_cnt = 0,
	.module_init_table = NULL,
	};

	static struct vpu_data_s vpu_data_g12a = {
	.chip_type = VPU_CHIP_G12A,
	.chip_name = "g12a",
	.clk_level_dft = CLK_LEVEL_DFT_G12A,
	.clk_level_max = CLK_LEVEL_MAX_G12A,
	.gp_pll_valid = 0,

	.fclk_div_table = fclk_div_table_g12a,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_g12a,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_gxb,
	.reset_table = vpu_reset_gx,

	.module_init_table_cnt = sizeof(vpu_module_init_g12a) / sizeof(struct vpu_ctrl_s),
	.module_init_table = vpu_module_init_g12a,
	};

	static struct vpu_data_s vpu_data_g12b = {
	.chip_type = VPU_CHIP_G12B,
	.chip_name = "g12b",
	.clk_level_dft = CLK_LEVEL_DFT_G12A,
	.clk_level_max = CLK_LEVEL_MAX_G12A,
	.gp_pll_valid = 0,

	.fclk_div_table = fclk_div_table_g12a,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_g12b,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_gxb,
	.reset_table = vpu_reset_gx,

	.module_init_table_cnt = sizeof(vpu_module_init_g12a) / sizeof(struct vpu_ctrl_s),
	.module_init_table = vpu_module_init_g12a,
	};

	static struct vpu_data_s vpu_data_tl1 = {
	.chip_type = VPU_CHIP_TL1,
	.chip_name = "tl1",
	.clk_level_dft = CLK_LEVEL_DFT_G12A,
	.clk_level_max = CLK_LEVEL_MAX_G12A,
	.gp_pll_valid = 0,

	.fclk_div_table = fclk_div_table_g12a,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_tl1,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_gxb,
	.reset_table = vpu_reset_tl1,

	.module_init_table_cnt = 0,
	.module_init_table = NULL,
	};

	static struct vpu_data_s vpu_data_sm1 = {
	.chip_type = VPU_CHIP_SM1,
	.chip_name = "sm1",
	.clk_level_dft = CLK_LEVEL_DFT_G12A,
	.clk_level_max = CLK_LEVEL_MAX_G12A,
	.gp_pll_valid = 0,

	.fclk_div_table = fclk_div_table_g12a,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_tl1,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_sm1,
	.reset_table = vpu_reset_gx,

	.module_init_table_cnt = sizeof(vpu_module_init_g12a) / sizeof(struct vpu_ctrl_s),
	.module_init_table = vpu_module_init_g12a,

	};


	static struct vpu_data_s vpu_data_tm2 = {
	.chip_type = VPU_CHIP_TM2,
	.chip_name = "tm2",
	.clk_level_dft = CLK_LEVEL_DFT_G12A,
	.clk_level_max = CLK_LEVEL_MAX_G12A,
	.gp_pll_valid = 0,

	.fclk_div_table = fclk_div_table_g12a,
	.vpu_clk_table = vpu_clk_table,

	.mem_pd_table = vpu_mem_pd_tm2,
	.hdmi_iso_pre_table = vpu_hdmi_iso_pre_gxb,
	.hdmi_iso_table = vpu_hdmi_iso_sm1,
	.reset_table = vpu_reset_tl1,

	.module_init_table_cnt = sizeof(vpu_module_init_tm2) / sizeof(struct vpu_ctrl_s),
	.module_init_table = vpu_module_init_tm2,
	};

	static void vpu_chip_detect(void)
	{
	unsigned int cpu_type;

