linux_dsm_epyc7002/drivers/gpu/ipu-v3/ipu-ic.c

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// SPDX-License-Identifier: GPL-2.0-or-later
/*
* Copyright (C) 2012-2014 Mentor Graphics Inc.
* Copyright 2005-2012 Freescale Semiconductor, Inc. All Rights Reserved.
*/
#include <linux/types.h>
#include <linux/init.h>
#include <linux/errno.h>
#include <linux/spinlock.h>
#include <linux/bitrev.h>
#include <linux/io.h>
#include <linux/err.h>
#include <linux/sizes.h>
#include "ipu-prv.h"
/* IC Register Offsets */
#define IC_CONF 0x0000
#define IC_PRP_ENC_RSC 0x0004
#define IC_PRP_VF_RSC 0x0008
#define IC_PP_RSC 0x000C
#define IC_CMBP_1 0x0010
#define IC_CMBP_2 0x0014
#define IC_IDMAC_1 0x0018
#define IC_IDMAC_2 0x001C
#define IC_IDMAC_3 0x0020
#define IC_IDMAC_4 0x0024
/* IC Register Fields */
#define IC_CONF_PRPENC_EN (1 << 0)
#define IC_CONF_PRPENC_CSC1 (1 << 1)
#define IC_CONF_PRPENC_ROT_EN (1 << 2)
#define IC_CONF_PRPVF_EN (1 << 8)
#define IC_CONF_PRPVF_CSC1 (1 << 9)
#define IC_CONF_PRPVF_CSC2 (1 << 10)
#define IC_CONF_PRPVF_CMB (1 << 11)
#define IC_CONF_PRPVF_ROT_EN (1 << 12)
#define IC_CONF_PP_EN (1 << 16)
#define IC_CONF_PP_CSC1 (1 << 17)
#define IC_CONF_PP_CSC2 (1 << 18)
#define IC_CONF_PP_CMB (1 << 19)
#define IC_CONF_PP_ROT_EN (1 << 20)
#define IC_CONF_IC_GLB_LOC_A (1 << 28)
#define IC_CONF_KEY_COLOR_EN (1 << 29)
#define IC_CONF_RWS_EN (1 << 30)
#define IC_CONF_CSI_MEM_WR_EN (1 << 31)
#define IC_IDMAC_1_CB0_BURST_16 (1 << 0)
#define IC_IDMAC_1_CB1_BURST_16 (1 << 1)
#define IC_IDMAC_1_CB2_BURST_16 (1 << 2)
#define IC_IDMAC_1_CB3_BURST_16 (1 << 3)
#define IC_IDMAC_1_CB4_BURST_16 (1 << 4)
#define IC_IDMAC_1_CB5_BURST_16 (1 << 5)
#define IC_IDMAC_1_CB6_BURST_16 (1 << 6)
#define IC_IDMAC_1_CB7_BURST_16 (1 << 7)
#define IC_IDMAC_1_PRPENC_ROT_MASK (0x7 << 11)
#define IC_IDMAC_1_PRPENC_ROT_OFFSET 11
#define IC_IDMAC_1_PRPVF_ROT_MASK (0x7 << 14)
#define IC_IDMAC_1_PRPVF_ROT_OFFSET 14
#define IC_IDMAC_1_PP_ROT_MASK (0x7 << 17)
#define IC_IDMAC_1_PP_ROT_OFFSET 17
#define IC_IDMAC_1_PP_FLIP_RS (1 << 22)
#define IC_IDMAC_1_PRPVF_FLIP_RS (1 << 21)
#define IC_IDMAC_1_PRPENC_FLIP_RS (1 << 20)
#define IC_IDMAC_2_PRPENC_HEIGHT_MASK (0x3ff << 0)
#define IC_IDMAC_2_PRPENC_HEIGHT_OFFSET 0
#define IC_IDMAC_2_PRPVF_HEIGHT_MASK (0x3ff << 10)
#define IC_IDMAC_2_PRPVF_HEIGHT_OFFSET 10
#define IC_IDMAC_2_PP_HEIGHT_MASK (0x3ff << 20)
#define IC_IDMAC_2_PP_HEIGHT_OFFSET 20
#define IC_IDMAC_3_PRPENC_WIDTH_MASK (0x3ff << 0)
#define IC_IDMAC_3_PRPENC_WIDTH_OFFSET 0
#define IC_IDMAC_3_PRPVF_WIDTH_MASK (0x3ff << 10)
#define IC_IDMAC_3_PRPVF_WIDTH_OFFSET 10
