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Commit 5c0ed8cd authored by Kristina Martšenko's avatar Kristina Martšenko Committed by Greg Kroah-Hartman
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staging: crystalhd: remove driver 

The driver hasn't had significant work done on it for a long time.
Broadcom has EOLed the hardware and is no longer selling it. There are
probably very few people still using it. So remove the driver.
Signed-off-by: default avatarKristina Martšenko <kristina.martsenko@gmail.com>
Cc: Naren Sankar <nsankar@broadcom.com>
Cc: Jarod Wilson <jarod@wilsonet.com>
Cc: Scott Davilla <davilla@4pi.com>
Cc: Manu Abraham <abraham.manu@gmail.com>
Signed-off-by: default avatarGreg Kroah-Hartman <gregkh@linuxfoundation.org>
parent 895ae876
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MAINTAINERS
View file @ 5c0ed8cd
...@@ -8512,14 +8512,6 @@ M: H Hartley Sweeten <hsweeten@visionengravers.com> ...@@ -8512,14 +8512,6 @@ M: H Hartley Sweeten <hsweeten@visionengravers.com>
S: Odd Fixes S: Odd Fixes
F: drivers/staging/comedi/ F: drivers/staging/comedi/
STAGING - CRYSTAL HD VIDEO DECODER
M: Naren Sankar <nsankar@broadcom.com>
M: Jarod Wilson <jarod@wilsonet.com>
M: Scott Davilla <davilla@4pi.com>
M: Manu Abraham <abraham.manu@gmail.com>
S: Odd Fixes
F: drivers/staging/crystalhd/
STAGING - ECHO CANCELLER STAGING - ECHO CANCELLER
M: Steve Underwood <steveu@coppice.org> M: Steve Underwood <steveu@coppice.org>
M: David Rowe <david@rowetel.com> M: David Rowe <david@rowetel.com>
......
drivers/staging/Kconfig
View file @ 5c0ed8cd
...@@ -80,8 +80,6 @@ source "drivers/staging/wlags49_h2/Kconfig" ...@@ -80,8 +80,6 @@ source "drivers/staging/wlags49_h2/Kconfig"
source "drivers/staging/wlags49_h25/Kconfig" source "drivers/staging/wlags49_h25/Kconfig"
source "drivers/staging/crystalhd/Kconfig"
source "drivers/staging/cxt1e1/Kconfig" source "drivers/staging/cxt1e1/Kconfig"
source "drivers/staging/xgifb/Kconfig" source "drivers/staging/xgifb/Kconfig"
......
drivers/staging/Makefile
View file @ 5c0ed8cd
...@@ -34,7 +34,6 @@ obj-$(CONFIG_DX_SEP) += sep/ ...@@ -34,7 +34,6 @@ obj-$(CONFIG_DX_SEP) += sep/
obj-$(CONFIG_IIO) += iio/ obj-$(CONFIG_IIO) += iio/
obj-$(CONFIG_WLAGS49_H2) += wlags49_h2/ obj-$(CONFIG_WLAGS49_H2) += wlags49_h2/
obj-$(CONFIG_WLAGS49_H25) += wlags49_h25/ obj-$(CONFIG_WLAGS49_H25) += wlags49_h25/
obj-$(CONFIG_CRYSTALHD) += crystalhd/
obj-$(CONFIG_CXT1E1) += cxt1e1/ obj-$(CONFIG_CXT1E1) += cxt1e1/
obj-$(CONFIG_FB_XGI) += xgifb/ obj-$(CONFIG_FB_XGI) += xgifb/
obj-$(CONFIG_TIDSPBRIDGE) += tidspbridge/ obj-$(CONFIG_TIDSPBRIDGE) += tidspbridge/
......
drivers/staging/crystalhd/Kconfig deleted 100644 → 0
View file @ 895ae876
config CRYSTALHD
tristate "Broadcom Crystal HD video decoder support"
depends on PCI
default n
help
Support for the Broadcom Crystal HD video decoder chipset
drivers/staging/crystalhd/Makefile deleted 100644 → 0
View file @ 895ae876
obj-$(CONFIG_CRYSTALHD) += crystalhd.o
crystalhd-y := crystalhd_cmds.o \
crystalhd_hw.o \
crystalhd_lnx.o \
crystalhd_misc.o
drivers/staging/crystalhd/TODO deleted 100644 → 0
View file @ 895ae876
- Testing
- Cleanup return codes
- Cleanup typedefs
- Allocate an Accelerator device class specific Major number,
since we don't have any other open sourced accelerators, it is the only
one in that category for now.
A somewhat similar device is the DXR2/3
Please send patches to:
Greg Kroah-Hartman <greg@kroah.com>
Naren Sankar <nsankar@broadcom.com>
Jarod Wilson <jarod@wilsonet.com>
Scott Davilla <davilla@4pi.com>
Manu Abraham <abraham.manu@gmail.com>
drivers/staging/crystalhd/bc_dts_defs.h deleted 100644 → 0
View file @ 895ae876
/********************************************************************
* Copyright(c) 2006-2009 Broadcom Corporation.
*
* Name: bc_dts_defs.h
*
* Description: Common definitions for all components. Only types
* is allowed to be included from this file.
*
* AU
*
* HISTORY:
*
********************************************************************
* This header is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as published
* by the Free Software Foundation, either version 2.1 of the License.
