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linux/drivers/media/platform/vsp1/vsp1_rpf.c
Laurent Pinchart cbb7fa49c7 media: v4l: vsp1: Rename BRU to BRx 
Some VSP instances have two blending units named BRU (Blend/ROP Unit)
and BRS (Blend/ROP Sub unit). The BRS is a smaller version of the BRU
with only two inputs, but otherwise offers similar features and offers
the same register interface. The BRU and BRS can be used exchangeably in
VSP pipelines (provided no more than two inputs are needed).

Due to historical reasons, the VSP1 driver implements support for both
the BRU and BRS through objects named vsp1_bru. The code uses the name
BRU to refer to either the BRU or the BRS, except in a few places where
noted explicitly. This creates confusion.

In an effort to avoid confusion, rename the vsp1_bru object and the
corresponding API to vsp1_brx, and use BRx to refer to blend unit
instances regardless of their type. The names BRU and BRS are retained
where reference to a particular blend unit type is needed, as well as in
hardware registers to stay close to the datasheet.

Signed-off-by: Laurent Pinchart <laurent.pinchart+renesas@ideasonboard.com>
Acked-by: Kieran Bingham <kieran.bingham+renesas@ideasonboard.com>
Signed-off-by: Mauro Carvalho Chehab <mchehab+samsung@kernel.org>
2018-05-04 08:06:29 -04:00

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/*
* vsp1_rpf.c -- R-Car VSP1 Read Pixel Formatter
*
* Copyright (C) 2013-2014 Renesas Electronics Corporation
*
* Contact: Laurent Pinchart (laurent.pinchart@ideasonboard.com)
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*/
#include <linux/device.h>
#include <media/v4l2-subdev.h>
#include "vsp1.h"
#include "vsp1_dl.h"
#include "vsp1_pipe.h"
#include "vsp1_rwpf.h"
#include "vsp1_video.h"
#define RPF_MAX_WIDTH 8190
#define RPF_MAX_HEIGHT 8190
/* -----------------------------------------------------------------------------
* Device Access
*/
static inline void vsp1_rpf_write(struct vsp1_rwpf *rpf,
struct vsp1_dl_list *dl, u32 reg, u32 data)
{
vsp1_dl_list_write(dl, reg + rpf->entity.index * VI6_RPF_OFFSET, data);
}
/* -----------------------------------------------------------------------------
* V4L2 Subdevice Operations
*/
static const struct v4l2_subdev_ops rpf_ops = {
.pad = &vsp1_rwpf_pad_ops,
};
/* -----------------------------------------------------------------------------
* VSP1 Entity Operations
*/
static void rpf_configure(struct vsp1_entity *entity,
struct vsp1_pipeline *pipe,
struct vsp1_dl_list *dl,
enum vsp1_entity_params params)
{
struct vsp1_rwpf *rpf = to_rwpf(&entity->subdev);
const struct vsp1_format_info *fmtinfo = rpf->fmtinfo;
const struct v4l2_pix_format_mplane *format = &rpf->format;
const struct v4l2_mbus_framefmt *source_format;
const struct v4l2_mbus_framefmt *sink_format;
unsigned int left = 0;
unsigned int top = 0;
u32 pstride;
u32 infmt;
if (params == VSP1_ENTITY_PARAMS_RUNTIME) {
vsp1_rpf_write(rpf, dl, VI6_RPF_VRTCOL_SET,
rpf->alpha << VI6_RPF_VRTCOL_SET_LAYA_SHIFT);
vsp1_rpf_write(rpf, dl, VI6_RPF_MULT_ALPHA, rpf->mult_alpha |
(rpf->alpha << VI6_RPF_MULT_ALPHA_RATIO_SHIFT));
vsp1_pipeline_propagate_alpha(pipe, dl, rpf->alpha);
return;
}
if (params == VSP1_ENTITY_PARAMS_PARTITION) {
struct vsp1_device *vsp1 = rpf->entity.vsp1;
struct vsp1_rwpf_memory mem = rpf->mem;
struct v4l2_rect crop;
/*
* Source size and crop offsets.
*
* The crop offsets correspond to the location of the crop
* rectangle top left corner in the plane buffer. Only two
* offsets are needed, as planes 2 and 3 always have identical
* strides.