#define IC_IDMAC_3_PP_WIDTH_MASK (0x3ff << 20)
#define IC_IDMAC_3_PP_WIDTH_OFFSET 20
struct ic_task_regoffs {
u32 rsc;
u32 tpmem_csc[2];
};
struct ic_task_bitfields {
u32 ic_conf_en;
u32 ic_conf_rot_en;
u32 ic_conf_cmb_en;
u32 ic_conf_csc1_en;
u32 ic_conf_csc2_en;
u32 ic_cmb_galpha_bit;
};
static const struct ic_task_regoffs ic_task_reg[IC_NUM_TASKS] = {
[IC_TASK_ENCODER] = {
.rsc = IC_PRP_ENC_RSC,
.tpmem_csc = {0x2008, 0},
},
[IC_TASK_VIEWFINDER] = {
.rsc = IC_PRP_VF_RSC,
.tpmem_csc = {0x4028, 0x4040},
},
[IC_TASK_POST_PROCESSOR] = {
.rsc = IC_PP_RSC,
.tpmem_csc = {0x6060, 0x6078},
},
};
static const struct ic_task_bitfields ic_task_bit[IC_NUM_TASKS] = {
[IC_TASK_ENCODER] = {
.ic_conf_en = IC_CONF_PRPENC_EN,
.ic_conf_rot_en = IC_CONF_PRPENC_ROT_EN,
.ic_conf_cmb_en = 0, /* NA */
.ic_conf_csc1_en = IC_CONF_PRPENC_CSC1,
.ic_conf_csc2_en = 0, /* NA */
.ic_cmb_galpha_bit = 0, /* NA */
},
[IC_TASK_VIEWFINDER] = {
.ic_conf_en = IC_CONF_PRPVF_EN,
.ic_conf_rot_en = IC_CONF_PRPVF_ROT_EN,
.ic_conf_cmb_en = IC_CONF_PRPVF_CMB,
.ic_conf_csc1_en = IC_CONF_PRPVF_CSC1,
.ic_conf_csc2_en = IC_CONF_PRPVF_CSC2,
.ic_cmb_galpha_bit = 0,
},
[IC_TASK_POST_PROCESSOR] = {
.ic_conf_en = IC_CONF_PP_EN,
.ic_conf_rot_en = IC_CONF_PP_ROT_EN,
.ic_conf_cmb_en = IC_CONF_PP_CMB,
.ic_conf_csc1_en = IC_CONF_PP_CSC1,
.ic_conf_csc2_en = IC_CONF_PP_CSC2,
.ic_cmb_galpha_bit = 8,
},
};
struct ipu_ic_priv;
struct ipu_ic {
enum ipu_ic_task task;
const struct ic_task_regoffs *reg;
const struct ic_task_bitfields *bit;
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
struct ipu_ic_colorspace in_cs;
struct ipu_ic_colorspace g_in_cs;
struct ipu_ic_colorspace out_cs;
bool graphics;
bool rotation;
bool in_use;
struct ipu_ic_priv *priv;
};
struct ipu_ic_priv {
void __iomem *base;
void __iomem *tpmem_base;
spinlock_t lock;
struct ipu_soc *ipu;
int use_count;
int irt_use_count;
struct ipu_ic task[IC_NUM_TASKS];
};
static inline u32 ipu_ic_read(struct ipu_ic *ic, unsigned offset)
{
return readl(ic->priv->base + offset);
}
static inline void ipu_ic_write(struct ipu_ic *ic, u32 value, unsigned offset)
{
writel(value, ic->priv->base + offset);
}
static int init_csc(struct ipu_ic *ic,
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
const struct ipu_ic_csc *csc,
int csc_index)
{
struct ipu_ic_priv *priv = ic->priv;
u32 __iomem *base;
const u16 (*c)[3];
const u16 *a;
u32 param;
base = (u32 __iomem *)
(priv->tpmem_base + ic->reg->tpmem_csc[csc_index]);
/* Cast to unsigned */
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
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c = (const u16 (*)[3])csc->params.coeff;