*
* This header is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
* You should have received a copy of the GNU Lesser General Public License
* along with this header. If not, see <http://www.gnu.org/licenses/>.
*******************************************************************/
#ifndef _BC_DTS_DEFS_H_
#define _BC_DTS_DEFS_H_
#include <linux/types.h>
/* BIT Mask */
#define BC_BIT(_x) (1 << (_x))
enum BC_STATUS {
BC_STS_SUCCESS = 0,
BC_STS_INV_ARG = 1,
BC_STS_BUSY = 2,
BC_STS_NOT_IMPL = 3,
BC_STS_PGM_QUIT = 4,
BC_STS_NO_ACCESS = 5,
BC_STS_INSUFF_RES = 6,
BC_STS_IO_ERROR = 7,
BC_STS_NO_DATA = 8,
BC_STS_VER_MISMATCH = 9,
BC_STS_TIMEOUT = 10,
BC_STS_FW_CMD_ERR = 11,
BC_STS_DEC_NOT_OPEN = 12,
BC_STS_ERR_USAGE = 13,
BC_STS_IO_USER_ABORT = 14,
BC_STS_IO_XFR_ERROR = 15,
BC_STS_DEC_NOT_STARTED = 16,
BC_STS_FWHEX_NOT_FOUND = 17,
BC_STS_FMT_CHANGE = 18,
BC_STS_HIF_ACCESS = 19,
BC_STS_CMD_CANCELLED = 20,
BC_STS_FW_AUTH_FAILED = 21,
BC_STS_BOOTLOADER_FAILED = 22,
BC_STS_CERT_VERIFY_ERROR = 23,
BC_STS_DEC_EXIST_OPEN = 24,
BC_STS_PENDING = 25,
BC_STS_CLK_NOCHG = 26,
/* Must be the last one.*/
BC_STS_ERROR = -1
};
/*------------------------------------------------------*
* Registry Key Definitions *
*------------------------------------------------------*/
#define BC_REG_KEY_MAIN_PATH "Software\\Broadcom\\MediaPC\\70010"
#define BC_REG_KEY_FWPATH "FirmwareFilePath"
#define BC_REG_KEY_SEC_OPT "DbgOptions"
/*
* Options:
*
* b[5] = Enable RSA KEY in EEPROM Support
* b[6] = Enable Old PIB scheme. (0 = Use PIB with video scheme)
*
* b[12] = Enable send message to NotifyIcon
*
*/
enum BC_SW_OPTIONS {
BC_OPT_DOSER_OUT_ENCRYPT = BC_BIT(3),
BC_OPT_LINK_OUT_ENCRYPT = BC_BIT(29),
};
struct BC_REG_CONFIG {
uint32_t DbgOptions;
};
#if defined(__KERNEL__) || defined(__LINUX_USER__)
#else
/* Align data structures */
#define ALIGN(x) __declspec(align(x))
#endif
/* mode
* b[0]..b[7] = _DtsDeviceOpenMode
* b[8] = Load new FW
* b[9] = Load file play back FW
* b[10] = Disk format (0 for HD DVD and 1 for BLU ray)
* b[11]-b[15] = default output resolution
* b[16] = Skip TX CPB Buffer Check
* b[17] = Adaptive Output Encrypt/Scramble Scheme
* b[18]-b[31] = reserved for future use
*/
/* To allow multiple apps to open the device. */
enum DtsDeviceOpenMode {
DTS_PLAYBACK_MODE = 0,
DTS_DIAG_MODE,
DTS_MONITOR_MODE,
DTS_HWINIT_MODE
};
/* To enable the filter to selectively enable/disable fixes or erratas */
enum DtsDeviceFixMode {
DTS_LOAD_NEW_FW = BC_BIT(8),
DTS_LOAD_FILE_PLAY_FW = BC_BIT(9),
DTS_DISK_FMT_BD = BC_BIT(10),
/* b[11]-b[15] : Default output resolution */
DTS_SKIP_TX_CHK_CPB = BC_BIT(16),
DTS_ADAPTIVE_OUTPUT_PER = BC_BIT(17),
DTS_INTELLIMAP = BC_BIT(18),
/* b[19]-b[21] : select clock frequency */
DTS_PLAYBACK_DROP_RPT_MODE = BC_BIT(22)
};
#define DTS_DFLT_RESOLUTION(x) (x<<11)
#define DTS_DFLT_CLOCK(x) (x<<19)
/* F/W File Version corresponding to S/W Releases */
enum FW_FILE_VER {
/* S/W release: 02.04.02 F/W release 2.12.2.0 */
BC_FW_VER_020402 = ((12<<16) | (2<<8) | (0))
};
/*------------------------------------------------------*
* Stream Types for DtsOpenDecoder() *
*------------------------------------------------------*/
enum DtsOpenDecStreamTypes {
BC_STREAM_TYPE_ES = 0,
BC_STREAM_TYPE_PES = 1,
BC_STREAM_TYPE_TS = 2,
BC_STREAM_TYPE_ES_TSTAMP = 6,
};
/*------------------------------------------------------*
* Video Algorithms for DtsSetVideoParams() *
*------------------------------------------------------*/
enum DtsSetVideoParamsAlgo {
BC_VID_ALGO_H264 = 0,
BC_VID_ALGO_MPEG2 = 1,
BC_VID_ALGO_VC1 = 4,
BC_VID_ALGO_VC1MP = 7,
};
/*------------------------------------------------------*
* MPEG Extension to the PPB *
*------------------------------------------------------*/
#define BC_MPEG_VALID_PANSCAN (1)
struct BC_PIB_EXT_MPEG {
uint32_t valid;
/* Always valid, defaults to picture size if no
* sequence display extension in the stream. */
