forked from Minki/linux
bbbe775ec5
The Amlogic Meson Display controller is composed of several components : DMC|---------------VPU (Video Processing Unit)----------------|------HHI------| | vd1 _______ _____________ _________________ | | D |-------| |----| | | | | HDMI PLL | D | vd2 | VIU | | Video Post | | Video Encoders |<---|-----VCLK | R |-------| |----| Processing | | | | | | osd2 | | | |---| Enci ----------|----|-----VDAC------| R |-------| CSC |----| Scalers | | Encp ----------|----|----HDMI-TX----| A | osd1 | | | Blenders | | Encl ----------|----|---------------| M |-------|______|----|____________| |________________| | | ___|__________________________________________________________|_______________| VIU: Video Input Unit --------------------- The Video Input Unit is in charge of the pixel scanout from the DDR memory. It fetches the frames addresses, stride and parameters from the "Canvas" memory. This part is also in charge of the CSC (Colorspace Conversion). It can handle 2 OSD Planes and 2 Video Planes. VPP: Video Post Processing -------------------------- The Video Post Processing is in charge of the scaling and blending of the various planes into a single pixel stream. There is a special "pre-blending" used by the video planes with a dedicated scaler and a "post-blending" to merge with the OSD Planes. The OSD planes also have a dedicated scaler for one of the OSD. VENC: Video Encoders -------------------- The VENC is composed of the multiple pixel encoders : - ENCI : Interlace Video encoder for CVBS and Interlace HDMI - ENCP : Progressive Video Encoder for HDMI - ENCL : LCD LVDS Encoder The VENC Unit gets a Pixel Clocks (VCLK) from a dedicated HDMI PLL and clock tree and provides the scanout clock to the VPP and VIU. The ENCI is connected to a single VDAC for Composite Output. The ENCI and ENCP are connected to an on-chip HDMI Transceiver. This driver is a DRM/KMS driver using the following DRM components : - GEM-CMA - PRIME-CMA - Atomic Modesetting - FBDev-CMA For the following SoCs : - GXBB Family (S905) - GXL Family (S905X, S905D) - GXM Family (S912) The current driver only supports the CVBS PAL/NTSC output modes, but the CRTC/Planes management should support bigger modes. But Advanced Colorspace Conversion, Scaling and HDMI Modes will be added in a second time. The Device Tree bindings makes use of the endpoints video interface definitions to connect to the optional CVBS and in the future the HDMI Connector nodes. HDMI Support is planned for a next release. Acked-by: Daniel Vetter <daniel.vetter@ffwll.ch> Signed-off-by: Neil Armstrong <narmstrong@baylibre.com>
332 lines
10 KiB
C
332 lines
10 KiB
C
/*
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* Copyright (C) 2016 BayLibre, SAS
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* Author: Neil Armstrong <narmstrong@baylibre.com>
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* Copyright (C) 2015 Amlogic, Inc. All rights reserved.
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* Copyright (C) 2014 Endless Mobile
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License as
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* published by the Free Software Foundation; either version 2 of the
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* License, or (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful, but
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* WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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* General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, see <http://www.gnu.org/licenses/>.
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*/
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#include <linux/kernel.h>
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#include <linux/module.h>
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#include <drm/drmP.h>
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#include "meson_drv.h"
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#include "meson_viu.h"
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#include "meson_vpp.h"
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#include "meson_venc.h"
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#include "meson_canvas.h"
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#include "meson_registers.h"
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/*
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* VIU Handles the Pixel scanout and the basic Colorspace conversions
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* We handle the following features :
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* - OSD1 RGB565/RGB888/xRGB8888 scanout
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* - RGB conversion to x/cb/cr
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* - Progressive or Interlace buffer scanout
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* - OSD1 Commit on Vsync
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* - HDR OSD matrix for GXL/GXM
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*
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* What is missing :
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* - BGR888/xBGR8888/BGRx8888/BGRx8888 modes
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* - YUV4:2:2 Y0CbY1Cr scanout
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* - Conversion to YUV 4:4:4 from 4:2:2 input
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* - Colorkey Alpha matching
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* - Big endian scanout
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* - X/Y reverse scanout
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* - Global alpha setup
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* - OSD2 support, would need interlace switching on vsync
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* - OSD1 full scaling to support TV overscan
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*/
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/* OSD csc defines */
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enum viu_matrix_sel_e {
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VIU_MATRIX_OSD_EOTF = 0,
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VIU_MATRIX_OSD,
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};
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enum viu_lut_sel_e {
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VIU_LUT_OSD_EOTF = 0,
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VIU_LUT_OSD_OETF,