a = (const u16 *)csc->params.offset;
param = ((a[0] & 0x1f) << 27) | ((c[0][0] & 0x1ff) << 18) |
((c[1][1] & 0x1ff) << 9) | (c[2][2] & 0x1ff);
writel(param, base++);
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
param = ((a[0] & 0x1fe0) >> 5) | (csc->params.scale << 8) |
(csc->params.sat << 10);
writel(param, base++);
param = ((a[1] & 0x1f) << 27) | ((c[0][1] & 0x1ff) << 18) |
((c[1][0] & 0x1ff) << 9) | (c[2][0] & 0x1ff);
writel(param, base++);
param = ((a[1] & 0x1fe0) >> 5);
writel(param, base++);
param = ((a[2] & 0x1f) << 27) | ((c[0][2] & 0x1ff) << 18) |
((c[1][2] & 0x1ff) << 9) | (c[2][1] & 0x1ff);
writel(param, base++);
param = ((a[2] & 0x1fe0) >> 5);
writel(param, base++);
return 0;
}
static int calc_resize_coeffs(struct ipu_ic *ic,
u32 in_size, u32 out_size,
u32 *resize_coeff,
u32 *downsize_coeff)
{
struct ipu_ic_priv *priv = ic->priv;
struct ipu_soc *ipu = priv->ipu;
u32 temp_size, temp_downsize;
/*
* Input size cannot be more than 4096, and output size cannot
* be more than 1024
*/
if (in_size > 4096) {
dev_err(ipu->dev, "Unsupported resize (in_size > 4096)\n");
return -EINVAL;
}
if (out_size > 1024) {
dev_err(ipu->dev, "Unsupported resize (out_size > 1024)\n");
return -EINVAL;
}
/* Cannot downsize more than 4:1 */
if ((out_size << 2) < in_size) {
dev_err(ipu->dev, "Unsupported downsize\n");
return -EINVAL;
}
/* Compute downsizing coefficient */
temp_downsize = 0;
temp_size = in_size;
while (((temp_size > 1024) || (temp_size >= out_size * 2)) &&
(temp_downsize < 2)) {
temp_size >>= 1;
temp_downsize++;
}
*downsize_coeff = temp_downsize;
/*
* compute resizing coefficient using the following equation:
* resize_coeff = M * (SI - 1) / (SO - 1)
* where M = 2^13, SI = input size, SO = output size
*/
*resize_coeff = (8192L * (temp_size - 1)) / (out_size - 1);
if (*resize_coeff >= 16384L) {
dev_err(ipu->dev, "Warning! Overflow on resize coeff.\n");
*resize_coeff = 0x3FFF;
}
return 0;
}
void ipu_ic_task_enable(struct ipu_ic *ic)
{
struct ipu_ic_priv *priv = ic->priv;
unsigned long flags;
u32 ic_conf;
spin_lock_irqsave(&priv->lock, flags);
ic_conf = ipu_ic_read(ic, IC_CONF);
ic_conf |= ic->bit->ic_conf_en;
if (ic->rotation)
ic_conf |= ic->bit->ic_conf_rot_en;
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
if (ic->in_cs.cs != ic->out_cs.cs)
ic_conf |= ic->bit->ic_conf_csc1_en;
if (ic->graphics) {
ic_conf |= ic->bit->ic_conf_cmb_en;
ic_conf |= ic->bit->ic_conf_csc1_en;
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
if (ic->g_in_cs.cs != ic->out_cs.cs)
ic_conf |= ic->bit->ic_conf_csc2_en;
}
