FreeRDP/libfreerdp/codec/nsc_encode.c

/**
 * FreeRDP: A Remote Desktop Protocol Implementation
 * NSCodec Encoder
 *
 * Copyright 2012 Vic Lee
 * Copyright 2016 Armin Novak <armin.novak@thincast.com>
 * Copyright 2016 Thincast Technologies GmbH
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

#ifdef HAVE_CONFIG_H
#include "config.h"
#endif

#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#include <winpr/crt.h>

#include <freerdp/codec/nsc.h>
#include <freerdp/codec/color.h>

#include "nsc_types.h"
#include "nsc_encode.h"

struct _NSC_MESSAGE
{
	UINT32 x;
	UINT32 y;
	UINT32 width;
	UINT32 height;
	const BYTE* data;
	UINT32 scanline;
	BYTE* PlaneBuffer;
	UINT32 MaxPlaneSize;
	BYTE* PlaneBuffers[5];
	UINT32 OrgByteCount[4];

	UINT32 LumaPlaneByteCount;
	UINT32 OrangeChromaPlaneByteCount;
	UINT32 GreenChromaPlaneByteCount;
	UINT32 AlphaPlaneByteCount;
	UINT8 ColorLossLevel;
	UINT8 ChromaSubsamplingLevel;
};
typedef struct _NSC_MESSAGE NSC_MESSAGE;

static BOOL nsc_write_message(NSC_CONTEXT* context, wStream* s, const NSC_MESSAGE* message);

static BOOL nsc_context_initialize_encode(NSC_CONTEXT* context)
{
	int i;
	UINT32 length;
	UINT32 tempWidth;
	UINT32 tempHeight;
	tempWidth = ROUND_UP_TO(context->width, 8);
	tempHeight = ROUND_UP_TO(context->height, 2);
	/* The maximum length a decoded plane can reach in all cases */
	length = tempWidth * tempHeight + 16;

	if (length > context->priv->PlaneBuffersLength)
	{
		for (i = 0; i < 5; i++)
		{
			BYTE* tmp = (BYTE*)realloc(context->priv->PlaneBuffers[i], length);

			if (!tmp)
				goto fail;

			context->priv->PlaneBuffers[i] = tmp;
		}

		context->priv->PlaneBuffersLength = length;
	}

	if (context->ChromaSubsamplingLevel)
	{
		context->OrgByteCount[0] = tempWidth * context->height;
		context->OrgByteCount[1] = tempWidth * tempHeight / 4;
		context->OrgByteCount[2] = tempWidth * tempHeight / 4;
		context->OrgByteCount[3] = context->width * context->height;
	}
	else
	{
		context->OrgByteCount[0] = context->width * context->height;
		context->OrgByteCount[1] = context->width * context->height;
		context->OrgByteCount[2] = context->width * context->height;
		context->OrgByteCount[3] = context->width * context->height;
	}

	return TRUE;
fail:

	if (length > context->priv->PlaneBuffersLength)
	{
		for (i = 0; i < 5; i++)
			free(context->priv->PlaneBuffers[i]);
	}

	return FALSE;
}

static BOOL nsc_encode_argb_to_aycocg(NSC_CONTEXT* context, const BYTE* data, UINT32 scanline)
{
	UINT16 x;
	UINT16 y;
	UINT16 rw;
	BYTE ccl;
	const BYTE* src;
	BYTE* yplane = NULL;
	BYTE* coplane = NULL;
	BYTE* cgplane = NULL;
	BYTE* aplane = NULL;
	INT16 r_val;
	INT16 g_val;
	INT16 b_val;
	BYTE a_val;
	UINT32 tempWidth;

	tempWidth = ROUND_UP_TO(context->width, 8);
	rw = (context->ChromaSubsamplingLevel ? tempWidth : context->width);
	ccl = context->ColorLossLevel;

	for (y = 0; y < context->height; y++)
	{
		src = data + (context->height - 1 - y) * scanline;
		yplane = context->priv->PlaneBuffers[0] + y * rw;
		coplane = context->priv->PlaneBuffers[1] + y * rw;
		cgplane = context->priv->PlaneBuffers[2] + y * rw;
		aplane = context->priv->PlaneBuffers[3] + y * context->width;

		for (x = 0; x < context->width; x++)
		{
			switch (context->format)
			{
				case PIXEL_FORMAT_BGRX32:
					b_val = *src++;
					g_val = *src++;
					r_val = *src++;
					src++;
					a_val = 0xFF;
					break;

				case PIXEL_FORMAT_BGRA32:
					b_val = *src++;
					g_val = *src++;
					r_val = *src++;
					a_val = *src++;
					break;