uint32_t display_horizontal_size;
uint32_t display_vertical_size;
/* MPEG_VALID_PANSCAN
* Offsets are a copy values from the MPEG stream. */
uint32_t offset_count;
int32_t horizontal_offset[3];
int32_t vertical_offset[3];
};
/*------------------------------------------------------*
* H.264 Extension to the PPB *
*------------------------------------------------------*/
/* Bit definitions for 'other.h264.valid' field */
#define H264_VALID_PANSCAN (1)
#define H264_VALID_SPS_CROP (2)
#define H264_VALID_VUI (4)
struct BC_PIB_EXT_H264 {
/* 'valid' specifies which fields (or sets of
* fields) below are valid. If the corresponding
* bit in 'valid' is NOT set then that field(s)
* is (are) not initialized. */
uint32_t valid;
/* H264_VALID_PANSCAN */
uint32_t pan_scan_count;
int32_t pan_scan_left[3];
int32_t pan_scan_right[3];
int32_t pan_scan_top[3];
int32_t pan_scan_bottom[3];
/* H264_VALID_SPS_CROP */
int32_t sps_crop_left;
int32_t sps_crop_right;
int32_t sps_crop_top;
int32_t sps_crop_bottom;
/* H264_VALID_VUI */
uint32_t chroma_top;
uint32_t chroma_bottom;
};
/*------------------------------------------------------*
* VC1 Extension to the PPB *
*------------------------------------------------------*/
#define VC1_VALID_PANSCAN (1)
struct BC_PIB_EXT_VC1 {
uint32_t valid;
/* Always valid, defaults to picture size if no
* sequence display extension in the stream. */
uint32_t display_horizontal_size;
uint32_t display_vertical_size;
/* VC1 pan scan windows */
uint32_t num_panscan_windows;
int32_t ps_horiz_offset[4];
int32_t ps_vert_offset[4];
int32_t ps_width[4];
int32_t ps_height[4];
};
/*------------------------------------------------------*
* Picture Information Block *
*------------------------------------------------------*/
#if defined(__LINUX_USER__)
/* Values for 'pulldown' field. '0' means no pulldown information
* was present for this picture. */
enum {
vdecNoPulldownInfo = 0,
vdecTop = 1,
vdecBottom = 2,
vdecTopBottom = 3,
vdecBottomTop = 4,
vdecTopBottomTop = 5,
vdecBottomTopBottom = 6,
vdecFrame_X2 = 7,
vdecFrame_X3 = 8,
vdecFrame_X1 = 9,
vdecFrame_X4 = 10,
};
/* Values for the 'frame_rate' field. */
enum {
vdecFrameRateUnknown = 0,
vdecFrameRate23_97,
vdecFrameRate24,
vdecFrameRate25,
vdecFrameRate29_97,
vdecFrameRate30,
vdecFrameRate50,
vdecFrameRate59_94,
vdecFrameRate60,
};
/* Values for the 'aspect_ratio' field. */
enum {
vdecAspectRatioUnknown = 0,
vdecAspectRatioSquare,
vdecAspectRatio12_11,
vdecAspectRatio10_11,
vdecAspectRatio16_11,
vdecAspectRatio40_33,
vdecAspectRatio24_11,
vdecAspectRatio20_11,
vdecAspectRatio32_11,
vdecAspectRatio80_33,
vdecAspectRatio18_11,
vdecAspectRatio15_11,
vdecAspectRatio64_33,
vdecAspectRatio160_99,
vdecAspectRatio4_3,
vdecAspectRatio16_9,
vdecAspectRatio221_1,
vdecAspectRatioOther = 255,
};
/* Values for the 'colour_primaries' field. */
enum {
vdecColourPrimariesUnknown = 0,
vdecColourPrimariesBT709,
vdecColourPrimariesUnspecified,
vdecColourPrimariesReserved,
vdecColourPrimariesBT470_2M = 4,
vdecColourPrimariesBT470_2BG,
vdecColourPrimariesSMPTE170M,
vdecColourPrimariesSMPTE240M,
vdecColourPrimariesGenericFilm,
};
/**
* @vdecRESOLUTION_CUSTOM: custom
* @vdecRESOLUTION_480i: 480i
* @vdecRESOLUTION_1080i: 1080i (1920x1080, 60i)
* @vdecRESOLUTION_NTSC: NTSC (720x483, 60i)
* @vdecRESOLUTION_480p: 480p (720x480, 60p)
* @vdecRESOLUTION_720p: 720p (1280x720, 60p)
* @vdecRESOLUTION_PAL1: PAL_1 (720x576, 50i)
* @vdecRESOLUTION_1080i25: 1080i25 (1920x1080, 50i)
* @vdecRESOLUTION_720p50: 720p50 (1280x720, 50p)
* @vdecRESOLUTION_576p: 576p (720x576, 50p)
* @vdecRESOLUTION_1080i29_97: 1080i (1920x1080, 59.94i)
* @vdecRESOLUTION_720p59_94: 720p (1280x720, 59.94p)
* @vdecRESOLUTION_SD_DVD: SD DVD (720x483, 60i)
* @vdecRESOLUTION_480p656: 480p (720x480, 60p),
* output bus width 8 bit, clock 74.25MHz
* @vdecRESOLUTION_1080p23_976: 1080p23_976 (1920x1080, 23.976p)