ipu_ic_write(ic, ic_conf, IC_CONF);
spin_unlock_irqrestore(&priv->lock, flags);
}
EXPORT_SYMBOL_GPL(ipu_ic_task_enable);
void ipu_ic_task_disable(struct ipu_ic *ic)
{
struct ipu_ic_priv *priv = ic->priv;
unsigned long flags;
u32 ic_conf;
spin_lock_irqsave(&priv->lock, flags);
ic_conf = ipu_ic_read(ic, IC_CONF);
ic_conf &= ~(ic->bit->ic_conf_en |
ic->bit->ic_conf_csc1_en |
ic->bit->ic_conf_rot_en);
if (ic->bit->ic_conf_csc2_en)
ic_conf &= ~ic->bit->ic_conf_csc2_en;
if (ic->bit->ic_conf_cmb_en)
ic_conf &= ~ic->bit->ic_conf_cmb_en;
ipu_ic_write(ic, ic_conf, IC_CONF);
spin_unlock_irqrestore(&priv->lock, flags);
}
EXPORT_SYMBOL_GPL(ipu_ic_task_disable);
int ipu_ic_task_graphics_init(struct ipu_ic *ic,
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
const struct ipu_ic_colorspace *g_in_cs,
bool galpha_en, u32 galpha,
bool colorkey_en, u32 colorkey)
{
struct ipu_ic_priv *priv = ic->priv;
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
struct ipu_ic_csc csc2;
unsigned long flags;
u32 reg, ic_conf;
int ret = 0;
if (ic->task == IC_TASK_ENCODER)
return -EINVAL;
spin_lock_irqsave(&priv->lock, flags);
ic_conf = ipu_ic_read(ic, IC_CONF);
if (!(ic_conf & ic->bit->ic_conf_csc1_en)) {
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
struct ipu_ic_csc csc1;
ret = ipu_ic_calc_csc(&csc1,
V4L2_YCBCR_ENC_601,
V4L2_QUANTIZATION_FULL_RANGE,
IPUV3_COLORSPACE_RGB,
V4L2_YCBCR_ENC_601,
V4L2_QUANTIZATION_FULL_RANGE,
IPUV3_COLORSPACE_RGB);
if (ret)
goto unlock;
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
/* need transparent CSC1 conversion */
ret = init_csc(ic, &csc1, 0);
if (ret)
goto unlock;
}
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
ic->g_in_cs = *g_in_cs;
csc2.in_cs = ic->g_in_cs;
csc2.out_cs = ic->out_cs;
ret = __ipu_ic_calc_csc(&csc2);
if (ret)
goto unlock;
ret = init_csc(ic, &csc2, 1);
if (ret)
goto unlock;
if (galpha_en) {
ic_conf |= IC_CONF_IC_GLB_LOC_A;
reg = ipu_ic_read(ic, IC_CMBP_1);
reg &= ~(0xff << ic->bit->ic_cmb_galpha_bit);
reg |= (galpha << ic->bit->ic_cmb_galpha_bit);
ipu_ic_write(ic, reg, IC_CMBP_1);
} else
ic_conf &= ~IC_CONF_IC_GLB_LOC_A;
if (colorkey_en) {
ic_conf |= IC_CONF_KEY_COLOR_EN;
ipu_ic_write(ic, colorkey, IC_CMBP_2);
} else
ic_conf &= ~IC_CONF_KEY_COLOR_EN;
ipu_ic_write(ic, ic_conf, IC_CONF);
ic->graphics = true;
unlock:
spin_unlock_irqrestore(&priv->lock, flags);
return ret;
}
EXPORT_SYMBOL_GPL(ipu_ic_task_graphics_init);
int ipu_ic_task_init_rsc(struct ipu_ic *ic,
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
const struct ipu_ic_csc *csc,
int in_width, int in_height,
int out_width, int out_height,
