/* Copyright (c) 2013-2015, The Linux Foundation. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 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. * * Neither the name of The Linux Foundation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 * COPYRIGHT OWNER 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 #include #include #include #include #include #include #include #include #include #include #include #include #include "include/panel.h" #include "include/display_resource.h" #include "gcdb_display.h" #define HFPLL_LDO_ID 8 static struct pm8x41_wled_data wled_ctrl = { .mod_scheme = 0x00, .led1_brightness = (0x0F << 8) | 0xEF, .max_duty_cycle = 0x01, .ovp = 0x0, .full_current_scale = 0x19, .fdbck = 0x1 }; static uint32_t dsi_pll_enable_seq_m(uint32_t pll_base) { uint32_t i = 0; uint32_t pll_locked = 0; mdss_dsi_uniphy_pll_sw_reset(pll_base); /* * Add hardware recommended delays between register writes for * the updates to take effect. These delays are necessary for the * PLL to successfully lock */ writel(0x01, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x05, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x0f, pll_base + 0x0020); /* GLB CFG */ udelay(1000); mdss_dsi_uniphy_pll_lock_detect_setting(pll_base); pll_locked = readl(pll_base + 0x00c0) & 0x01; for (i = 0; (i < 4) && !pll_locked; i++) { writel(0x07, pll_base + 0x0020); /* GLB CFG */ if (i != 0) writel(0x34, pll_base + 0x00070); /* CAL CFG1*/ udelay(1); writel(0x0f, pll_base + 0x0020); /* GLB CFG */ udelay(1000); mdss_dsi_uniphy_pll_lock_detect_setting(pll_base); pll_locked = readl(pll_base + 0x00c0) & 0x01; } return pll_locked; } static uint32_t dsi_pll_enable_seq_d(uint32_t pll_base) { uint32_t pll_locked = 0; mdss_dsi_uniphy_pll_sw_reset(pll_base); /* * Add hardware recommended delays between register writes for * the updates to take effect. These delays are necessary for the * PLL to successfully lock */ writel(0x01, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x05, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x07, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x05, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x07, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x0f, pll_base + 0x0020); /* GLB CFG */ udelay(1000); mdss_dsi_uniphy_pll_lock_detect_setting(pll_base); pll_locked = readl(pll_base + 0x00c0) & 0x01; return pll_locked; } static uint32_t dsi_pll_enable_seq_f1(uint32_t pll_base) { uint32_t pll_locked = 0; mdss_dsi_uniphy_pll_sw_reset(pll_base); /* * Add hardware recommended delays between register writes for * the updates to take effect. These delays are necessary for the * PLL to successfully lock */ writel(0x01, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x05, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x0f, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x0d, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x0f, pll_base + 0x0020); /* GLB CFG */ udelay(1000); mdss_dsi_uniphy_pll_lock_detect_setting(pll_base); pll_locked = readl(pll_base + 0x00c0) & 0x01; return pll_locked; } static uint32_t dsi_pll_enable_seq_c(uint32_t pll_base) { uint32_t pll_locked = 0; mdss_dsi_uniphy_pll_sw_reset(pll_base); /* * Add hardware recommended delays between register writes for * the updates to take effect. These delays are necessary for the * PLL to successfully lock */ writel(0x01, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x05, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x0f, pll_base + 0x0020); /* GLB CFG */ udelay(1000); mdss_dsi_uniphy_pll_lock_detect_setting(pll_base); pll_locked = readl(pll_base + 0x00c0) & 0x01; return pll_locked; } static uint32_t dsi_pll_enable_seq_e(uint32_t pll_base) { uint32_t pll_locked = 0; mdss_dsi_uniphy_pll_sw_reset(pll_base); /* * Add hardware recommended delays between register writes for * the updates to take effect. These delays are necessary for the * PLL to successfully lock */ writel(0x01, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x05, pll_base + 0x0020); /* GLB CFG */ udelay(200); writel(0x0d, pll_base + 0x0020); /* GLB CFG */ udelay(1); writel(0x0f, pll_base + 0x0020); /* GLB CFG */ udelay(1000); mdss_dsi_uniphy_pll_lock_detect_setting(pll_base); pll_locked = readl(pll_base + 0x00c0) & 0x01; return pll_locked; } static int msm8226_wled_backlight_ctrl(uint8_t enable) { if (enable) { pm8x41_wled_config(&wled_ctrl); pm8x41_wled_sink_control(enable); pm8x41_wled_iled_sync_control(enable); pm8x41_wled_led_mod_enable(enable); } pm8x41_wled_enable(enable); return NO_ERROR; } static int msm8226_pwm_backlight_ctrl(int gpio_num, int lpg_chan, int enable) { struct pm8x41_gpio gpio_param = { .direction = PM_GPIO_DIR_OUT, .function = PM_GPIO_FUNC_2, .vin_sel = 2, /* VIN_2 */ .pull = PM_GPIO_PULL_UP_1_5 | PM_GPIO_PULLDOWN_10, .output_buffer = PM_GPIO_OUT_CMOS, .out_strength = PM_GPIO_OUT_DRIVE_HIGH, }; dprintf(SPEW, "%s: gpio=%d lpg=%d enable=%d\n", __func__, gpio_num, lpg_chan, enable); if (enable) { pm8x41_gpio_config(gpio_num, &gpio_param); pm8x41_lpg_write(lpg_chan, 0x41, 0x33); /* LPG_PWM_SIZE_CLK, */ pm8x41_lpg_write(lpg_chan, 0x42, 0x01); /* LPG_PWM_FREQ_PREDIV */ pm8x41_lpg_write(lpg_chan, 0x43, 0x20); /* LPG_PWM_TYPE_CONFIG */ pm8x41_lpg_write(lpg_chan, 0x44, 0xb2); /* LPG_VALUE_LSB */ pm8x41_lpg_write(lpg_chan, 0x45, 0x01); /* LPG_VALUE_MSB */ pm8x41_lpg_write(lpg_chan, 0x46, 0xe4); /* LPG_ENABLE_CONTROL */ } else { pm8x41_lpg_write(lpg_chan, 0x46, 0x00); } return NO_ERROR; } int target_backlight_ctrl(struct backlight *bl, uint8_t enable) { uint32_t ret = NO_ERROR; dprintf(SPEW, "target_backlight_ctrl\n"); if (!bl) { dprintf(CRITICAL, "backlight structure is not available\n"); return ERR_INVALID_ARGS; } switch (bl->bl_interface_type) { case BL_WLED: ret = msm8226_wled_backlight_ctrl(enable); break; case BL_PWM: ret = msm8226_pwm_backlight_ctrl(pwm_gpio.pin_id, PWM_BL_LPG_CHAN_ID, enable); break; case BL_DCS: break; default: dprintf(CRITICAL, "backlight type:%d not supported\n", bl->bl_interface_type); return ERR_NOT_SUPPORTED; } return ret; } static void dsi_pll_enable_seq(uint32_t pll_base) { if (dsi_pll_enable_seq_m(pll_base)) { } else if (dsi_pll_enable_seq_d(pll_base)) { } else if (dsi_pll_enable_seq_d(pll_base)) { } else if (dsi_pll_enable_seq_f1(pll_base)) { } else if (dsi_pll_enable_seq_c(pll_base)) { } else if (dsi_pll_enable_seq_e(pll_base)) { } else { dprintf(CRITICAL, "Not able to enable the pll\n"); } } int target_panel_clock(uint8_t enable, struct msm_panel_info *pinfo) { int32_t ret; struct mdss_dsi_pll_config *pll_data; dprintf(SPEW, "target_panel_clock\n"); pll_data = pinfo->mipi.dsi_pll_config; if (enable) { mdp_gdsc_ctrl(enable); mmss_bus_clocks_enable(); mdp_clock_enable(); ret = restore_secure_cfg(SECURE_DEVICE_MDSS); if (ret) { dprintf(CRITICAL, "%s: Failed to restore MDP security configs", __func__); mdp_clock_disable(); mmss_bus_clocks_disable(); mdp_gdsc_ctrl(0); return