* @vdecRESOLUTION_720p23_976: 720p23_976 (1280x720p, 23.976p)
* @vdecRESOLUTION_240p29_97: 240p (1440x240, 29.97p )
* @vdecRESOLUTION_240p30: 240p (1440x240, 30p)
* @vdecRESOLUTION_288p25: 288p (1440x288p, 25p)
* @vdecRESOLUTION_1080p29_97: 1080p29_97 (1920x1080, 29.97p)
* @vdecRESOLUTION_1080p30: 1080p30 (1920x1080, 30p)
* @vdecRESOLUTION_1080p24: 1080p24 (1920x1080, 24p)
* @vdecRESOLUTION_1080p25: 1080p25 (1920x1080, 25p)
* @vdecRESOLUTION_720p24: 720p24 (1280x720, 25p)
* @vdecRESOLUTION_720p29_97: 720p29.97 (1280x720, 29.97p)
* @vdecRESOLUTION_480p23_976: 480p23.976 (720*480, 23.976)
* @vdecRESOLUTION_480p29_97: 480p29.976 (720*480, 29.97p)
* @vdecRESOLUTION_576p25: 576p25 (720*576, 25p)
* @vdecRESOLUTION_480p0: 480p (720x480, 0p)
* @vdecRESOLUTION_480i0: 480i (720x480, 0i)
* @vdecRESOLUTION_576p0: 576p (720x576, 0p)
* @vdecRESOLUTION_720p0: 720p (1280x720, 0p)
* @vdecRESOLUTION_1080p0: 1080p (1920x1080, 0p)
* @vdecRESOLUTION_1080i0: 1080i (1920x1080, 0i)
*/
enum {
vdecRESOLUTION_CUSTOM = 0x00000000,
vdecRESOLUTION_480i = 0x00000001,
vdecRESOLUTION_1080i = 0x00000002,
vdecRESOLUTION_NTSC = 0x00000003,
vdecRESOLUTION_480p = 0x00000004,
vdecRESOLUTION_720p = 0x00000005,
vdecRESOLUTION_PAL1 = 0x00000006,
vdecRESOLUTION_1080i25 = 0x00000007,
vdecRESOLUTION_720p50 = 0x00000008,
vdecRESOLUTION_576p = 0x00000009,
vdecRESOLUTION_1080i29_97 = 0x0000000A,
vdecRESOLUTION_720p59_94 = 0x0000000B,
vdecRESOLUTION_SD_DVD = 0x0000000C,
vdecRESOLUTION_480p656 = 0x0000000D,
vdecRESOLUTION_1080p23_976 = 0x0000000E,
vdecRESOLUTION_720p23_976 = 0x0000000F,
vdecRESOLUTION_240p29_97 = 0x00000010,
vdecRESOLUTION_240p30 = 0x00000011,
vdecRESOLUTION_288p25 = 0x00000012,
vdecRESOLUTION_1080p29_97 = 0x00000013,
vdecRESOLUTION_1080p30 = 0x00000014,
vdecRESOLUTION_1080p24 = 0x00000015,
vdecRESOLUTION_1080p25 = 0x00000016,
vdecRESOLUTION_720p24 = 0x00000017,
vdecRESOLUTION_720p29_97 = 0x00000018,
vdecRESOLUTION_480p23_976 = 0x00000019,
vdecRESOLUTION_480p29_97 = 0x0000001A,
vdecRESOLUTION_576p25 = 0x0000001B,
/* For Zero Frame Rate */
vdecRESOLUTION_480p0 = 0x0000001C,
vdecRESOLUTION_480i0 = 0x0000001D,
vdecRESOLUTION_576p0 = 0x0000001E,
vdecRESOLUTION_720p0 = 0x0000001F,
vdecRESOLUTION_1080p0 = 0x00000020,
vdecRESOLUTION_1080i0 = 0x00000021,
};
/* Bit definitions for 'flags' field */
#define VDEC_FLAG_EOS (0x0004)
#define VDEC_FLAG_FRAME (0x0000)
#define VDEC_FLAG_FIELDPAIR (0x0008)
#define VDEC_FLAG_TOPFIELD (0x0010)
#define VDEC_FLAG_BOTTOMFIELD (0x0018)
#define VDEC_FLAG_PROGRESSIVE_SRC (0x0000)
#define VDEC_FLAG_INTERLACED_SRC (0x0020)
#define VDEC_FLAG_UNKNOWN_SRC (0x0040)
#define VDEC_FLAG_BOTTOM_FIRST (0x0080)
#define VDEC_FLAG_LAST_PICTURE (0x0100)
#define VDEC_FLAG_PICTURE_META_DATA_PRESENT (0x40000)
#endif /* __LINUX_USER__ */
enum _BC_OUTPUT_FORMAT {
MODE420 = 0x0,
MODE422_YUY2 = 0x1,
MODE422_UYVY = 0x2,
};
/**
* struct BC_PIC_INFO_BLOCK
* @timeStam;: Timestamp
* @picture_number: Ordinal display number
* @width: pixels
* @height: pixels
* @chroma_format: 0x420, 0x422 or 0x444
* @n_drop;: number of non-reference frames
* remaining to be dropped
*/
struct BC_PIC_INFO_BLOCK {
/* Common fields. */
uint64_t timeStamp;
uint32_t picture_number;
uint32_t width;
uint32_t height;
uint32_t chroma_format;
uint32_t pulldown;
uint32_t flags;
uint32_t frame_rate;
uint32_t aspect_ratio;
uint32_t colour_primaries;
uint32_t picture_meta_payload;
uint32_t sess_num;
uint32_t ycom;
uint32_t custom_aspect_ratio_width_height;
uint32_t n_drop; /* number of non-reference frames
remaining to be dropped */
/* Protocol-specific extensions. */
union {
struct BC_PIB_EXT_H264 h264;
struct BC_PIB_EXT_MPEG mpeg;
struct BC_PIB_EXT_VC1 vc1;
} other;
};
/*------------------------------------------------------*
* ProcOut Info *
*------------------------------------------------------*/
/**
* enum POUT_OPTIONAL_IN_FLAGS - Optional flags for ProcOut Interface.