u32 rsc)
{
struct ipu_ic_priv *priv = ic->priv;
u32 downsize_coeff, resize_coeff;
unsigned long flags;
int ret = 0;
if (!rsc) {
/* Setup vertical resizing */
ret = calc_resize_coeffs(ic, in_height, out_height,
&resize_coeff, &downsize_coeff);
if (ret)
return ret;
rsc = (downsize_coeff << 30) | (resize_coeff << 16);
/* Setup horizontal resizing */
ret = calc_resize_coeffs(ic, in_width, out_width,
&resize_coeff, &downsize_coeff);
if (ret)
return ret;
rsc |= (downsize_coeff << 14) | resize_coeff;
}
spin_lock_irqsave(&priv->lock, flags);
ipu_ic_write(ic, rsc, ic->reg->rsc);
/* Setup color space conversion */
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
ic->in_cs = csc->in_cs;
ic->out_cs = csc->out_cs;
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
ret = init_csc(ic, csc, 0);
spin_unlock_irqrestore(&priv->lock, flags);
return ret;
}
int ipu_ic_task_init(struct ipu_ic *ic,
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
const struct ipu_ic_csc *csc,
int in_width, int in_height,
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
int out_width, int out_height)
{
gpu: ipu-v3: ipu-ic: Fully describe colorspace conversions Only providing the input and output RGB/YUV space to the IC task init functions is not sufficient. To fully characterize a colorspace conversion, the Y'CbCr encoding standard, and quantization also need to be specified. Define a 'struct ipu_ic_colorspace' that includes all the above. This allows to actually enforce the fact that the IC: - can only encode to/from YUV and RGB full range. A follow-up patch will remove this restriction. - can only encode using BT.601 standard. A follow-up patch will add Rec.709 encoding support. The determination of the CSC coefficients based on the input/output 'struct ipu_ic_colorspace' are moved to a new exported function ipu_ic_calc_csc(), and 'struct ic_csc_params' is exported as 'struct ipu_ic_csc_params'. ipu_ic_calc_csc() fills a 'struct ipu_ic_csc' with the input/output 'struct ipu_ic_colorspace' and the calculated 'struct ic_csc_params' from those input/output colorspaces. The functions ipu_ic_task_init(_rsc)() now take a filled 'struct ipu_ic_csc'. The existing CSC coefficient tables and ipu_ic_calc_csc() are moved to a new module ipu-ic-csc.c. This is in preparation for adding more coefficient tables for limited range quantization and more encoding standards. The existing ycbcr2rgb and inverse rgb2ycbcr tables defined the BT.601 Y'CbCr encoding coefficients. The rgb2ycbcr table specifically described the BT.601 encoding from full range RGB to full range