*/
crop = *vsp1_rwpf_get_crop(rpf, rpf->entity.config);
/*
* Partition Algorithm Control
*
* The partition algorithm can split this frame into multiple
* slices. We must scale our partition window based on the pipe
* configuration to match the destination partition window.
* To achieve this, we adjust our crop to provide a 'sub-crop'
* matching the expected partition window. Only 'left' and
* 'width' need to be adjusted.
*/
if (pipe->partitions > 1) {
crop.width = pipe->partition->rpf.width;
crop.left += pipe->partition->rpf.left;
}
vsp1_rpf_write(rpf, dl, VI6_RPF_SRC_BSIZE,
(crop.width << VI6_RPF_SRC_BSIZE_BHSIZE_SHIFT) |
(crop.height << VI6_RPF_SRC_BSIZE_BVSIZE_SHIFT));
vsp1_rpf_write(rpf, dl, VI6_RPF_SRC_ESIZE,
(crop.width << VI6_RPF_SRC_ESIZE_EHSIZE_SHIFT) |
(crop.height << VI6_RPF_SRC_ESIZE_EVSIZE_SHIFT));
mem.addr[0] += crop.top * format->plane_fmt[0].bytesperline
+ crop.left * fmtinfo->bpp[0] / 8;
if (format->num_planes > 1) {
unsigned int offset;
offset = crop.top * format->plane_fmt[1].bytesperline
+ crop.left / fmtinfo->hsub
* fmtinfo->bpp[1] / 8;
mem.addr[1] += offset;
mem.addr[2] += offset;
}
/*
* On Gen3 hardware the SPUVS bit has no effect on 3-planar
* formats. Swap the U and V planes manually in that case.
*/
if (vsp1->info->gen == 3 && format->num_planes == 3 &&
fmtinfo->swap_uv)
swap(mem.addr[1], mem.addr[2]);
vsp1_rpf_write(rpf, dl, VI6_RPF_SRCM_ADDR_Y, mem.addr[0]);
vsp1_rpf_write(rpf, dl, VI6_RPF_SRCM_ADDR_C0, mem.addr[1]);
vsp1_rpf_write(rpf, dl, VI6_RPF_SRCM_ADDR_C1, mem.addr[2]);
return;
}
/* Stride */
pstride = format->plane_fmt[0].bytesperline
<< VI6_RPF_SRCM_PSTRIDE_Y_SHIFT;
if (format->num_planes > 1)
pstride |= format->plane_fmt[1].bytesperline
<< VI6_RPF_SRCM_PSTRIDE_C_SHIFT;
vsp1_rpf_write(rpf, dl, VI6_RPF_SRCM_PSTRIDE, pstride);
/* Format */
sink_format = vsp1_entity_get_pad_format(&rpf->entity,
rpf->entity.config,
RWPF_PAD_SINK);
source_format = vsp1_entity_get_pad_format(&rpf->entity,
rpf->entity.config,
RWPF_PAD_SOURCE);
infmt = VI6_RPF_INFMT_CIPM
| (fmtinfo->hwfmt << VI6_RPF_INFMT_RDFMT_SHIFT);
if (fmtinfo->swap_yc)
infmt |= VI6_RPF_INFMT_SPYCS;
if (fmtinfo->swap_uv)
infmt |= VI6_RPF_INFMT_SPUVS;
if (sink_format->code != source_format->code)
infmt |= VI6_RPF_INFMT_CSC;
vsp1_rpf_write(rpf, dl, VI6_RPF_INFMT, infmt);
vsp1_rpf_write(rpf, dl, VI6_RPF_DSWAP, fmtinfo->swap);
/* Output location */
if (pipe->brx) {
const struct v4l2_rect *compose;
compose = vsp1_entity_get_pad_selection(pipe->brx,
pipe->brx->config,
rpf->brx_input,
V4L2_SEL_TGT_COMPOSE);
left = compose->left;
top = compose->top;
}
vsp1_rpf_write(rpf, dl, VI6_RPF_LOC,
(left << VI6_RPF_LOC_HCOORD_SHIFT) |
(top << VI6_RPF_LOC_VCOORD_SHIFT));
/*
* On Gen2 use the alpha channel (extended to 8 bits) when available or
* a fixed alpha value set through the V4L2_CID_ALPHA_COMPONENT control
* otherwise.