* @BC_POUT_FLAGS_YV12: Copy Data in YV12 format
* @BC_POUT_FLAGS_STRIDE: Stride size is valid.
* @BC_POUT_FLAGS_SIZE: Take size information from Application
* @BC_POUT_FLAGS_INTERLACED: copy only half the bytes
* @BC_POUT_FLAGS_INTERLEAVED: interleaved frame
* @: * @BC_POUT_FLAGS_FMT_CHANGE: Data is not VALID when this flag is set
* @BC_POUT_FLAGS_PIB_VALID: PIB Information valid
* @BC_POUT_FLAGS_ENCRYPTED: Data is encrypted.
* @BC_POUT_FLAGS_FLD_BOT: Bottom Field data
*/
enum POUT_OPTIONAL_IN_FLAGS_ {
/* Flags from App to Device */
BC_POUT_FLAGS_YV12 = 0x01,
BC_POUT_FLAGS_STRIDE = 0x02,
BC_POUT_FLAGS_SIZE = 0x04,
BC_POUT_FLAGS_INTERLACED = 0x08,
BC_POUT_FLAGS_INTERLEAVED = 0x10,
/* Flags from Device to APP */
BC_POUT_FLAGS_FMT_CHANGE = 0x10000,
BC_POUT_FLAGS_PIB_VALID = 0x20000,
BC_POUT_FLAGS_ENCRYPTED = 0x40000,
BC_POUT_FLAGS_FLD_BOT = 0x80000,
};
typedef enum BC_STATUS(*dts_pout_callback)(void *shnd, uint32_t width,
uint32_t height, uint32_t stride, void *pOut);
/* Line 21 Closed Caption */
/* User Data */
#define MAX_UD_SIZE 1792 /* 1920 - 128 */
/**
* struct BC_DTS_PROC_OUT
* @Ybuff: Caller Supplied buffer for Y data
* @YbuffSz: Caller Supplied Y buffer size
* @YBuffDoneSz: Transferred Y datasize
* @*UVbuff: Caller Supplied buffer for UV data
* @UVbuffSz: Caller Supplied UV buffer size
* @UVBuffDoneSz: Transferred UV data size
* @StrideSz: Caller supplied Stride Size
* @PoutFlags: Call IN Flags
* @discCnt: Picture discontinuity count
* @PicInfo: Picture Information Block Data
* @b422Mode: Picture output Mode
* @bPibEnc: PIB encrypted
*/
struct BC_DTS_PROC_OUT {
uint8_t *Ybuff;
uint32_t YbuffSz;
uint32_t YBuffDoneSz;
uint8_t *UVbuff;
uint32_t UVbuffSz;
uint32_t UVBuffDoneSz;
uint32_t StrideSz;
uint32_t PoutFlags;
uint32_t discCnt;
struct BC_PIC_INFO_BLOCK PicInfo;
/* Line 21 Closed Caption */
/* User Data */
uint32_t UserDataSz;
uint8_t UserData[MAX_UD_SIZE];
void *hnd;
dts_pout_callback AppCallBack;
uint8_t DropFrames;
uint8_t b422Mode;
uint8_t bPibEnc;
uint8_t bRevertScramble;
};
/**
* struct BC_DTS_STATUS
* @ReadyListCount: Number of frames in ready list (reported by driver)
* @PowerStateChange: Number of active state power
* transitions (reported by driver)
* @FramesDropped: Number of frames dropped. (reported by DIL)
* @FramesCaptured: Number of frames captured. (reported by DIL)
* @FramesRepeated: Number of frames repeated. (reported by DIL)
* @InputCount: Times compressed video has been sent to the HW.
* i.e. Successful DtsProcInput() calls (reported by DIL)
* @InputTotalSize: Amount of compressed video that has been sent to the HW.