YUV. Table comments have been added in ipu-ic-csc.c to make this more clear. The ycbcr2rgb inverse table described encoding YUV limited range to RGB full range. To be consistent with the rgb2ycbcr table, this table is converted to YUV full range to RGB full range, and the comments are expanded in ipu-ic-csc.c. The ic_csc_rgb2rgb table was just an identity matrix, so it is renamed 'identity' in ipu-ic-csc.c. Signed-off-by: Steve Longerbeam <slongerbeam@gmail.com> [p.zabel@pengutronix.de: removed a superfluous blank line] Signed-off-by: Philipp Zabel <p.zabel@pengutronix.de>
2019-05-22 08:03:14 +07:00
return ipu_ic_task_init_rsc(ic, csc,
in_width, in_height,
out_width, out_height, 0);
}
EXPORT_SYMBOL_GPL(ipu_ic_task_init);
int ipu_ic_task_idma_init(struct ipu_ic *ic, struct ipuv3_channel *channel,
u32 width, u32 height, int burst_size,
enum ipu_rotate_mode rot)
{
struct ipu_ic_priv *priv = ic->priv;
struct ipu_soc *ipu = priv->ipu;
u32 ic_idmac_1, ic_idmac_2, ic_idmac_3;
u32 temp_rot = bitrev8(rot) >> 5;
bool need_hor_flip = false;
unsigned long flags;
int ret = 0;
if ((burst_size != 8) && (burst_size != 16)) {
dev_err(ipu->dev, "Illegal burst length for IC\n");
return -EINVAL;
}
width--;
height--;
if (temp_rot & 0x2) /* Need horizontal flip */
need_hor_flip = true;
spin_lock_irqsave(&priv->lock, flags);
ic_idmac_1 = ipu_ic_read(ic, IC_IDMAC_1);
ic_idmac_2 = ipu_ic_read(ic, IC_IDMAC_2);
ic_idmac_3 = ipu_ic_read(ic, IC_IDMAC_3);
switch (channel->num) {
case IPUV3_CHANNEL_IC_PP_MEM:
if (burst_size == 16)
ic_idmac_1 |= IC_IDMAC_1_CB2_BURST_16;
else
ic_idmac_1 &= ~IC_IDMAC_1_CB2_BURST_16;
if (need_hor_flip)
ic_idmac_1 |= IC_IDMAC_1_PP_FLIP_RS;
else
ic_idmac_1 &= ~IC_IDMAC_1_PP_FLIP_RS;
ic_idmac_2 &= ~IC_IDMAC_2_PP_HEIGHT_MASK;
ic_idmac_2 |= height << IC_IDMAC_2_PP_HEIGHT_OFFSET;
ic_idmac_3 &= ~IC_IDMAC_3_PP_WIDTH_MASK;
ic_idmac_3 |= width << IC_IDMAC_3_PP_WIDTH_OFFSET;
break;
case IPUV3_CHANNEL_MEM_IC_PP:
if (burst_size == 16)
ic_idmac_1 |= IC_IDMAC_1_CB5_BURST_16;
else
ic_idmac_1 &= ~IC_IDMAC_1_CB5_BURST_16;
break;
case IPUV3_CHANNEL_MEM_ROT_PP:
ic_idmac_1 &= ~IC_IDMAC_1_PP_ROT_MASK;
ic_idmac_1 |= temp_rot << IC_IDMAC_1_PP_ROT_OFFSET;
break;
case IPUV3_CHANNEL_MEM_IC_PRP_VF:
if (burst_size == 16)
ic_idmac_1 |= IC_IDMAC_1_CB6_BURST_16;
else
ic_idmac_1 &= ~IC_IDMAC_1_CB6_BURST_16;
break;
case IPUV3_CHANNEL_IC_PRP_ENC_MEM:
if (burst_size == 16)
ic_idmac_1 |= IC_IDMAC_1_CB0_BURST_16;
else
ic_idmac_1 &= ~IC_IDMAC_1_CB0_BURST_16;
if (need_hor_flip)
ic_idmac_1 |= IC_IDMAC_1_PRPENC_FLIP_RS;
else
ic_idmac_1 &= ~IC_IDMAC_1_PRPENC_FLIP_RS;