*
* The Gen3 RPF has extended alpha capability and can both multiply the
* alpha channel by a fixed global alpha value, and multiply the pixel
* components to convert the input to premultiplied alpha.
*
* As alpha premultiplication is available in the BRx for both Gen2 and
* Gen3 we handle it there and use the Gen3 alpha multiplier for global
* alpha multiplication only. This however prevents conversion to
* premultiplied alpha if no BRx is present in the pipeline. If that use
* case turns out to be useful we will revisit the implementation (for
* Gen3 only).
*
* We enable alpha multiplication on Gen3 using the fixed alpha value
* set through the V4L2_CID_ALPHA_COMPONENT control when the input
* contains an alpha channel. On Gen2 the global alpha is ignored in
* that case.
*
* In all cases, disable color keying.
*/
vsp1_rpf_write(rpf, dl, VI6_RPF_ALPH_SEL, VI6_RPF_ALPH_SEL_AEXT_EXT |
(fmtinfo->alpha ? VI6_RPF_ALPH_SEL_ASEL_PACKED
: VI6_RPF_ALPH_SEL_ASEL_FIXED));
if (entity->vsp1->info->gen == 3) {
u32 mult;
if (fmtinfo->alpha) {
/*
* When the input contains an alpha channel enable the
* alpha multiplier. If the input is premultiplied we
* need to multiply both the alpha channel and the pixel
* components by the global alpha value to keep them
* premultiplied. Otherwise multiply the alpha channel
* only.
*/
bool premultiplied = format->flags
& V4L2_PIX_FMT_FLAG_PREMUL_ALPHA;
mult = VI6_RPF_MULT_ALPHA_A_MMD_RATIO
| (premultiplied ?
VI6_RPF_MULT_ALPHA_P_MMD_RATIO :
VI6_RPF_MULT_ALPHA_P_MMD_NONE);
} else {
/*
* When the input doesn't contain an alpha channel the
* global alpha value is applied in the unpacking unit,
* the alpha multiplier isn't needed and must be
* disabled.
*/
mult = VI6_RPF_MULT_ALPHA_A_MMD_NONE
| VI6_RPF_MULT_ALPHA_P_MMD_NONE;
}
rpf->mult_alpha = mult;
}
vsp1_rpf_write(rpf, dl, VI6_RPF_MSK_CTRL, 0);
vsp1_rpf_write(rpf, dl, VI6_RPF_CKEY_CTRL, 0);
}
static void rpf_partition(struct vsp1_entity *entity,
struct vsp1_pipeline *pipe,
struct vsp1_partition *partition,
unsigned int partition_idx,
struct vsp1_partition_window *window)
{
partition->rpf = *window;
}
static const struct vsp1_entity_operations rpf_entity_ops = {
.configure = rpf_configure,
.partition = rpf_partition,
};
/* -----------------------------------------------------------------------------
* Initialization and Cleanup
*/
struct vsp1_rwpf *vsp1_rpf_create(struct vsp1_device *vsp1, unsigned int index)
{
struct vsp1_rwpf *rpf;
char name[6];
int ret;
rpf = devm_kzalloc(vsp1->dev, sizeof(*rpf), GFP_KERNEL);
if (rpf == NULL)
return ERR_PTR(-ENOMEM);
rpf->max_width = RPF_MAX_WIDTH;
rpf->max_height = RPF_MAX_HEIGHT;
rpf->entity.ops = &rpf_entity_ops;
rpf->entity.type = VSP1_ENTITY_RPF;
rpf->entity.index = index;
sprintf(name, "rpf.%u", index);
ret = vsp1_entity_init(vsp1, &rpf->entity, name, 2, &rpf_ops,
MEDIA_ENT_F_PROC_VIDEO_PIXEL_FORMATTER);
if (ret < 0)
return ERR_PTR(ret);
/* Initialize the control handler. */
ret = vsp1_rwpf_init_ctrls(rpf, 0);
if (ret < 0) {
dev_err(vsp1->dev, "rpf%u: failed to initialize controls\n",
index);
goto error;
}
v4l2_ctrl_handler_setup(&rpf->ctrls);
return rpf;
error:
vsp1_entity_destroy(&rpf->entity);
return ERR_PTR(ret);
}
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