// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (C) 2009 Nokia Corporation * Author: Tomi Valkeinen * * VENC settings from TI's DSS driver */ #define DSS_SUBSYS_NAME "VENC" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "omapdss.h" #include "dss.h" /* Venc registers */ #define VENC_REV_ID 0x00 #define VENC_STATUS 0x04 #define VENC_F_CONTROL 0x08 #define VENC_VIDOUT_CTRL 0x10 #define VENC_SYNC_CTRL 0x14 #define VENC_LLEN 0x1C #define VENC_FLENS 0x20 #define VENC_HFLTR_CTRL 0x24 #define VENC_CC_CARR_WSS_CARR 0x28 #define VENC_C_PHASE 0x2C #define VENC_GAIN_U 0x30 #define VENC_GAIN_V 0x34 #define VENC_GAIN_Y 0x38 #define VENC_BLACK_LEVEL 0x3C #define VENC_BLANK_LEVEL 0x40 #define VENC_X_COLOR 0x44 #define VENC_M_CONTROL 0x48 #define VENC_BSTAMP_WSS_DATA 0x4C #define VENC_S_CARR 0x50 #define VENC_LINE21 0x54 #define VENC_LN_SEL 0x58 #define VENC_L21__WC_CTL 0x5C #define VENC_HTRIGGER_VTRIGGER 0x60 #define VENC_SAVID__EAVID 0x64 #define VENC_FLEN__FAL 0x68 #define VENC_LAL__PHASE_RESET 0x6C #define VENC_HS_INT_START_STOP_X 0x70 #define VENC_HS_EXT_START_STOP_X 0x74 #define VENC_VS_INT_START_X 0x78 #define VENC_VS_INT_STOP_X__VS_INT_START_Y 0x7C #define VENC_VS_INT_STOP_Y__VS_EXT_START_X 0x80 #define VENC_VS_EXT_STOP_X__VS_EXT_START_Y 0x84 #define VENC_VS_EXT_STOP_Y 0x88 #define VENC_AVID_START_STOP_X 0x90 #define VENC_AVID_START_STOP_Y 0x94 #define VENC_FID_INT_START_X__FID_INT_START_Y 0xA0 #define VENC_FID_INT_OFFSET_Y__FID_EXT_START_X 0xA4 #define VENC_FID_EXT_START_Y__FID_EXT_OFFSET_Y 0xA8 #define VENC_TVDETGP_INT_START_STOP_X 0xB0 #define VENC_TVDETGP_INT_START_STOP_Y 0xB4 #define VENC_GEN_CTRL 0xB8 #define VENC_OUTPUT_CONTROL 0xC4 #define VENC_OUTPUT_TEST 0xC8 #define VENC_DAC_B__DAC_C 0xC8 struct venc_config { u32 f_control; u32 vidout_ctrl; u32 sync_ctrl; u32 llen; u32 flens; u32 hfltr_ctrl; u32 cc_carr_wss_carr; u32 c_phase; u32 gain_u; u32 gain_v; u32 gain_y; u32 black_level; u32 blank_level; u32 x_color; u32 m_control; u32 bstamp_wss_data; u32 s_carr; u32 line21; u32 ln_sel; u32 l21__wc_ctl; u32 htrigger_vtrigger; u32 savid__eavid; u32 flen__fal; u32 lal__phase_reset; u32 hs_int_start_stop_x; u32 hs_ext_start_stop_x; u32 vs_int_start_x; u32 vs_int_stop_x__vs_int_start_y; u32 vs_int_stop_y__vs_ext_start_x; u32 vs_ext_stop_x__vs_ext_start_y; u32 vs_ext_stop_y; u32 avid_start_stop_x; u32 avid_start_stop_y; u32 fid_int_start_x__fid_int_start_y; u32 fid_int_offset_y__fid_ext_start_x; u32 fid_ext_start_y__fid_ext_offset_y; u32 tvdetgp_int_start_stop_x; u32 tvdetgp_int_start_stop_y; u32 gen_ctrl; }; /* from TRM */ static const struct venc_config venc_config_pal_trm = { .f_control = 0, .vidout_ctrl = 1, .sync_ctrl = 0x40, .llen = 0x35F, /* 863 */ .flens = 0x270, /* 624 */ .hfltr_ctrl = 0, .cc_carr_wss_carr = 0x2F7225ED, .c_phase = 0, .gain_u = 0x111, .gain_v = 0x181, .gain_y = 0x140, .black_level = 0x3B, .blank_level = 0x3B, .x_color = 0x7, .m_control = 0x2, .bstamp_wss_data = 0x3F, .s_carr = 0x2A098ACB, .line21 = 0, .ln_sel = 0x01290015, .l21__wc_ctl = 0x0000F603, .htrigger_vtrigger = 0, .savid__eavid = 0x06A70108, .flen__fal = 0x00180270, .lal__phase_reset = 0x00040135, .hs_int_start_stop_x = 0x00880358, .hs_ext_start_stop_x = 0x000F035F, .vs_int_start_x = 0x01A70000, .vs_int_stop_x__vs_int_start_y = 0x000001A7, .vs_int_stop_y__vs_ext_start_x = 0x01AF0000, .vs_ext_stop_x__vs_ext_start_y = 0x000101AF, .vs_ext_stop_y = 0x00000025, .avid_start_stop_x = 0x03530083, .avid_start_stop_y = 0x026C002E, .fid_int_start_x__fid_int_start_y = 0x0001008A, .fid_int_offset_y__fid_ext_start_x = 0x002E0138, .fid_ext_start_y__fid_ext_offset_y = 0x01380001, .tvdetgp_int_start_stop_x = 0x00140001, .tvdetgp_int_start_stop_y = 0x00010001, .gen_ctrl = 0x00FF0000, }; /* from TRM */ static const struct venc_config venc_config_ntsc_trm = { .f_control = 0, .vidout_ctrl = 1, .sync_ctrl = 0x8040, .llen = 0x359, .flens = 0x20C, .hfltr_ctrl = 0, .cc_carr_wss_carr = 0x043F2631, .c_phase = 0, .gain_u = 0x102, .gain_v = 0x16C, .gain_y = 0x12F, .black_level = 0x43, .blank_level = 0x38, .x_color = 0x7, .m_control = 0x1, .bstamp_wss_data = 0x38, .s_carr = 0x21F07C1F, .line21 = 0, .ln_sel = 0x01310011, .l21__wc_ctl = 0x0000F003, .htrigger_vtrigger = 0, .savid__eavid = 0x069300F4, .flen__fal = 0x0016020C, .lal__phase_reset = 0x00060107, .hs_int_start_stop_x = 0x008E0350, .hs_ext_start_stop_x = 0x000F0359, .vs_int_start_x = 0x01A00000, .vs_int_stop_x__vs_int_start_y = 0x020701A0, .vs_int_stop_y__vs_ext_start_x = 0x01AC0024, .vs_ext_stop_x__vs_ext_start_y = 0x020D01AC, .vs_ext_stop_y = 0x00000006, .avid_start_stop_x = 0x03480078, .avid_start_stop_y = 0x02060024, .fid_int_start_x__fid_int_start_y = 0x0001008A, .fid_int_offset_y__fid_ext_start_x = 0x01AC0106, .fid_ext_start_y__fid_ext_offset_y = 0x01060006, .tvdetgp_int_start_stop_x = 0x00140001, .tvdetgp_int_start_stop_y = 0x00010001, .gen_ctrl = 0x00F90000, }; enum venc_videomode { VENC_MODE_UNKNOWN, VENC_MODE_PAL, VENC_MODE_NTSC, }; static const struct drm_display_mode omap_dss_pal_mode = { .hdisplay = 720, .hsync_start = 732, .hsync_end = 796, .htotal = 864, .vdisplay = 574, .vsync_start = 579, .vsync_end = 584, .vtotal = 625, .clock = 13500, .flags = DRM_MODE_FLAG_INTERLACE | DRM_MODE_FLAG_NHSYNC | DRM_MODE_FLAG_NVSYNC, }; static const struct drm_display_mode omap_dss_ntsc_mode = { .hdisplay = 720, .hsync_start = 736, .hsync_end = 800, .htotal = 858, .vdisplay = 482, .vsync_start = 488, .vsync_end = 494, .vtotal = 525, .clock = 13500, .flags = DRM_MODE_FLAG_INTERLACE | DRM_MODE_FLAG_NHSYNC | DRM_MODE_FLAG_NVSYNC, }; struct venc_device { struct platform_device *pdev; void __iomem *base; struct regulator *vdda_dac_reg; struct dss_device *dss; struct dss_debugfs_entry *debugfs; struct clk *tv_dac_clk; const struct venc_config *config; enum omap_dss_venc_type type; bool invert_polarity; bool requires_tv_dac_clk; struct omap_dss_device output; struct drm_bridge bridge; }; #define drm_bridge_to_venc(b) container_of(b, struct venc_device, bridge) static inline void venc_write_reg(struct venc_device *venc, int idx, u32 val) { __raw_writel(val, venc->base + idx); } static inline u32 venc_read_reg(struct venc_device *venc, int idx) { u32 