ic_idmac_2 &= ~IC_IDMAC_2_PRPENC_HEIGHT_MASK;
ic_idmac_2 |= height << IC_IDMAC_2_PRPENC_HEIGHT_OFFSET;
ic_idmac_3 &= ~IC_IDMAC_3_PRPENC_WIDTH_MASK;
ic_idmac_3 |= width << IC_IDMAC_3_PRPENC_WIDTH_OFFSET;
break;
case IPUV3_CHANNEL_MEM_ROT_ENC:
ic_idmac_1 &= ~IC_IDMAC_1_PRPENC_ROT_MASK;
ic_idmac_1 |= temp_rot << IC_IDMAC_1_PRPENC_ROT_OFFSET;
break;
case IPUV3_CHANNEL_IC_PRP_VF_MEM:
if (burst_size == 16)
ic_idmac_1 |= IC_IDMAC_1_CB1_BURST_16;
else
ic_idmac_1 &= ~IC_IDMAC_1_CB1_BURST_16;
if (need_hor_flip)
ic_idmac_1 |= IC_IDMAC_1_PRPVF_FLIP_RS;
else
ic_idmac_1 &= ~IC_IDMAC_1_PRPVF_FLIP_RS;
ic_idmac_2 &= ~IC_IDMAC_2_PRPVF_HEIGHT_MASK;
ic_idmac_2 |= height << IC_IDMAC_2_PRPVF_HEIGHT_OFFSET;
ic_idmac_3 &= ~IC_IDMAC_3_PRPVF_WIDTH_MASK;
ic_idmac_3 |= width << IC_IDMAC_3_PRPVF_WIDTH_OFFSET;
break;
case IPUV3_CHANNEL_MEM_ROT_VF:
ic_idmac_1 &= ~IC_IDMAC_1_PRPVF_ROT_MASK;
ic_idmac_1 |= temp_rot << IC_IDMAC_1_PRPVF_ROT_OFFSET;
break;
case IPUV3_CHANNEL_G_MEM_IC_PRP_VF:
if (burst_size == 16)
ic_idmac_1 |= IC_IDMAC_1_CB3_BURST_16;
else
ic_idmac_1 &= ~IC_IDMAC_1_CB3_BURST_16;
break;
case IPUV3_CHANNEL_G_MEM_IC_PP:
if (burst_size == 16)
ic_idmac_1 |= IC_IDMAC_1_CB4_BURST_16;
else
ic_idmac_1 &= ~IC_IDMAC_1_CB4_BURST_16;
break;
case IPUV3_CHANNEL_VDI_MEM_IC_VF:
if (burst_size == 16)
ic_idmac_1 |= IC_IDMAC_1_CB7_BURST_16;
else
ic_idmac_1 &= ~IC_IDMAC_1_CB7_BURST_16;
break;
default:
goto unlock;
}
ipu_ic_write(ic, ic_idmac_1, IC_IDMAC_1);
ipu_ic_write(ic, ic_idmac_2, IC_IDMAC_2);
ipu_ic_write(ic, ic_idmac_3, IC_IDMAC_3);
if (ipu_rot_mode_is_irt(rot))
ic->rotation = true;
unlock:
spin_unlock_irqrestore(&priv->lock, flags);
return ret;
}
EXPORT_SYMBOL_GPL(ipu_ic_task_idma_init);
static void ipu_irt_enable(struct ipu_ic *ic)
{
struct ipu_ic_priv *priv = ic->priv;
if (!priv->irt_use_count)
ipu_module_enable(priv->ipu, IPU_CONF_ROT_EN);
priv->irt_use_count++;
}
static void ipu_irt_disable(struct ipu_ic *ic)
{
struct ipu_ic_priv *priv = ic->priv;
if (priv->irt_use_count) {
if (!--priv->irt_use_count)
ipu_module_disable(priv->ipu, IPU_CONF_ROT_EN);
}
}
int ipu_ic_enable(struct ipu_ic *ic)
{
struct ipu_ic_priv *priv = ic->priv;
unsigned long flags;
spin_lock_irqsave(&priv->lock, flags);
if (!priv->use_count)
ipu_module_enable(priv->ipu, IPU_CONF_IC_EN);
priv->use_count++;
if (ic->rotation)
ipu_irt_enable(ic);
spin_unlock_irqrestore(&priv->lock, flags);
return 0;
}
EXPORT_SYMBOL_GPL(ipu_ic_enable);
int ipu_ic_disable(struct ipu_ic *ic)
{
struct ipu_ic_priv *priv = ic->priv;
unsigned long flags;
spin_lock_irqsave(&priv->lock, flags);
priv->use_count--;
if (!priv->use_count)