* (reported by DIL)
* @InputBusyCount: Times compressed video has attempted to be sent to the HW
* but the input FIFO was full. (reported by DIL)
* @PIBMissCount: Amount of times a PIB is invalid. (reported by DIL)
* @cpbEmptySize: supported only for H.264, specifically changed for
* Adobe. Report size of CPB buffer available. (reported by DIL)
* @NextTimeStamp: TimeStamp of the next picture that will be returned
* by a call to ProcOutput. Added for Adobe. Reported
* back from the driver
*/
struct BC_DTS_STATUS {
uint8_t ReadyListCount;
uint8_t FreeListCount;
uint8_t PowerStateChange;
uint8_t reserved_[1];
uint32_t FramesDropped;
uint32_t FramesCaptured;
uint32_t FramesRepeated;
uint32_t InputCount;
uint64_t InputTotalSize;
uint32_t InputBusyCount;
uint32_t PIBMissCount;
uint32_t cpbEmptySize;
uint64_t NextTimeStamp;
uint8_t reserved__[16];
};
#define BC_SWAP32(_v) \
((((_v) & 0xFF000000)>>24)| \
(((_v) & 0x00FF0000)>>8)| \
(((_v) & 0x0000FF00)<<8)| \
(((_v) & 0x000000FF)<<24))
#define WM_AGENT_TRAYICON_DECODER_OPEN 10001
#define WM_AGENT_TRAYICON_DECODER_CLOSE 10002
#define WM_AGENT_TRAYICON_DECODER_START 10003
#define WM_AGENT_TRAYICON_DECODER_STOP 10004
#define WM_AGENT_TRAYICON_DECODER_RUN 10005
#define WM_AGENT_TRAYICON_DECODER_PAUSE 10006
#endif /* _BC_DTS_DEFS_H_ */
drivers/staging/crystalhd/bc_dts_glob_lnx.h deleted 100644 → 0
View file @ 895ae876
/********************************************************************
* Copyright(c) 2006-2009 Broadcom Corporation.
*
* Name: bc_dts_glob_lnx.h
*
* Description: Wrapper to Windows dts_glob.h for Link-Linux usage.
* The idea is to define additional Linux related defs
* in this file to avoid changes to existing Windows
* glob file.
*
* AU
*
* HISTORY:
*
********************************************************************
* This header is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as published
* by the Free Software Foundation, either version 2.1 of the License.
*
* This header is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
* You should have received a copy of the GNU Lesser General Public License
* along with this header. If not, see <http://www.gnu.org/licenses/>.
*******************************************************************/
#ifndef _BC_DTS_GLOB_LNX_H_
#define _BC_DTS_GLOB_LNX_H_
#ifdef __LINUX_USER__
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <fcntl.h>
#include <ctype.h>
#include <string.h>
#include <errno.h>
#include <netdb.h>
#include <sys/time.h>
#include <time.h>
#include <arpa/inet.h>
#include <linux/param.h>
#include <linux/ioctl.h>
#include <sys/select.h>
#define DRVIFLIB_INT_API
#endif
#include "crystalhd.h"
#define CRYSTALHD_API_NAME "crystalhd"
#define CRYSTALHD_API_DEV_NAME "/dev/crystalhd"
/*
* These are SW stack tunable parameters shared
* between the driver and the application.
*/
enum BC_DTS_GLOBALS {
BC_MAX_FW_CMD_BUFF_SZ = 0x40, /* FW passthrough cmd/rsp buffer size */
PCI_CFG_SIZE = 256, /* PCI config size buffer */
BC_IOCTL_DATA_POOL_SIZE = 8, /* BC_IOCTL_DATA Pool size */
BC_LINK_MAX_OPENS = 3, /* Maximum simultaneous opens*/
BC_LINK_MAX_SGLS = 1024, /* Maximum SG elements 4M/4K */
BC_TX_LIST_CNT = 2, /* Max Tx DMA Rings */
BC_RX_LIST_CNT = 8, /* Max Rx DMA Rings*/
BC_PROC_OUTPUT_TIMEOUT = 3000, /* Milliseconds */
BC_INFIFO_THRESHOLD = 0x10000,
};
struct BC_CMD_REG_ACC {
uint32_t Offset;
uint32_t Value;
};
struct BC_CMD_DEV_MEM {
uint32_t StartOff;
uint32_t NumDwords;
uint32_t Rsrd;
};