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};
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#define COEFF_NORM(a) ((int)((((a) * 2048.0) + 1) / 2))
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#define MATRIX_5X3_COEF_SIZE 24
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#define EOTF_COEFF_NORM(a) ((int)((((a) * 4096.0) + 1) / 2))
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#define EOTF_COEFF_SIZE 10
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#define EOTF_COEFF_RIGHTSHIFT 1
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static int RGB709_to_YUV709l_coeff[MATRIX_5X3_COEF_SIZE] = {
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0, 0, 0, /* pre offset */
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COEFF_NORM(0.181873), COEFF_NORM(0.611831), COEFF_NORM(0.061765),
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COEFF_NORM(-0.100251), COEFF_NORM(-0.337249), COEFF_NORM(0.437500),
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COEFF_NORM(0.437500), COEFF_NORM(-0.397384), COEFF_NORM(-0.040116),
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0, 0, 0, /* 10'/11'/12' */
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0, 0, 0, /* 20'/21'/22' */
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64, 512, 512, /* offset */
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0, 0, 0 /* mode, right_shift, clip_en */
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};
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/* eotf matrix: bypass */
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static int eotf_bypass_coeff[EOTF_COEFF_SIZE] = {
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EOTF_COEFF_NORM(1.0), EOTF_COEFF_NORM(0.0), EOTF_COEFF_NORM(0.0),
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EOTF_COEFF_NORM(0.0), EOTF_COEFF_NORM(1.0), EOTF_COEFF_NORM(0.0),
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EOTF_COEFF_NORM(0.0), EOTF_COEFF_NORM(0.0), EOTF_COEFF_NORM(1.0),
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EOTF_COEFF_RIGHTSHIFT /* right shift */
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};
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void meson_viu_set_osd_matrix(struct meson_drm *priv,
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enum viu_matrix_sel_e m_select,
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int *m, bool csc_on)
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{
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if (m_select == VIU_MATRIX_OSD) {
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/* osd matrix, VIU_MATRIX_0 */
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writel(((m[0] & 0xfff) << 16) | (m[1] & 0xfff),
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priv->io_base + _REG(VIU_OSD1_MATRIX_PRE_OFFSET0_1));
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writel(m[2] & 0xfff,
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priv->io_base + _REG(VIU_OSD1_MATRIX_PRE_OFFSET2));
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writel(((m[3] & 0x1fff) << 16) | (m[4] & 0x1fff),
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priv->io_base + _REG(VIU_OSD1_MATRIX_COEF00_01));
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writel(((m[5] & 0x1fff) << 16) | (m[6] & 0x1fff),
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priv->io_base + _REG(VIU_OSD1_MATRIX_COEF02_10));
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writel(((m[7] & 0x1fff) << 16) | (m[8] & 0x1fff),
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priv->io_base + _REG(VIU_OSD1_MATRIX_COEF11_12));
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writel(((m[9] & 0x1fff) << 16) | (m[10] & 0x1fff),
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priv->io_base + _REG(VIU_OSD1_MATRIX_COEF20_21));
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if (m[21]) {
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writel(((m[11] & 0x1fff) << 16) | (m[12] & 0x1fff),
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priv->io_base +
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_REG(VIU_OSD1_MATRIX_COEF22_30));
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writel(((m[13] & 0x1fff) << 16) | (m[14] & 0x1fff),
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priv->io_base +
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_REG(VIU_OSD1_MATRIX_COEF31_32));
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writel(((m[15] & 0x1fff) << 16) | (m[16] & 0x1fff),
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priv->io_base +
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_REG(VIU_OSD1_MATRIX_COEF40_41));
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writel(m[17] & 0x1fff, priv->io_base +
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_REG(VIU_OSD1_MATRIX_COLMOD_COEF42));
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} else
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writel((m[11] & 0x1fff) << 16, priv->io_base +
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_REG(VIU_OSD1_MATRIX_COEF22_30));
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writel(((m[18] & 0xfff) << 16) | (m[19] & 0xfff),
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priv->io_base + _REG(VIU_OSD1_MATRIX_OFFSET0_1));
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writel(m[20] & 0xfff,
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priv->io_base + _REG(VIU_OSD1_MATRIX_OFFSET2));
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writel_bits_relaxed(3 << 30, m[21] << 30,
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priv->io_base + _REG(VIU_OSD1_MATRIX_COLMOD_COEF42));
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writel_bits_relaxed(7 << 16, m[22] << 16,
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priv->io_base + _REG(VIU_OSD1_MATRIX_COLMOD_COEF42));
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/* 23 reserved for clipping control */
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writel_bits_relaxed(BIT(0), csc_on ? BIT(0) : 0,
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priv->io_base + _REG(VIU_OSD1_MATRIX_CTRL));
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writel_bits_relaxed(BIT(1), 0,
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priv->io_base + _REG(VIU_OSD1_MATRIX_CTRL));
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} else if (m_select == VIU_MATRIX_OSD_EOTF) {
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int i;
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/* osd eotf matrix, VIU_MATRIX_OSD_EOTF */