	cpu_type = get_cpu_id().family_id;
	switch (cpu_type) {
	case MESON_CPU_MAJOR_ID_GXBB:
	vpu_conf.data = &vpu_data_gxb;
	break;
	case MESON_CPU_MAJOR_ID_GXTVBB:
	vpu_conf.data = &vpu_data_gxtvbb;
	break;
	case MESON_CPU_MAJOR_ID_GXL:
	vpu_conf.data = &vpu_data_gxl;
	break;
	case MESON_CPU_MAJOR_ID_GXM:
	vpu_conf.data = &vpu_data_gxm;
	break;
	case MESON_CPU_MAJOR_ID_TXL:
	vpu_conf.data = &vpu_data_txl;
	break;
	case MESON_CPU_MAJOR_ID_TXLX:
	vpu_conf.data = &vpu_data_txlx;
	break;
	case MESON_CPU_MAJOR_ID_AXG:
	vpu_conf.data = &vpu_data_axg;
	break;
	case MESON_CPU_MAJOR_ID_TXHD:
	vpu_conf.data = &vpu_data_txhd;
	break;
	case MESON_CPU_MAJOR_ID_G12A:
	vpu_conf.data = &vpu_data_g12a;
	break;
	case MESON_CPU_MAJOR_ID_G12B:
	vpu_conf.data = &vpu_data_g12b;
	break;
	case MESON_CPU_MAJOR_ID_TL1:
	vpu_conf.data = &vpu_data_tl1;
	break;
	case MESON_CPU_MAJOR_ID_SM1:
	vpu_conf.data = &vpu_data_sm1;
	break;
	case MESON_CPU_MAJOR_ID_TM2:
	vpu_conf.data = &vpu_data_tm2;
	break;
	default:
	vpu_conf.data = NULL;
	break;
	}

	strcpy(vpu_conf.drv_version, VPU_VERION);

	if (vpu_conf.data == NULL) {
	VPUERR("invalid vpu\n");
	return ;
	} else {
	#ifdef CONFIG_VPU_CLK_LEVEL_DFT
	vpu_conf.data->clk_level_dft = CONFIG_VPU_CLK_LEVEL_DFT;
	#endif

	#ifdef VPU_DEBUG_PRINT
	VPUPR("driver version: %s\n", vpu_conf.drv_version);
	VPUPR("detect chip type: %d\n", vpu_conf.data->chip_type);
	VPUPR("clk_level default: %d(%dHz), max: %d(%dHz)\n",
	vpu_conf.data->clk_level_dft,
	(vpu_conf.data->vpu_clk_table + vpu_conf.data->clk_level_dft)->freq,
	(vpu_conf.data->clk_level_max - 1),
	(vpu_conf.data->vpu_clk_table + (vpu_conf.data->clk_level_max - 1))->freq);
	#endif
	}
	}

	static int vpu_check(void)
	{
	int ret = -1;

	if (vpu_conf.data == NULL) {
	VPUERR("invalid vpu\n");
	return -1;
	}

	switch (vpu_conf.data->chip_type) {
	case VPU_CHIP_GXBB:
	case VPU_CHIP_GXTVBB:
	case VPU_CHIP_GXL:
	case VPU_CHIP_GXM:
	case VPU_CHIP_TXL:
	case VPU_CHIP_TXLX:
	case VPU_CHIP_AXG:
	case VPU_CHIP_TXHD:
	case VPU_CHIP_G12A:
	case VPU_CHIP_G12B:
	case VPU_CHIP_TL1:
	case VPU_CHIP_SM1:
	case VPU_CHIP_TM2:
	ret = 0;
	break;
	default:
	VPUERR("invalid vpu for current chip\n");
	break;
	}

	return ret;
	}

	static unsigned int get_vpu_clk_level(unsigned int video_clk)
	{
	unsigned clk_level;
	int i;

	for (i = 0; i < vpu_conf.data->clk_level_max; i++) {
	if (video_clk <= (vpu_conf.data->vpu_clk_table + i)->freq)
	break;
	}
	clk_level = i;

	return clk_level;
	}

	static unsigned long get_fclk_div_freq(unsigned int mux_id)
	{
	struct fclk_div_s *fclk_div;
	unsigned long fclk, div, clk_source = 0;
	unsigned int i;