/* FW Passthrough command structure */
enum bc_fw_cmd_flags {
BC_FW_CMD_FLAGS_NONE = 0,
BC_FW_CMD_PIB_QS = 0x01,
};
struct BC_FW_CMD {
uint32_t cmd[BC_MAX_FW_CMD_BUFF_SZ];
uint32_t rsp[BC_MAX_FW_CMD_BUFF_SZ];
uint32_t flags;
uint32_t add_data;
};
struct BC_HW_TYPE {
uint16_t PciDevId;
uint16_t PciVenId;
uint8_t HwRev;
uint8_t Align[3];
};
struct BC_PCI_CFG {
uint32_t Size;
uint32_t Offset;
uint8_t pci_cfg_space[PCI_CFG_SIZE];
};
struct BC_VERSION_INFO {
uint8_t DriverMajor;
uint8_t DriverMinor;
uint16_t DriverRevision;
};
struct BC_START_RX_CAP {
uint32_t Rsrd;
uint32_t StartDeliveryThsh;
uint32_t PauseThsh;
uint32_t ResumeThsh;
};
struct BC_FLUSH_RX_CAP {
uint32_t Rsrd;
uint32_t bDiscardOnly;
};
struct BC_DTS_STATS {
uint8_t drvRLL;
uint8_t drvFLL;
uint8_t eosDetected;
uint8_t pwr_state_change;
/* Stats from App */
uint32_t opFrameDropped;
uint32_t opFrameCaptured;
uint32_t ipSampleCnt;
uint64_t ipTotalSize;
uint32_t reptdFrames;
uint32_t pauseCount;
uint32_t pibMisses;
uint32_t discCounter;
/* Stats from Driver */
uint32_t TxFifoBsyCnt;
uint32_t intCount;
uint32_t DrvIgnIntrCnt;
uint32_t DrvTotalFrmDropped;
uint32_t DrvTotalHWErrs;
uint32_t DrvTotalPIBFlushCnt;
uint32_t DrvTotalFrmCaptured;
uint32_t DrvPIBMisses;
uint32_t DrvPauseTime;
uint32_t DrvRepeatedFrms;
uint32_t res1[13];
};
struct BC_PROC_INPUT {
uint8_t *pDmaBuff;
uint32_t BuffSz;
uint8_t Mapped;
uint8_t Encrypted;
uint8_t Rsrd[2];
uint32_t DramOffset; /* For debug use only */
};
struct BC_DEC_YUV_BUFFS {
uint32_t b422Mode;
uint8_t *YuvBuff;
uint32_t YuvBuffSz;
uint32_t UVbuffOffset;
uint32_t YBuffDoneSz;
uint32_t UVBuffDoneSz;
uint32_t RefCnt;
};
enum DECOUT_COMPLETION_FLAGS {
COMP_FLAG_NO_INFO = 0x00,
COMP_FLAG_FMT_CHANGE = 0x01,
COMP_FLAG_PIB_VALID = 0x02,
COMP_FLAG_DATA_VALID = 0x04,
COMP_FLAG_DATA_ENC = 0x08,
COMP_FLAG_DATA_BOT = 0x10,
};
struct BC_DEC_OUT_BUFF {
struct BC_DEC_YUV_BUFFS OutPutBuffs;
struct BC_PIC_INFO_BLOCK PibInfo;
uint32_t Flags;
uint32_t BadFrCnt;
};
struct BC_NOTIFY_MODE {
uint32_t Mode;
uint32_t Rsvr[3];
};
struct BC_CLOCK {
uint32_t clk;
uint32_t Rsvr[3];
};
struct BC_IOCTL_DATA {
enum BC_STATUS RetSts;
uint32_t IoctlDataSz;
uint32_t Timeout;
union {
struct BC_CMD_REG_ACC regAcc;
struct BC_CMD_DEV_MEM devMem;
struct BC_FW_CMD fwCmd;
struct BC_HW_TYPE hwType;
struct BC_PCI_CFG pciCfg;
struct BC_VERSION_INFO VerInfo;
struct BC_PROC_INPUT ProcInput;
struct BC_DEC_YUV_BUFFS RxBuffs;
struct BC_DEC_OUT_BUFF DecOutData;
struct BC_START_RX_CAP RxCap;
struct BC_FLUSH_RX_CAP FlushRxCap;
struct BC_DTS_STATS drvStat;
struct BC_NOTIFY_MODE NotifyMode;
struct BC_CLOCK clockValue;
} u;
struct _BC_IOCTL_DATA *next;
};
enum BC_DRV_CMD {
DRV_CMD_VERSION = 0, /* Get SW version */
DRV_CMD_GET_HWTYPE, /* Get HW version and type Dozer/Tank */
DRV_CMD_REG_RD, /* Read Device Register */
DRV_CMD_REG_WR, /* Write Device Register */
DRV_CMD_FPGA_RD, /* Read FPGA Register */
DRV_CMD_FPGA_WR, /* Write FPGA Register */
DRV_CMD_MEM_RD, /* Read Device Memory */
DRV_CMD_MEM_WR, /* Write Device Memory */
DRV_CMD_RD_PCI_CFG, /* Read PCI Config Space */
DRV_CMD_WR_PCI_CFG, /* Write the PCI Configuration Space*/
DRV_CMD_FW_DOWNLOAD, /* Download Firmware */
DRV_ISSUE_FW_CMD, /* Issue FW Cmd (pass through mode) */
DRV_CMD_PROC_INPUT, /* Process Input Sample */
DRV_CMD_ADD_RXBUFFS, /* Add Rx side buffers to driver pool */
DRV_CMD_FETCH_RXBUFF, /* Get Rx DMAed buffer */
DRV_CMD_START_RX_CAP, /* Start Rx Buffer Capture */
DRV_CMD_FLUSH_RX_CAP, /* Stop the capture for now...