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for (i = 0; i < 5; i++)
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writel(((m[i * 2] & 0x1fff) << 16) |
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(m[i * 2 + 1] & 0x1fff), priv->io_base +
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_REG(VIU_OSD1_EOTF_CTL + i + 1));
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writel_bits_relaxed(BIT(30), csc_on ? BIT(30) : 0,
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priv->io_base + _REG(VIU_OSD1_EOTF_CTL));
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writel_bits_relaxed(BIT(31), csc_on ? BIT(31) : 0,
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priv->io_base + _REG(VIU_OSD1_EOTF_CTL));
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}
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}
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#define OSD_EOTF_LUT_SIZE 33
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#define OSD_OETF_LUT_SIZE 41
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void meson_viu_set_osd_lut(struct meson_drm *priv, enum viu_lut_sel_e lut_sel,
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unsigned int *r_map, unsigned int *g_map,
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unsigned int *b_map,
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bool csc_on)
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{
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unsigned int addr_port;
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unsigned int data_port;
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unsigned int ctrl_port;
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int i;
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if (lut_sel == VIU_LUT_OSD_EOTF) {
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addr_port = VIU_OSD1_EOTF_LUT_ADDR_PORT;
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data_port = VIU_OSD1_EOTF_LUT_DATA_PORT;
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ctrl_port = VIU_OSD1_EOTF_CTL;
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} else if (lut_sel == VIU_LUT_OSD_OETF) {
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addr_port = VIU_OSD1_OETF_LUT_ADDR_PORT;
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data_port = VIU_OSD1_OETF_LUT_DATA_PORT;
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ctrl_port = VIU_OSD1_OETF_CTL;
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} else
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return;
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if (lut_sel == VIU_LUT_OSD_OETF) {
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writel(0, priv->io_base + _REG(addr_port));
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for (i = 0; i < 20; i++)
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writel(r_map[i * 2] | (r_map[i * 2 + 1] << 16),
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priv->io_base + _REG(data_port));
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writel(r_map[OSD_OETF_LUT_SIZE - 1] | (g_map[0] << 16),
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priv->io_base + _REG(data_port));
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for (i = 0; i < 20; i++)
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writel(g_map[i * 2 + 1] | (g_map[i * 2 + 2] << 16),
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priv->io_base + _REG(data_port));
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for (i = 0; i < 20; i++)
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writel(b_map[i * 2] | (b_map[i * 2 + 1] << 16),
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priv->io_base + _REG(data_port));
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writel(b_map[OSD_OETF_LUT_SIZE - 1],
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priv->io_base + _REG(data_port));
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if (csc_on)
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writel_bits_relaxed(0x7 << 29, 7 << 29,
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priv->io_base + _REG(ctrl_port));
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else
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writel_bits_relaxed(0x7 << 29, 0,
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priv->io_base + _REG(ctrl_port));
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} else if (lut_sel == VIU_LUT_OSD_EOTF) {
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writel(0, priv->io_base + _REG(addr_port));
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for (i = 0; i < 20; i++)
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writel(r_map[i * 2] | (r_map[i * 2 + 1] << 16),
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priv->io_base + _REG(data_port));
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writel(r_map[OSD_EOTF_LUT_SIZE - 1] | (g_map[0] << 16),
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priv->io_base + _REG(data_port));
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for (i = 0; i < 20; i++)
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writel(g_map[i * 2 + 1] | (g_map[i * 2 + 2] << 16),
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priv->io_base + _REG(data_port));
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for (i = 0; i < 20; i++)
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writel(b_map[i * 2] | (b_map[i * 2 + 1] << 16),
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priv->io_base + _REG(data_port));
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writel(b_map[OSD_EOTF_LUT_SIZE - 1],
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priv->io_base + _REG(data_port));
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if (csc_on)
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writel_bits_relaxed(7 << 27, 7 << 27,
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priv->io_base + _REG(ctrl_port));
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else
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writel_bits_relaxed(7 << 27, 0,
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priv->io_base + _REG(ctrl_port));
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writel_bits_relaxed(BIT(31), BIT(31),
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priv->io_base + _REG(ctrl_port));
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}
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}
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/* eotf lut: linear */
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static unsigned int eotf_33_linear_mapping[OSD_EOTF_LUT_SIZE] = {