	fclk = vpu_conf.fclk_freq * 1000000;

	for (i = 0; i < FCLK_DIV_MAX; i++) {
	fclk_div = vpu_conf.data->fclk_div_table + i;
	if (fclk_div->fclk_id == mux_id) {
	div = fclk_div->fclk_div;
	clk_source = ((fclk * 100 / div) + 99) / 100;
	break;
	}
	if (fclk_div->fclk_id == FCLK_DIV_MAX)
	break;
	}

	return clk_source;
	}

	static unsigned int get_vpu_clk_mux_id(void)
	{
	struct fclk_div_s *fclk_div;
	unsigned int i, mux, mux_id;

	mux = vpu_hiu_getb(HHI_VPU_CLK_CNTL, 9, 3);
	mux_id = mux;
	for (i = 0; i < FCLK_DIV_MAX; i++) {
	fclk_div = vpu_conf.data->fclk_div_table + i;
	if (fclk_div->fclk_mux == mux) {
	mux_id = fclk_div->fclk_id;
	break;
	}
	if (fclk_div->fclk_id == FCLK_DIV_MAX)
	break;
	}

	return mux_id;
	}

	static unsigned int get_vpu_clk_mux(unsigned int mux_id)
	{
	struct fclk_div_s *fclk_div;
	unsigned int i, mux;

	mux = mux_id;
	for (i = 0; i < FCLK_DIV_MAX; i++) {
	fclk_div = vpu_conf.data->fclk_div_table + i;
	if (fclk_div->fclk_id == mux_id) {
	mux = fclk_div->fclk_mux;
	break;
	}
	if (fclk_div->fclk_id == FCLK_DIV_MAX)
	break;
	}

	return mux;
	}

	static unsigned int get_vpu_clk(void)
	{
	unsigned long clk_freq;
	unsigned long clk_source, div;
	unsigned int mux_id;

	mux_id = get_vpu_clk_mux_id();
	switch (mux_id) {
	case FCLK_DIV4:
	case FCLK_DIV3:
	case FCLK_DIV5:
	case FCLK_DIV7:
	clk_source = get_fclk_div_freq(mux_id);
	break;
	case GPLL_CLK:
	clk_source = (vpu_conf.data->vpu_clk_table + 8)->freq;
	break;
	default:
	clk_source = 0;
	break;
	}

	div = vpu_hiu_getb(HHI_VPU_CLK_CNTL, 0, 7) + 1;
	clk_freq = ((clk_source * 100 / div) + 99) / 100;

	return (unsigned int)clk_freq;
	}

	static int switch_gp1_pll_gxtvbb(int flag)
	{
	int cnt = 100;
	int ret = 0;

	if (flag) { /* enable gp1_pll */
	/* GP1 DPLL 696MHz output*/
	vpu_hiu_write(HHI_GP1_PLL_CNTL2, 0x69c80000);
	vpu_hiu_write(HHI_GP1_PLL_CNTL3, 0x0a5590c4);
	vpu_hiu_write(HHI_GP1_PLL_CNTL4, 0x0000500d);
	vpu_hiu_write(HHI_GP1_PLL_CNTL, 0x6a01023a);
	vpu_hiu_write(HHI_GP1_PLL_CNTL, 0x4a01023a);
	do {
	udelay(10);
	vpu_hiu_setb(HHI_GP1_PLL_CNTL, 1, 29, 1); /* reset */
	udelay(50);
	/* release reset */
	vpu_hiu_setb(HHI_GP1_PLL_CNTL, 0, 29, 1);
	udelay(50);
	cnt--;
	if (cnt == 0)
	break;
	} while (vpu_hiu_getb(HHI_GP1_PLL_CNTL, 31, 1) == 0);
	if (vpu_hiu_getb(HHI_GP1_PLL_CNTL, 31, 1) == 0) {
	ret = -1;
	vpu_hiu_setb(HHI_GP1_PLL_CNTL, 0, 30, 1);
	VPUERR("GP1_PLL lock failed\n");
	}
	} else { /* disable gp1_pll */
	vpu_hiu_setb(HHI_GP1_PLL_CNTL, 0, 30, 1);
	}