				case PIXEL_FORMAT_RGBX32:
					r_val = *src++;
					g_val = *src++;
					b_val = *src++;
					src++;
					a_val = 0xFF;
					break;

				case PIXEL_FORMAT_RGBA32:
					r_val = *src++;
					g_val = *src++;
					b_val = *src++;
					a_val = *src++;
					break;

				case PIXEL_FORMAT_BGR24:
					b_val = *src++;
					g_val = *src++;
					r_val = *src++;
					a_val = 0xFF;
					break;

				case PIXEL_FORMAT_RGB24:
					r_val = *src++;
					g_val = *src++;
					b_val = *src++;
					a_val = 0xFF;
					break;

				case PIXEL_FORMAT_BGR16:
					b_val = (INT16)(((*(src + 1)) & 0xF8) | ((*(src + 1)) >> 5));
					g_val = (INT16)((((*(src + 1)) & 0x07) << 5) | (((*src) & 0xE0) >> 3));
					r_val = (INT16)((((*src) & 0x1F) << 3) | (((*src) >> 2) & 0x07));
					a_val = 0xFF;
					src += 2;
					break;

				case PIXEL_FORMAT_RGB16:
					r_val = (INT16)(((*(src + 1)) & 0xF8) | ((*(src + 1)) >> 5));
					g_val = (INT16)((((*(src + 1)) & 0x07) << 5) | (((*src) & 0xE0) >> 3));
					b_val = (INT16)((((*src) & 0x1F) << 3) | (((*src) >> 2) & 0x07));
					a_val = 0xFF;
					src += 2;
					break;

				case PIXEL_FORMAT_A4:
				{
					int shift;
					BYTE idx;
					shift = (7 - (x % 8));
					idx = ((*src) >> shift) & 1;
					idx |= (((*(src + 1)) >> shift) & 1) << 1;
					idx |= (((*(src + 2)) >> shift) & 1) << 2;
					idx |= (((*(src + 3)) >> shift) & 1) << 3;
					idx *= 3;
					r_val = (INT16)context->palette[idx];
					g_val = (INT16)context->palette[idx + 1];
					b_val = (INT16)context->palette[idx + 2];

					if (shift == 0)
						src += 4;
				}

					a_val = 0xFF;
					break;

				case PIXEL_FORMAT_RGB8:
				{
					int idx = (*src) * 3;
					r_val = (INT16)context->palette[idx];
					g_val = (INT16)context->palette[idx + 1];
					b_val = (INT16)context->palette[idx + 2];
					src++;
				}

					a_val = 0xFF;
					break;

				default:
					r_val = g_val = b_val = a_val = 0;
					break;
			}

			*yplane++ = (BYTE)((r_val >> 2) + (g_val >> 1) + (b_val >> 2));
			/* Perform color loss reduction here */
			*coplane++ = (BYTE)((r_val - b_val) >> ccl);
			*cgplane++ = (BYTE)((-(r_val >> 1) + g_val - (b_val >> 1)) >> ccl);
			*aplane++ = a_val;
		}

		if (context->ChromaSubsamplingLevel && (x % 2) == 1)
		{
			*yplane = *(yplane - 1);
			*coplane = *(coplane - 1);
			*cgplane = *(cgplane - 1);
		}
	}

	if (context->ChromaSubsamplingLevel && (y % 2) == 1)
	{
		yplane = context->priv->PlaneBuffers[0] + y * rw;
		coplane = context->priv->PlaneBuffers[1] + y * rw;
		cgplane = context->priv->PlaneBuffers[2] + y * rw;
		CopyMemory(yplane, yplane - rw, rw);
		CopyMemory(coplane, coplane - rw, rw);
		CopyMemory(cgplane, cgplane - rw, rw);
	}

	return TRUE;
}

static BOOL nsc_encode_subsampling(NSC_CONTEXT* context)
{
	UINT32 y;
	UINT32 tempWidth;
	UINT32 tempHeight;

	if (!context)
		return FALSE;

	tempWidth = ROUND_UP_TO(context->width, 8);
	tempHeight = ROUND_UP_TO(context->height, 2);

	if (tempHeight == 0)
		return FALSE;

	if (tempWidth > context->priv->PlaneBuffersLength / tempHeight)
		return FALSE;