l = __raw_readl(venc->base + idx); return l; } static void venc_write_config(struct venc_device *venc, const struct venc_config *config) { DSSDBG("write venc conf\n"); venc_write_reg(venc, VENC_LLEN, config->llen); venc_write_reg(venc, VENC_FLENS, config->flens); venc_write_reg(venc, VENC_CC_CARR_WSS_CARR, config->cc_carr_wss_carr); venc_write_reg(venc, VENC_C_PHASE, config->c_phase); venc_write_reg(venc, VENC_GAIN_U, config->gain_u); venc_write_reg(venc, VENC_GAIN_V, config->gain_v); venc_write_reg(venc, VENC_GAIN_Y, config->gain_y); venc_write_reg(venc, VENC_BLACK_LEVEL, config->black_level); venc_write_reg(venc, VENC_BLANK_LEVEL, config->blank_level); venc_write_reg(venc, VENC_M_CONTROL, config->m_control); venc_write_reg(venc, VENC_BSTAMP_WSS_DATA, config->bstamp_wss_data); venc_write_reg(venc, VENC_S_CARR, config->s_carr); venc_write_reg(venc, VENC_L21__WC_CTL, config->l21__wc_ctl); venc_write_reg(venc, VENC_SAVID__EAVID, config->savid__eavid); venc_write_reg(venc, VENC_FLEN__FAL, config->flen__fal); venc_write_reg(venc, VENC_LAL__PHASE_RESET, config->lal__phase_reset); venc_write_reg(venc, VENC_HS_INT_START_STOP_X, config->hs_int_start_stop_x); venc_write_reg(venc, VENC_HS_EXT_START_STOP_X, config->hs_ext_start_stop_x); venc_write_reg(venc, VENC_VS_INT_START_X, config->vs_int_start_x); venc_write_reg(venc, VENC_VS_INT_STOP_X__VS_INT_START_Y, config->vs_int_stop_x__vs_int_start_y); venc_write_reg(venc, VENC_VS_INT_STOP_Y__VS_EXT_START_X, config->vs_int_stop_y__vs_ext_start_x); venc_write_reg(venc, VENC_VS_EXT_STOP_X__VS_EXT_START_Y, config->vs_ext_stop_x__vs_ext_start_y); venc_write_reg(venc, VENC_VS_EXT_STOP_Y, config->vs_ext_stop_y); venc_write_reg(venc, VENC_AVID_START_STOP_X, config->avid_start_stop_x); venc_write_reg(venc, VENC_AVID_START_STOP_Y, config->avid_start_stop_y); venc_write_reg(venc, VENC_FID_INT_START_X__FID_INT_START_Y, config->fid_int_start_x__fid_int_start_y); venc_write_reg(venc, VENC_FID_INT_OFFSET_Y__FID_EXT_START_X, config->fid_int_offset_y__fid_ext_start_x); venc_write_reg(venc, VENC_FID_EXT_START_Y__FID_EXT_OFFSET_Y, config->fid_ext_start_y__fid_ext_offset_y); venc_write_reg(venc, VENC_DAC_B__DAC_C, venc_read_reg(venc, VENC_DAC_B__DAC_C)); venc_write_reg(venc, VENC_VIDOUT_CTRL, config->vidout_ctrl); venc_write_reg(venc, VENC_HFLTR_CTRL, config->hfltr_ctrl); venc_write_reg(venc, VENC_X_COLOR, config->x_color); venc_write_reg(venc, VENC_LINE21, config->line21); venc_write_reg(venc, VENC_LN_SEL, config->ln_sel); venc_write_reg(venc, VENC_HTRIGGER_VTRIGGER, config->htrigger_vtrigger); venc_write_reg(venc, VENC_TVDETGP_INT_START_STOP_X, config->tvdetgp_int_start_stop_x); venc_write_reg(venc, VENC_TVDETGP_INT_START_STOP_Y, config->tvdetgp_int_start_stop_y); venc_write_reg(venc, VENC_GEN_CTRL, config->gen_ctrl); venc_write_reg(venc, VENC_F_CONTROL, config->f_control); venc_write_reg(venc, VENC_SYNC_CTRL, config->sync_ctrl); } static void venc_reset(struct venc_device *venc) { int t = 1000; venc_write_reg(venc, VENC_F_CONTROL, 1<<8); while (venc_read_reg(venc, VENC_F_CONTROL) & (1<<8)) { if (--t == 