ret; } mdss_dsi_auto_pll_config(pinfo->mipi.pll_base, pinfo->mipi.ctl_base, pll_data); dsi_pll_enable_seq(pinfo->mipi.pll_base); mmss_dsi_clocks_enable(pll_data->pclk_m, pll_data->pclk_n, pll_data->pclk_d); } else if(!target_cont_splash_screen()) { mmss_dsi_clocks_disable(); mdp_clock_disable(); mmss_bus_clocks_disable(); mdp_gdsc_ctrl(enable); } return 0; } int target_panel_reset(uint8_t enable, struct panel_reset_sequence *resetseq, struct msm_panel_info *pinfo) { int ret = NO_ERROR; if (enable) { if (pinfo->mipi.use_enable_gpio) { gpio_tlmm_config(enable_gpio.pin_id, 0, enable_gpio.pin_direction, enable_gpio.pin_pull, enable_gpio.pin_strength, enable_gpio.pin_state); gpio_set_dir(enable_gpio.pin_id, 2); } gpio_tlmm_config(reset_gpio.pin_id, 0, reset_gpio.pin_direction, reset_gpio.pin_pull, reset_gpio.pin_strength, reset_gpio.pin_state); gpio_set_dir(reset_gpio.pin_id, 2); gpio_set_value(reset_gpio.pin_id, resetseq->pin_state[0]); mdelay(resetseq->sleep[0]); gpio_set_value(reset_gpio.pin_id, resetseq->pin_state[1]); mdelay(resetseq->sleep[1]); gpio_set_value(reset_gpio.pin_id, resetseq->pin_state[2]); mdelay(resetseq->sleep[2]); } else if(!target_cont_splash_screen()) { gpio_set_value(reset_gpio.pin_id, 0); if (pinfo->mipi.use_enable_gpio) gpio_set_value(enable_gpio.pin_id, 0); } return ret; } int target_ldo_ctrl(uint8_t enable, struct msm_panel_info *pinfo) { uint32_t ret = NO_ERROR; uint32_t ldocounter = 0; uint32_t pm8x41_ldo_base = 0x13F00; while (ldocounter < TOTAL_LDO_DEFINED) { struct pm8x41_ldo ldo_entry = LDO((pm8x41_ldo_base + 0x100 * ldo_entry_array[ldocounter].ldo_id), ldo_entry_array[ldocounter].ldo_type); dprintf(SPEW, "Setting %s\n", ldo_entry_array[ldocounter].ldo_id); /* Set voltage during power on */ if (enable) { pm8x41_ldo_set_voltage(&ldo_entry, ldo_entry_array[ldocounter].ldo_voltage); pm8x41_ldo_control(&ldo_entry, enable); } else if(!target_cont_splash_screen() && ldo_entry_array[ldocounter].ldo_id != HFPLL_LDO_ID) { pm8x41_ldo_control(&ldo_entry, enable); } ldocounter++; } return ret; } int target_dsi_phy_config(struct mdss_dsi_phy_ctrl *phy_db) { memcpy(phy_db->regulator, panel_regulator_settings, REGULATOR_SIZE); memcpy(phy_db->ctrl, panel_physical_ctrl, PHYSICAL_SIZE); memcpy(phy_db->strength, panel_strength_ctrl, STRENGTH_SIZE); memcpy(phy_db->bistCtrl, panel_bist_ctrl, BIST_SIZE); memcpy(phy_db->laneCfg, panel_lane_config, LANE_SIZE); return NO_ERROR; } bool target_display_panel_node(char *pbuf, uint16_t buf_size) { return gcdb_display_cmdline_arg(pbuf, buf_size); } void target_display_init(const char *panel_name) { uint32_t panel_loop = 0; uint32_t ret = 0; uint32_t fb_addr = MIPI_FB_ADDR; struct oem_panel_data oem; set_panel_cmd_string(panel_name); oem = mdss_dsi_get_oem_data(); if (!strcmp(oem.panel, NO_PANEL_CONFIG) || !strcmp(oem.panel, SIM_VIDEO_PANEL) || !strcmp(oem.panel, SIM_CMD_PANEL) || oem.skip) { dprintf(INFO, "Selected panel: %s\nSkip panel configuration\n", oem.panel); return; } if (board_hardware_subtype() == HW_PLATFORM_SUBTYPE_QVGA) fb_addr = MIPI_FB_ADDR_QVGA; do { target_force_cont_splash_disable(false); ret = gcdb_display_init(oem.panel, MDP_REV_50, fb_addr); if (!ret || ret == ERR_NOT_SUPPORTED) { break; } else { target_force_cont_splash_disable(true); msm_display_off(); } } while (++panel_loop <= oem_panel_max_auto_detect_panels()); if (!oem.cont_splash) { dprintf(INFO, "Forcing continuous splash disable\n"); target_force_cont_splash_disable(true); } } void target_display_shutdown(void) { gcdb_display_shutdown(); }