	return ret;
	}

	static int switch_gp_pll(int flag)
	{
	int ret = -1;

	if (vpu_conf.data->gp_pll_valid == 0)
	return ret;

	switch (vpu_conf.data->chip_type) {
	case VPU_CHIP_GXTVBB:
	ret = switch_gp1_pll_gxtvbb(flag);
	break;
	default:
	break;
	}

	return ret;
	}

	/* unit: MHz */
	#define VPU_CLKB_MAX 350
	static int adjust_vpu_clk(unsigned int clk_level)
	{
	struct vpu_clk_s *clk_table;
	unsigned int vpu_clk;
	unsigned int mux, div;
	int ret = 0;

	/* vpu clk */
	clk_table = vpu_conf.data->vpu_clk_table + clk_level;
	mux = get_vpu_clk_mux(clk_table->mux);
	if (mux == GPLL_CLK) {
	ret = switch_gp_pll(1);
	if (ret) {
	clk_level = vpu_conf.data->clk_level_dft;
	VPUERR("adjust_vpu_clk: gp pll error, use default clk\n");
	}
	}
	vpu_conf.clk_level = clk_level;
	clk_table = vpu_conf.data->vpu_clk_table + clk_level;

	vpu_clk = clk_table->freq;
	mux = get_vpu_clk_mux(clk_table->mux);
	div = clk_table->div;

	vpu_hiu_write(HHI_VPU_CLK_CNTL, ((mux << 9) \| (div << 0)));
	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 1, 8, 1);

	/* vpu clkb if needed */
	switch (vpu_conf.data->chip_type) {
	case VPU_CHIP_GXBB:
	case VPU_CHIP_GXTVBB:
	case VPU_CHIP_GXL:
	case VPU_CHIP_GXM:
	case VPU_CHIP_TXL:
	if (vpu_clk >= (VPU_CLKB_MAX * 1000000))
	vpu_hiu_write(HHI_VPU_CLKB_CNTL, ((1 << 8) \| (1 << 0)));
	else
	vpu_hiu_write(HHI_VPU_CLKB_CNTL, ((1 << 8) \| (0 << 0)));
	break;
	default:
	break;
	}

	/* vapb clk */
	if (vpu_clk >= 250000000) {
	vpu_hiu_write(HHI_VAPBCLK_CNTL, (1 << 30) \| /* turn on ge2d clock */
	(0 << 9) \| /* clk_sel //250Mhz */
	(1 << 0)); /* clk_div */
	} else {
	vpu_hiu_write(HHI_VAPBCLK_CNTL, (1 << 30) \| /* turn on ge2d clock */
	(clk_table->mux << 9) \| /* clk_sel */
	(div << 0)); /* clk_div */
	}
	vpu_hiu_setb(HHI_VAPBCLK_CNTL, 1, 8, 1);

	VPUPR("set clk: %uHz, readback: %uHz(0x%x)\n",
	vpu_clk, get_vpu_clk(), (vpu_hiu_read(HHI_VPU_CLK_CNTL)));
	return ret;
	}

	static int set_vpu_clk(unsigned int vclk)
	{
	int ret = 0;
	unsigned int clk_level;

	#ifdef VPU_DEBUG_PRINT
	VPUPR("%s\n", __func__);
	#endif

	if (vclk >= 100) /* regard as vpu_clk */
	clk_level = get_vpu_clk_level(vclk);
	else /* regard as clk_level */
	clk_level = vclk;

	if (clk_level >= vpu_conf.data->clk_level_max) {
	clk_level = vpu_conf.data->clk_level_dft;
	VPUPR("clk out of supported range, set to default\n");
	}

	ret = adjust_vpu_clk(clk_level);