0) { DSSERR("Failed to reset venc\n"); return; } } #ifdef CONFIG_OMAP2_DSS_SLEEP_AFTER_VENC_RESET /* the magical sleep that makes things work */ /* XXX more info? What bug this circumvents? */ msleep(20); #endif } static int venc_runtime_get(struct venc_device *venc) { int r; DSSDBG("venc_runtime_get\n"); r = pm_runtime_get_sync(&venc->pdev->dev); if (WARN_ON(r < 0)) { pm_runtime_put_noidle(&venc->pdev->dev); return r; } return 0; } static void venc_runtime_put(struct venc_device *venc) { int r; DSSDBG("venc_runtime_put\n"); r = pm_runtime_put_sync(&venc->pdev->dev); WARN_ON(r < 0 && r != -ENOSYS); } static int venc_power_on(struct venc_device *venc) { u32 l; int r; r = venc_runtime_get(venc); if (r) goto err0; venc_reset(venc); venc_write_config(venc, venc->config); dss_set_venc_output(venc->dss, venc->type); dss_set_dac_pwrdn_bgz(venc->dss, 1); l = 0; if (venc->type == OMAP_DSS_VENC_TYPE_COMPOSITE) l |= 1 << 1; else /* S-Video */ l |= (1 << 0) | (1 << 2); if (venc->invert_polarity == false) l |= 1 << 3; venc_write_reg(venc, VENC_OUTPUT_CONTROL, l); r = regulator_enable(venc->vdda_dac_reg); if (r) goto err1; r = dss_mgr_enable(&venc->output); if (r) goto err2; return 0; err2: regulator_disable(venc->vdda_dac_reg); err1: venc_write_reg(venc, VENC_OUTPUT_CONTROL, 0); dss_set_dac_pwrdn_bgz(venc->dss, 0); venc_runtime_put(venc); err0: return r; } static void venc_power_off(struct venc_device *venc) { venc_write_reg(venc, VENC_OUTPUT_CONTROL, 0); dss_set_dac_pwrdn_bgz(venc->dss, 0); dss_mgr_disable(&venc->output); regulator_disable(venc->vdda_dac_reg); venc_runtime_put(venc); } static enum venc_videomode venc_get_videomode(const struct drm_display_mode *mode) { if (!(mode->flags & DRM_MODE_FLAG_INTERLACE)) return VENC_MODE_UNKNOWN; if (mode->clock == omap_dss_pal_mode.clock && mode->hdisplay == omap_dss_pal_mode.hdisplay && mode->vdisplay == omap_dss_pal_mode.vdisplay) return VENC_MODE_PAL; if (mode->clock == omap_dss_ntsc_mode.clock && mode->hdisplay == omap_dss_ntsc_mode.hdisplay && mode->vdisplay == omap_dss_ntsc_mode.vdisplay) return VENC_MODE_NTSC; return VENC_MODE_UNKNOWN; } static int venc_dump_regs(struct seq_file *s, void *p) { struct venc_device *venc = s->private; #define DUMPREG(venc, r) \ seq_printf(s, "%-35s %08x\n", #r, venc_read_reg(venc, r)) if (venc_runtime_get(venc)) return 0; DUMPREG(venc, VENC_F_CONTROL); DUMPREG(venc, VENC_VIDOUT_CTRL); DUMPREG(venc, VENC_SYNC_CTRL); DUMPREG(venc, VENC_LLEN); DUMPREG(venc, VENC_FLENS); DUMPREG(venc, VENC_HFLTR_CTRL); DUMPREG(venc, VENC_CC_CARR_WSS_CARR); DUMPREG(venc, VENC_C_PHASE); DUMPREG(venc, VENC_GAIN_U); DUMPREG(venc, VENC_GAIN_V); DUMPREG(venc, VENC_GAIN_Y); DUMPREG(venc, VENC_BLACK_LEVEL); DUMPREG(venc, VENC_BLANK_LEVEL); DUMPREG(venc, VENC_X_COLOR); DUMPREG(venc, VENC_M_CONTROL); DUMPREG(venc, VENC_BSTAMP_WSS_DATA); DUMPREG(venc, VENC_S_CARR); DUMPREG(venc, VENC_LINE21); DUMPREG(venc, VENC_LN_SEL); DUMPREG(venc, VENC_L21__WC_CTL); DUMPREG(venc, VENC_HTRIGGER_VTRIGGER); DUMPREG(venc, VENC_SAVID__EAVID); DUMPREG(venc, VENC_FLEN__FAL); DUMPREG(venc, VENC_LAL__PHASE_RESET); DUMPREG(venc, VENC_HS_INT_START_STOP_X); DUMPREG(venc, VENC_HS_EXT_START_STOP_X); DUMPREG(venc, VENC_VS_INT_START_X); DUMPREG(venc, VENC_VS_INT_STOP_X__VS_INT_START_Y); DUMPREG(venc, VENC_VS_INT_STOP_Y__VS_EXT_START_X); DUMPREG(venc, VENC_VS_EXT_STOP_X__VS_EXT_START_Y); DUMPREG(venc, VENC_VS_EXT_STOP_Y); DUMPREG(venc, VENC_AVID_START_STOP_X); DUMPREG(venc, VENC_AVID_START_STOP_Y); DUMPREG(venc, VENC_FID_INT_START_X__FID_INT_START_Y); DUMPREG(venc, VENC_FID_INT_OFFSET_Y__FID_EXT_START_X); DUMPREG(venc, VENC_FID_EXT_START_Y__FID_EXT_OFFSET_Y); DUMPREG(venc, VENC_TVDETGP_INT_START_STOP_X); DUMPREG(venc, VENC_TVDETGP_INT_START_STOP_Y); DUMPREG(venc, VENC_GEN_CTRL); DUMPREG(venc, VENC_OUTPUT_CONTROL); DUMPREG(venc, VENC_OUTPUT_TEST); venc_runtime_put(venc); #undef DUMPREG return 0; } static int venc_get_clocks(struct venc_device *venc) { struct clk *clk; if (venc->requires_tv_dac_clk) { clk = devm_clk_get(&venc->pdev->dev, "tv_dac_clk"); if (IS_ERR(clk)) { DSSERR("can't get tv_dac_clk\n"); return PTR_ERR(clk); } } else { clk = NULL; } venc->tv_dac_clk = clk; return 0; } /* ----------------------------------------------------------------------------- * DRM Bridge Operations */ static int venc_bridge_attach(struct drm_bridge *bridge, enum drm_bridge_attach_flags flags) { struct venc_device *venc = drm_bridge_to_venc(bridge); if (!(flags & DRM_BRIDGE_ATTACH_NO_CONNECTOR)) return -EINVAL; return drm_bridge_attach(bridge->encoder, venc->output.next_bridge, bridge, flags); } static enum drm_mode_status venc_bridge_mode_valid(struct drm_bridge *bridge, const struct drm_display_info *info, const struct drm_display_mode *mode) { switch (venc_get_videomode(mode)) { case VENC_MODE_PAL: case VENC_MODE_NTSC: return MODE_OK; default: return MODE_BAD; } } static bool venc_bridge_mode_fixup(struct drm_bridge *bridge, const struct drm_display_mode *mode, struct drm_display_mode *adjusted_mode) { const struct drm_display_mode *venc_mode; switch (venc_get_videomode(adjusted_mode)) { case VENC_MODE_PAL: venc_mode = &omap_dss_pal_mode; break; case VENC_MODE_NTSC: venc_mode = &omap_dss_ntsc_mode; break; default: return false; } drm_mode_copy(adjusted_mode, venc_mode); drm_mode_set_crtcinfo(adjusted_mode, CRTC_INTERLACE_HALVE_V); drm_mode_set_name(adjusted_mode); return true; } static void venc_bridge_mode_set(struct drm_bridge *bridge, const struct drm_display_mode *mode, const struct drm_display_mode *adjusted_mode) { struct venc_device *venc = drm_bridge_to_venc(bridge); enum venc_videomode venc_mode = venc_get_videomode(adjusted_mode); switch (venc_mode) { default: WARN_ON_ONCE(1); fallthrough; case VENC_MODE_PAL: venc->config = &venc_config_pal_trm; break; case VENC_MODE_NTSC: venc->config = &venc_config_ntsc_trm; break; } dispc_set_tv_pclk(venc->dss->dispc, 13500000); } static void venc_bridge_enable(struct drm_bridge *bridge) { struct venc_device *venc = drm_bridge_to_venc(bridge); venc_power_on(venc); } static void venc_bridge_disable(struct drm_bridge *bridge) { struct venc_device *venc = drm_bridge_to_venc(bridge); venc_power_off(venc); } static