ipu_module_disable(priv->ipu, IPU_CONF_IC_EN);
if (priv->use_count < 0)
priv->use_count = 0;
if (ic->rotation)
ipu_irt_disable(ic);
ic->rotation = ic->graphics = false;
spin_unlock_irqrestore(&priv->lock, flags);
return 0;
}
EXPORT_SYMBOL_GPL(ipu_ic_disable);
struct ipu_ic *ipu_ic_get(struct ipu_soc *ipu, enum ipu_ic_task task)
{
struct ipu_ic_priv *priv = ipu->ic_priv;
unsigned long flags;
struct ipu_ic *ic, *ret;
if (task >= IC_NUM_TASKS)
return ERR_PTR(-EINVAL);
ic = &priv->task[task];
spin_lock_irqsave(&priv->lock, flags);
if (ic->in_use) {
ret = ERR_PTR(-EBUSY);
goto unlock;
}
ic->in_use = true;
ret = ic;
unlock:
spin_unlock_irqrestore(&priv->lock, flags);
return ret;
}
EXPORT_SYMBOL_GPL(ipu_ic_get);
void ipu_ic_put(struct ipu_ic *ic)
{
struct ipu_ic_priv *priv = ic->priv;
unsigned long flags;
spin_lock_irqsave(&priv->lock, flags);
ic->in_use = false;
spin_unlock_irqrestore(&priv->lock, flags);
}
EXPORT_SYMBOL_GPL(ipu_ic_put);
int ipu_ic_init(struct ipu_soc *ipu, struct device *dev,
unsigned long base, unsigned long tpmem_base)
{
struct ipu_ic_priv *priv;
int i;
priv = devm_kzalloc(dev, sizeof(*priv), GFP_KERNEL);
if (!priv)
return -ENOMEM;
ipu->ic_priv = priv;
spin_lock_init(&priv->lock);
priv->base = devm_ioremap(dev, base, PAGE_SIZE);
if (!priv->base)
return -ENOMEM;
priv->tpmem_base = devm_ioremap(dev, tpmem_base, SZ_64K);
if (!priv->tpmem_base)
return -ENOMEM;
dev_dbg(dev, "IC base: 0x%08lx remapped to %p\n", base, priv->base);
priv->ipu = ipu;
for (i = 0; i < IC_NUM_TASKS; i++) {
priv->task[i].task = i;
priv->task[i].priv = priv;
priv->task[i].reg = &ic_task_reg[i];
priv->task[i].bit = &ic_task_bit[i];
}
return 0;
}
void ipu_ic_exit(struct ipu_soc *ipu)
{
}
void ipu_ic_dump(struct ipu_ic *ic)
{
struct ipu_ic_priv *priv = ic->priv;
struct ipu_soc *ipu = priv->ipu;
dev_dbg(ipu->dev, "IC_CONF = \t0x%08X\n",
ipu_ic_read(ic, IC_CONF));
dev_dbg(ipu->dev, "IC_PRP_ENC_RSC = \t0x%08X\n",
ipu_ic_read(ic, IC_PRP_ENC_RSC));
dev_dbg(ipu->dev, "IC_PRP_VF_RSC = \t0x%08X\n",
ipu_ic_read(ic, IC_PRP_VF_RSC));
dev_dbg(ipu->dev, "IC_PP_RSC = \t0x%08X\n",
ipu_ic_read(ic, IC_PP_RSC));
dev_dbg(ipu->dev, "IC_CMBP_1 = \t0x%08X\n",
ipu_ic_read(ic, IC_CMBP_1));
dev_dbg(ipu->dev, "IC_CMBP_2 = \t0x%08X\n",
ipu_ic_read(ic, IC_CMBP_2));
dev_dbg(ipu->dev, "IC_IDMAC_1 = \t0x%08X\n",
ipu_ic_read(ic, IC_IDMAC_1));
dev_dbg(ipu->dev, "IC_IDMAC_2 = \t0x%08X\n",
ipu_ic_read(ic, IC_IDMAC_2));
dev_dbg(ipu->dev, "IC_IDMAC_3 = \t0x%08X\n",
ipu_ic_read(ic, IC_IDMAC_3));
dev_dbg(ipu->dev, "IC_IDMAC_4 = \t0x%08X\n",
ipu_ic_read(ic, IC_IDMAC_4));
}
EXPORT_SYMBOL_GPL(ipu_ic_dump);