	#ifdef VPU_DEBUG_PRINT
	VPUPR("%s finish\n", __func__);
	#endif

	return ret;
	}

	static int get_vpu_config(void)
	{
	#ifdef CONFIG_OF_LIBFDT
	int nodeoffset;
	char *propdata;
	#endif

	if (dts_ready == 1) {
	#ifdef CONFIG_OF_LIBFDT
	nodeoffset = fdt_path_offset(dt_addr, "/vpu");
	if (nodeoffset < 0) {
	VPUERR("not find /vpu node in dts %s\n", fdt_strerror(nodeoffset));
	return -1;
	}

	propdata = (char *)fdt_getprop(dt_addr, nodeoffset, "clk_level", NULL);
	if (propdata == NULL) {
	vpu_conf.clk_level = vpu_conf.data->clk_level_dft;
	VPUERR("don't find clk_level in dts, set to default\n");
	} else {
	vpu_conf.clk_level = (unsigned short)(be32_to_cpup((u32*)propdata));
	if (vpu_conf.clk_level >= vpu_conf.data->clk_level_max) {
	VPUERR("clk_level in dts is out of support, set to default\n");
	vpu_conf.clk_level = vpu_conf.data->clk_level_dft;
	}
	}
	VPUPR("clk_level in dts: %u\n", vpu_conf.clk_level);
	#endif
	} else {
	vpu_conf.clk_level = vpu_conf.data->clk_level_dft;
	VPUPR("clk_level = %u\n", vpu_conf.clk_level);
	}

	return 0;
	}

	int vpu_probe(void)
	{
	int ret;

	dts_ready = 0;
	#ifdef CONFIG_OF_LIBFDT
	#ifdef CONFIG_DTB_MEM_ADDR
	dt_addr = (char *)CONFIG_DTB_MEM_ADDR;
	#else
	dt_addr = (char *)0x01000000;
	#endif
	ret = fdt_check_header((const void *)dt_addr);
	if (ret < 0) {
	VPUERR("vpu: check dts: %s, load default parameters\n",
	fdt_strerror(ret));
	} else {
	dts_ready = 1;
	}
	#endif

	vpu_chip_detect();
	if (vpu_check())
	return -1;

	ret = get_vpu_config();
	vpu_power_on();
	set_vpu_clk(vpu_conf.clk_level);
	//vpu_power_on();

	/* vpu module init off, for power save, and special module init */
	vpu_mem_pd_init_off();
	vpu_module_init_config();

	return ret;
	}

	int vpu_remove(void)
	{
	if (vpu_check())
	return -1;

	VPUPR("vpu remove\n");
	vpu_power_off();
	return 0;
	}

	static void vpu_clk_switch(void)
	{
	struct vpu_clk_s *clk_table;
	unsigned int mux, div;

	/* step 1: switch to 2nd vpu clk patch */
	clk_table = vpu_conf.data->vpu_clk_table + vpu_conf.data->clk_level_dft;
	mux = get_vpu_clk_mux(clk_table->mux);
	vpu_hiu_setb(HHI_VPU_CLK_CNTL, mux, 25, 3);
	div = clk_table->div;
	vpu_hiu_setb(HHI_VPU_CLK_CNTL, div, 16, 7);
	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 1, 24, 1);
	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 1, 31, 1);
	udelay(10);
	/* step 2: adjust 1st vpu clk frequency */
	clk_table = vpu_conf.data->vpu_clk_table + vpu_conf.clk_level;
	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 0, 8, 1);
	mux = get_vpu_clk_mux(clk_table->mux);
	vpu_hiu_setb(HHI_VPU_CLK_CNTL, mux, 9, 3);
	div = clk_table->div;
	vpu_hiu_setb(HHI_VPU_CLK_CNTL, div, 0, 7);
	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 1, 8, 1);
	udelay(20);
	/* step 3: switch back to 1st vpu clk patch */
	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 0, 31, 1);
	vpu_hiu_setb(HHI_VPU_CLK_CNTL, 0, 24, 1);
	}