int venc_bridge_get_modes(struct drm_bridge *bridge, struct drm_connector *connector) { static const struct drm_display_mode *modes[] = { &omap_dss_pal_mode, &omap_dss_ntsc_mode, }; unsigned int i; for (i = 0; i < ARRAY_SIZE(modes); ++i) { struct drm_display_mode *mode; mode = drm_mode_duplicate(connector->dev, modes[i]); if (!mode) return i; mode->type = DRM_MODE_TYPE_DRIVER | DRM_MODE_TYPE_PREFERRED; drm_mode_set_name(mode); drm_mode_probed_add(connector, mode); } return ARRAY_SIZE(modes); } static const struct drm_bridge_funcs venc_bridge_funcs = { .attach = venc_bridge_attach, .mode_valid = venc_bridge_mode_valid, .mode_fixup = venc_bridge_mode_fixup, .mode_set = venc_bridge_mode_set, .enable = venc_bridge_enable, .disable = venc_bridge_disable, .get_modes = venc_bridge_get_modes, }; static void venc_bridge_init(struct venc_device *venc) { venc->bridge.funcs = &venc_bridge_funcs; venc->bridge.of_node = venc->pdev->dev.of_node; venc->bridge.ops = DRM_BRIDGE_OP_MODES; venc->bridge.type = DRM_MODE_CONNECTOR_SVIDEO; venc->bridge.interlace_allowed = true; drm_bridge_add(&venc->bridge); } static void venc_bridge_cleanup(struct venc_device *venc) { drm_bridge_remove(&venc->bridge); } /* ----------------------------------------------------------------------------- * Component Bind & Unbind */ static int venc_bind(struct device *dev, struct device *master, void *data) { struct dss_device *dss = dss_get_device(master); struct venc_device *venc = dev_get_drvdata(dev); u8 rev_id; int r; venc->dss = dss; r = venc_runtime_get(venc); if (r) return r; rev_id = (u8)(venc_read_reg(venc, VENC_REV_ID) & 0xff); dev_dbg(dev, "OMAP VENC rev %d\n", rev_id); venc_runtime_put(venc); venc->debugfs = dss_debugfs_create_file(dss, "venc", venc_dump_regs, venc); return 0; } static void venc_unbind(struct device *dev, struct device *master, void *data) { struct venc_device *venc = dev_get_drvdata(dev); dss_debugfs_remove_file(venc->debugfs); } static const struct component_ops venc_component_ops = { .bind = venc_bind, .unbind = venc_unbind, }; /* ----------------------------------------------------------------------------- * Probe & Remove, Suspend & Resume */ static int venc_init_output(struct venc_device *venc) { struct omap_dss_device *out = &venc->output; int r; venc_bridge_init(venc); out->dev = &venc->pdev->dev; out->id = OMAP_DSS_OUTPUT_VENC; out->type = OMAP_DISPLAY_TYPE_VENC; out->name = "venc.0"; out->dispc_channel = OMAP_DSS_CHANNEL_DIGIT; out->owner = THIS_MODULE; out->of_port = 0; out->ops_flags = OMAP_DSS_DEVICE_OP_MODES; r = omapdss_device_init_output(out, &venc->bridge); if (r < 0) { venc_bridge_cleanup(venc); return r; } omapdss_device_register(out); return 0; } static void venc_uninit_output(struct venc_device *venc) { omapdss_device_unregister(&venc->output); omapdss_device_cleanup_output(&venc->output); venc_bridge_cleanup(venc); } static int venc_probe_of(struct venc_device *venc) { struct device_node *node = venc->pdev->dev.of_node; struct device_node *ep; u32 channels; int r; ep = of_graph_get_endpoint_by_regs(node, 0, 0); if (!ep) return 0; venc->invert_polarity = of_property_read_bool(ep, "ti,invert-polarity"); r = of_property_read_u32(ep, "ti,channels", &channels); if (r) { dev_err(&venc->pdev->dev, "failed to read property 'ti,channels': %d\n", r); goto err; } switch (channels) { case 1: venc->type = OMAP_DSS_VENC_TYPE_COMPOSITE; break; case 2: venc->type = OMAP_DSS_VENC_TYPE_SVIDEO; break; default: dev_err(&venc->pdev->dev, "bad channel property '%d'\n", channels); r = -EINVAL; goto err; } of_node_put(ep); return 0; err: of_node_put(ep); return r; } static const struct soc_device_attribute venc_soc_devices[] = { { .machine = "OMAP3[45]*" }, { .machine = "AM35*" }, { /* sentinel */ } }; static int venc_probe(struct platform_device *pdev) { struct venc_device *venc; struct resource *venc_mem; int r; venc = kzalloc(sizeof(*venc), GFP_KERNEL); if (!venc) return -ENOMEM; venc->pdev = pdev; platform_set_drvdata(pdev, venc); /* The OMAP34xx, OMAP35xx and AM35xx VENC require the TV DAC clock. */ if (soc_device_match(venc_soc_devices)) venc->requires_tv_dac_clk = true; venc->config = &venc_config_pal_trm; venc_mem = platform_get_resource(venc->pdev, IORESOURCE_MEM, 0); venc->base = devm_ioremap_resource(&pdev->dev, venc_mem); if (IS_ERR(venc->base)) { r = PTR_ERR(venc->base); goto err_free; } venc->vdda_dac_reg = devm_regulator_get(&pdev->dev, "vdda"); if (IS_ERR(venc->vdda_dac_reg)) { r = PTR_ERR(venc->vdda_dac_reg); if (r != -EPROBE_DEFER) DSSERR("can't get VDDA_DAC regulator\n"); goto err_free; } r = venc_get_clocks(venc); if (r) goto err_free; r = venc_probe_of(venc); if (r) goto err_free; pm_runtime_enable(&pdev->dev); r = venc_init_output(venc); if (r) goto err_pm_disable; r = component_add(&pdev->dev, &venc_component_ops); if (r) goto err_uninit_output; return 0; err_uninit_output: venc_uninit_output(venc); err_pm_disable: pm_runtime_disable(&pdev->dev); err_free: kfree(venc); return r; } static int venc_remove(struct platform_device *pdev) { struct venc_device *venc = platform_get_drvdata(pdev); component_del(&pdev->dev, &venc_component_ops); venc_uninit_output(venc); pm_runtime_disable(&pdev->dev); kfree(venc); return 0; } static int venc_runtime_suspend(struct device *dev) { struct venc_device *venc = dev_get_drvdata(dev); if (venc->tv_dac_clk) clk_disable_unprepare(venc->tv_dac_clk); return 0; } static int venc_runtime_resume(struct device *dev) { struct venc_device *venc = dev_get_drvdata(dev); if (venc->tv_dac_clk) clk_prepare_enable(venc->tv_dac_clk); return 0; } static const struct dev_pm_ops venc_pm_ops = { .runtime_suspend = venc_runtime_suspend, .runtime_resume = venc_runtime_resume, SET_LATE_SYSTEM_SLEEP_PM_OPS(pm_runtime_force_suspend, pm_runtime_force_resume) }; static const struct of_device_id venc_of_match[] = { { .compatible = "ti,omap2-venc", }, { .compatible = "ti,omap3-venc", }, { .compatible = "ti,omap4-venc", }, {}, }; struct platform_driver omap_venchw_driver = { .probe = venc_probe, .remove = venc_remove, .driver = { .name = "omapdss_venc", .pm = &venc_pm_ops, .of_match_table = venc_of_match, .suppress_bind_attrs = true, }, };