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0x0000, 0x0200, 0x0400, 0x0600,
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0x0800, 0x0a00, 0x0c00, 0x0e00,
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0x1000, 0x1200, 0x1400, 0x1600,
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0x1800, 0x1a00, 0x1c00, 0x1e00,
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0x2000, 0x2200, 0x2400, 0x2600,
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0x2800, 0x2a00, 0x2c00, 0x2e00,
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0x3000, 0x3200, 0x3400, 0x3600,
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0x3800, 0x3a00, 0x3c00, 0x3e00,
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0x4000
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};
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/* osd oetf lut: linear */
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static unsigned int oetf_41_linear_mapping[OSD_OETF_LUT_SIZE] = {
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0, 0, 0, 0,
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0, 32, 64, 96,
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128, 160, 196, 224,
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256, 288, 320, 352,
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384, 416, 448, 480,
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512, 544, 576, 608,
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640, 672, 704, 736,
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768, 800, 832, 864,
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896, 928, 960, 992,
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1023, 1023, 1023, 1023,
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1023
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};
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static void meson_viu_load_matrix(struct meson_drm *priv)
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{
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/* eotf lut bypass */
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meson_viu_set_osd_lut(priv, VIU_LUT_OSD_EOTF,
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eotf_33_linear_mapping, /* R */
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eotf_33_linear_mapping, /* G */
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eotf_33_linear_mapping, /* B */
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false);
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/* eotf matrix bypass */
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meson_viu_set_osd_matrix(priv, VIU_MATRIX_OSD_EOTF,
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eotf_bypass_coeff,
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false);
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/* oetf lut bypass */
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meson_viu_set_osd_lut(priv, VIU_LUT_OSD_OETF,
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oetf_41_linear_mapping, /* R */
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oetf_41_linear_mapping, /* G */
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oetf_41_linear_mapping, /* B */
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false);
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/* osd matrix RGB709 to YUV709 limit */
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meson_viu_set_osd_matrix(priv, VIU_MATRIX_OSD,
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RGB709_to_YUV709l_coeff,
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true);
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}
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void meson_viu_init(struct meson_drm *priv)
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{
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uint32_t reg;
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/* Disable OSDs */
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writel_bits_relaxed(BIT(0) | BIT(21), 0,
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priv->io_base + _REG(VIU_OSD1_CTRL_STAT));
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writel_bits_relaxed(BIT(0) | BIT(21), 0,
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priv->io_base + _REG(VIU_OSD2_CTRL_STAT));
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/* On GXL/GXM, Use the 10bit HDR conversion matrix */
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if (meson_vpu_is_compatible(priv, "amlogic,meson-gxm-vpu") ||
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meson_vpu_is_compatible(priv, "amlogic,meson-gxl-vpu"))
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meson_viu_load_matrix(priv);
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/* Initialize OSD1 fifo control register */
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reg = BIT(0) | /* Urgent DDR request priority */
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(4 << 5) | /* hold_fifo_lines */
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(3 << 10) | /* burst length 64 */
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(32 << 12) | /* fifo_depth_val: 32*8=256 */
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(2 << 22) | /* 4 words in 1 burst */
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(2 << 24);
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writel_relaxed(reg, priv->io_base + _REG(VIU_OSD1_FIFO_CTRL_STAT));
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writel_relaxed(reg, priv->io_base + _REG(VIU_OSD2_FIFO_CTRL_STAT));
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/* Set OSD alpha replace value */
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writel_bits_relaxed(0xff << OSD_REPLACE_SHIFT,
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0xff << OSD_REPLACE_SHIFT,
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priv->io_base + _REG(VIU_OSD1_CTRL_STAT2));
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writel_bits_relaxed(0xff << OSD_REPLACE_SHIFT,
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0xff << OSD_REPLACE_SHIFT,
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priv->io_base + _REG(VIU_OSD2_CTRL_STAT2));
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priv->viu.osd1_enabled = false;
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priv->viu.osd1_commit = false;
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priv->viu.osd1_interlace = false;
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}
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