	int vpu_clk_change(int level)
	{
	struct vpu_clk_s *clk_table;
	unsigned int vpu_clk;

	if (vpu_check())
	return -1;

	if (level >= 100) /* regard as vpu_clk */
	level = get_vpu_clk_level(level);

	if (level >= vpu_conf.data->clk_level_max) {
	clk_table = vpu_conf.data->vpu_clk_table + (vpu_conf.data->clk_level_max - 1);
	VPUPR("clk out of supported range\n");
	VPUPR("clk max level: %u(%uHz)\n",
	(vpu_conf.data->clk_level_max - 1),
	clk_table->freq);
	return -1;
	}

	vpu_conf.clk_level = level;
	clk_table = vpu_conf.data->vpu_clk_table + vpu_conf.clk_level;
	vpu_clk = clk_table->freq;

	vpu_clk_switch();

	VPUPR("set clk: %uHz, readback: %uHz(0x%x)\n",
	vpu_clk, get_vpu_clk(), vpu_hiu_read(HHI_VPU_CLK_CNTL));
	return 0;
	}

	void vpu_clk_get(void)
	{
	if (vpu_check())
	return;

	VPUPR("clk_level: %u, clk: %uHz, reg: 0x%x\n",
	vpu_conf.clk_level, get_vpu_clk(),
	vpu_hiu_read(HHI_VPU_CLK_CNTL));
	}

	void vpu_info_print(void)
	{
	if (vpu_check())
	return;

	printf("vpu driver version: %s\n", vpu_conf.drv_version);
	printf("detect chip type: %d(%s)\n",
	vpu_conf.data->chip_type,
	vpu_conf.data->chip_name);
	printf("clk_level: %d(%dHz)\n"
	"clk_level default: %d(%dHz)\n"
	"clk_level max: %d(%dHz)\n",
	vpu_conf.clk_level,
	(vpu_conf.data->vpu_clk_table + vpu_conf.clk_level)->freq,
	vpu_conf.data->clk_level_dft,
	(vpu_conf.data->vpu_clk_table + vpu_conf.data->clk_level_dft)->freq,
	(vpu_conf.data->clk_level_max - 1),
	(vpu_conf.data->vpu_clk_table + (vpu_conf.data->clk_level_max - 1))->freq);
	}

	static unsigned int vcbus_reg[] = {
	0x1b7f, /* VENC_VDAC_TST_VAL */
	0x1c30, /* ENCP_DVI_HSO_BEGIN */
	0x1d00, /* VPP_DUMMY_DATA */
	0x2730, /* VPU_VPU_PWM_V0 */
	};

	void vcbus_test(void)
	{
	unsigned int val;
	unsigned int temp;
	int i,j;

	if (vpu_check())
	return;

	VPUPR("vcbus test:\n");
	for (i = 0; i < ARRAY_SIZE(vcbus_reg); i++) {
	for (j = 0; j < 24; j++) {
	val = vpu_vcbus_read(vcbus_reg[i]);
	printf("%02d read 0x%04x=0x%08x\n", j, vcbus_reg[i], val);
	}
	printf("\n");
	}
	temp = 0x5a5a5a5a;
	for (i = 0; i < ARRAY_SIZE(vcbus_reg); i++) {
	vpu_vcbus_write(vcbus_reg[i], temp);
	val = vpu_vcbus_read(vcbus_reg[i]);
	printf("write 0x%04x=0x%08x, readback: 0x%08x\n", vcbus_reg[i], temp, val);
	}
	for (i = 0; i < ARRAY_SIZE(vcbus_reg); i++) {
	for (j = 0; j < 24; j++) {
	val = vpu_vcbus_read(vcbus_reg[i]);
	printf("%02d read 0x%04x=0x%08x\n", j, vcbus_reg[i], val);
	}
	printf("\n");
	}
	}