	for (y = 0; y<tempHeight>> 1; y++)
	{
		UINT32 x;
		BYTE* co_dst = context->priv->PlaneBuffers[1] + y * (tempWidth >> 1);
		BYTE* cg_dst = context->priv->PlaneBuffers[2] + y * (tempWidth >> 1);
		const INT8* co_src0 = (INT8*)context->priv->PlaneBuffers[1] + (y << 1) * tempWidth;
		const INT8* co_src1 = co_src0 + tempWidth;
		const INT8* cg_src0 = (INT8*)context->priv->PlaneBuffers[2] + (y << 1) * tempWidth;
		const INT8* cg_src1 = cg_src0 + tempWidth;

		for (x = 0; x<tempWidth>> 1; x++)
		{
			*co_dst++ = (BYTE)(((INT16)*co_src0 + (INT16) * (co_src0 + 1) + (INT16)*co_src1 +
			                    (INT16) * (co_src1 + 1)) >>
			                   2);
			*cg_dst++ = (BYTE)(((INT16)*cg_src0 + (INT16) * (cg_src0 + 1) + (INT16)*cg_src1 +
			                    (INT16) * (cg_src1 + 1)) >>
			                   2);
			co_src0 += 2;
			co_src1 += 2;
			cg_src0 += 2;
			cg_src1 += 2;
		}
	}

	return TRUE;
}

BOOL nsc_encode(NSC_CONTEXT* context, const BYTE* bmpdata, UINT32 rowstride)
{
	if (!context || !bmpdata || (rowstride == 0))
		return FALSE;

	if (!nsc_encode_argb_to_aycocg(context, bmpdata, rowstride))
		return FALSE;

	if (context->ChromaSubsamplingLevel)
	{
		if (!nsc_encode_subsampling(context))
			return FALSE;
	}

	return TRUE;
}

static UINT32 nsc_rle_encode(const BYTE* in, BYTE* out, UINT32 originalSize)
{
	UINT32 left;
	UINT32 runlength = 1;
	UINT32 planeSize = 0;
	left = originalSize;

	/**
	 * We quit the loop if the running compressed size is larger than the original.
	 * In such cases data will be sent uncompressed.
	 */
	while (left > 4 && planeSize < originalSize - 4)
	{
		if (left > 5 && *in == *(in + 1))
		{
			runlength++;
		}
		else if (runlength == 1)
		{
			*out++ = *in;
			planeSize++;
		}
		else if (runlength < 256)
		{
			*out++ = *in;
			*out++ = *in;
			*out++ = runlength - 2;
			runlength = 1;
			planeSize += 3;
		}
		else
		{
			*out++ = *in;
			*out++ = *in;
			*out++ = 0xFF;
			*out++ = (runlength & 0x000000FF);
			*out++ = (runlength & 0x0000FF00) >> 8;
			*out++ = (runlength & 0x00FF0000) >> 16;
			*out++ = (runlength & 0xFF000000) >> 24;
			runlength = 1;
			planeSize += 7;
		}

		in++;
		left--;
	}

	if (planeSize < originalSize - 4)
		CopyMemory(out, in, 4);

	planeSize += 4;
	return planeSize;
}

static void nsc_rle_compress_data(NSC_CONTEXT* context)
{
	UINT16 i;
	UINT32 planeSize;
	UINT32 originalSize;

	for (i = 0; i < 4; i++)
	{
		originalSize = context->OrgByteCount[i];

		if (originalSize == 0)
		{
			planeSize = 0;
		}
		else
		{
			planeSize = nsc_rle_encode(context->priv->PlaneBuffers[i],
			                           context->priv->PlaneBuffers[4], originalSize);

			if (planeSize < originalSize)
				CopyMemory(context->priv->PlaneBuffers[i], context->priv->PlaneBuffers[4],
				           planeSize);
			else
				planeSize = originalSize;
		}

		context->PlaneByteCount[i] = planeSize;
	}
}

static UINT32 nsc_compute_byte_count(NSC_CONTEXT* context, UINT32* ByteCount, UINT32 width,
                                     UINT32 height)
{
	UINT32 tempWidth;
	UINT32 tempHeight;
	UINT32 maxPlaneSize;
	tempWidth = ROUND_UP_TO(width, 8);
	tempHeight = ROUND_UP_TO(height, 2);
	maxPlaneSize = tempWidth * tempHeight + 16;

	if (context->ChromaSubsamplingLevel)
	{
		ByteCount[0] = tempWidth * height;
		ByteCount[1] = tempWidth * tempHeight / 4;
		ByteCount[2] = tempWidth * tempHeight / 4;
		ByteCount[3] = width * height;
	}
	else
	{
		ByteCount[0] = width * height;
		ByteCount[1] = width * height;
		ByteCount[2] = width * height;
		ByteCount[3] = width * height;
	}

	return maxPlaneSize;
}

BOOL nsc_write_message(NSC_CONTEXT* context, wStream* s, const NSC_MESSAGE* message)
{
	UINT32 totalPlaneByteCount;
	totalPlaneByteCount = message->LumaPlaneByteCount + message->OrangeChromaPlaneByteCount +
	                      message->GreenChromaPlaneByteCount + message->AlphaPlaneByteCount;

	if (!Stream_EnsureRemainingCapacity(s, 20 + totalPlaneByteCount))
		return FALSE;

	Stream_Write_UINT32(s, message->LumaPlaneByteCount); /* LumaPlaneByteCount (4 bytes) */
	Stream_Write_UINT32(
	    s, message->OrangeChromaPlaneByteCount); /* OrangeChromaPlaneByteCount (4 bytes) */
	Stream_Write_UINT32(
	    s, message->GreenChromaPlaneByteCount);           /* GreenChromaPlaneByteCount (4 bytes) */
	Stream_Write_UINT32(s, message->AlphaPlaneByteCount); /* AlphaPlaneByteCount (4 bytes) */
	Stream_Write_UINT8(s, message->ColorLossLevel);       /* ColorLossLevel (1 byte) */
	Stream_Write_UINT8(s, message->ChromaSubsamplingLevel); /* ChromaSubsamplingLevel (1 byte) */
	Stream_Write_UINT16(s, 0);                              /* Reserved (2 bytes) */

	if (message->LumaPlaneByteCount)
		Stream_Write(s, message->PlaneBuffers[0], message->LumaPlaneByteCount); /* LumaPlane */

	if (message->OrangeChromaPlaneByteCount)
		Stream_Write(s, message->PlaneBuffers[1],
		             message->OrangeChromaPlaneByteCount); /* OrangeChromaPlane */

	if (message->GreenChromaPlaneByteCount)
		Stream_Write(s, message->PlaneBuffers[2],
		             message->GreenChromaPlaneByteCount); /* GreenChromaPlane */

	if (message->AlphaPlaneByteCount)
		Stream_Write(s, message->PlaneBuffers[3], message->AlphaPlaneByteCount); /* AlphaPlane */

	return TRUE;
}

BOOL nsc_compose_message(NSC_CONTEXT* context, wStream* s, const BYTE* data, UINT32 width,
                         UINT32 height, UINT32 scanline)
{
	BOOL rc;
	NSC_MESSAGE message = { 0 };

	if (!context || !s || !data)
		return FALSE;

	context->width = width;
	context->height = height;

	if (!nsc_context_initialize_encode(context))
		return FALSE;

	/* ARGB to AYCoCg conversion, chroma subsampling and colorloss reduction */
	PROFILER_ENTER(context->priv->prof_nsc_encode)
	rc = context->encode(context, data, scanline);
	PROFILER_EXIT(context->priv->prof_nsc_encode)
	if (!rc)
		return FALSE;

	/* RLE encode */
	PROFILER_ENTER(context->priv->prof_nsc_rle_compress_data)
	nsc_rle_compress_data(context);
	PROFILER_EXIT(context->priv->prof_nsc_rle_compress_data)
	message.PlaneBuffers[0] = context->priv->PlaneBuffers[0];
	message.PlaneBuffers[1] = context->priv->PlaneBuffers[1];
	message.PlaneBuffers[2] = context->priv->PlaneBuffers[2];
	message.PlaneBuffers[3] = context->priv->PlaneBuffers[3];
	message.LumaPlaneByteCount = context->PlaneByteCount[0];
	message.OrangeChromaPlaneByteCount = context->PlaneByteCount[1];
	message.GreenChromaPlaneByteCount = context->PlaneByteCount[2];
	message.AlphaPlaneByteCount = context->PlaneByteCount[3];
	message.ColorLossLevel = context->ColorLossLevel;
	message.ChromaSubsamplingLevel = context->ChromaSubsamplingLevel;
	return nsc_write_message(context, s, &message);
}

BOOL nsc_decompose_message(NSC_CONTEXT* context, wStream* s, BYTE* bmpdata, UINT32 x, UINT32 y,
                           UINT32 width, UINT32 height, UINT32 rowstride, UINT32 format,
                           UINT32 flip)
{
	size_t size = Stream_GetRemainingLength(s);
	if (size > UINT32_MAX)
		return FALSE;

	if (!nsc_process_message(context, (UINT16)GetBitsPerPixel(context->format), width, height,
	                         Stream_Pointer(s), (UINT32)size, bmpdata, format, rowstride, x, y,
	                         width, height, flip))
		return FALSE;
	Stream_Seek(s, size);
	return TRUE;
}