we will enhance this later*/
DRV_CMD_GET_DRV_STAT, /* Get Driver Internal Statistics */
DRV_CMD_RST_DRV_STAT, /* Reset Driver Internal Statistics */
DRV_CMD_NOTIFY_MODE, /* Notify the Mode to driver
in which the application is Operating*/
DRV_CMD_CHANGE_CLOCK, /* Change the core clock to either save power
or improve performance */
/* MUST be the last one.. */
DRV_CMD_END, /* End of the List.. */
};
#define BC_IOC_BASE 'b'
#define BC_IOC_VOID _IOC_NONE
#define BC_IOC_IOWR(nr, type) _IOWR(BC_IOC_BASE, nr, type)
#define BC_IOCTL_MB struct BC_IOCTL_DATA
#define BCM_IOC_GET_VERSION BC_IOC_IOWR(DRV_CMD_VERSION, BC_IOCTL_MB)
#define BCM_IOC_GET_HWTYPE BC_IOC_IOWR(DRV_CMD_GET_HWTYPE, BC_IOCTL_MB)
#define BCM_IOC_REG_RD BC_IOC_IOWR(DRV_CMD_REG_RD, BC_IOCTL_MB)
#define BCM_IOC_REG_WR BC_IOC_IOWR(DRV_CMD_REG_WR, BC_IOCTL_MB)
#define BCM_IOC_MEM_RD BC_IOC_IOWR(DRV_CMD_MEM_RD, BC_IOCTL_MB)
#define BCM_IOC_MEM_WR BC_IOC_IOWR(DRV_CMD_MEM_WR, BC_IOCTL_MB)
#define BCM_IOC_FPGA_RD BC_IOC_IOWR(DRV_CMD_FPGA_RD, BC_IOCTL_MB)
#define BCM_IOC_FPGA_WR BC_IOC_IOWR(DRV_CMD_FPGA_WR, BC_IOCTL_MB)
#define BCM_IOC_RD_PCI_CFG BC_IOC_IOWR(DRV_CMD_RD_PCI_CFG, BC_IOCTL_MB)
#define BCM_IOC_WR_PCI_CFG BC_IOC_IOWR(DRV_CMD_WR_PCI_CFG, BC_IOCTL_MB)
#define BCM_IOC_PROC_INPUT BC_IOC_IOWR(DRV_CMD_PROC_INPUT, BC_IOCTL_MB)
#define BCM_IOC_ADD_RXBUFFS BC_IOC_IOWR(DRV_CMD_ADD_RXBUFFS, BC_IOCTL_MB)
#define BCM_IOC_FETCH_RXBUFF BC_IOC_IOWR(DRV_CMD_FETCH_RXBUFF, BC_IOCTL_MB)
#define BCM_IOC_FW_CMD BC_IOC_IOWR(DRV_ISSUE_FW_CMD, BC_IOCTL_MB)
#define BCM_IOC_START_RX_CAP BC_IOC_IOWR(DRV_CMD_START_RX_CAP, BC_IOCTL_MB)
#define BCM_IOC_FLUSH_RX_CAP BC_IOC_IOWR(DRV_CMD_FLUSH_RX_CAP, BC_IOCTL_MB)
#define BCM_IOC_GET_DRV_STAT BC_IOC_IOWR(DRV_CMD_GET_DRV_STAT, BC_IOCTL_MB)
#define BCM_IOC_RST_DRV_STAT BC_IOC_IOWR(DRV_CMD_RST_DRV_STAT, BC_IOCTL_MB)
#define BCM_IOC_NOTIFY_MODE BC_IOC_IOWR(DRV_CMD_NOTIFY_MODE, BC_IOCTL_MB)
#define BCM_IOC_FW_DOWNLOAD BC_IOC_IOWR(DRV_CMD_FW_DOWNLOAD, BC_IOCTL_MB)
#define BCM_IOC_CHG_CLK BC_IOC_IOWR(DRV_CMD_CHANGE_CLOCK, BC_IOCTL_MB)
#define BCM_IOC_END BC_IOC_VOID
/* Wrapper for main IOCTL data */
struct crystalhd_ioctl_data {
struct BC_IOCTL_DATA udata; /* IOCTL from App..*/
uint32_t u_id; /* Driver specific user ID */
uint32_t cmd; /* Cmd ID for driver's use. */
void *add_cdata; /* Additional command specific data..*/
uint32_t add_cdata_sz; /* Additional command specific data size */
struct crystalhd_ioctl_data *next; /* List/Fifo management */
};
enum crystalhd_kmod_ver {
crystalhd_kmod_major = 0,
crystalhd_kmod_minor = 9,
crystalhd_kmod_rev = 27,
};
#endif
drivers/staging/crystalhd/bcm_70012_regs.h deleted 100644 → 0
View file @ 895ae876
/***************************************************************************
* Copyright (c) 1999-2009, Broadcom Corporation.
*
* Name: bcm_70012_regs.h
*
* Description: BCM70012 registers
*
********************************************************************
* This header is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as published
* by the Free Software Foundation, either version 2.1 of the License.
*
* This header is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
* You should have received a copy of the GNU Lesser General Public License
* along with this header. If not, see <http://www.gnu.org/licenses/>.
***************************************************************************/
#ifndef MACFILE_H__
#define MACFILE_H__
/**
* m = memory, c = core, r = register, f = field, d = data.
*/
#if !defined(GET_FIELD) && !defined(SET_FIELD)
#define BRCM_ALIGN(c, r, f) c##_##r##_##f##_ALIGN
#define BRCM_BITS(c, r, f) c##_##r##_##f##_BITS
#define BRCM_MASK(c, r, f) c##_##r##_##f##_MASK
#define BRCM_SHIFT(c, r, f) c##_##r##_##f##_SHIFT
#define GET_FIELD(m, c, r, f) \
((((m) & BRCM_MASK(c, r, f)) >> BRCM_SHIFT(c, r, f)) << \
BRCM_ALIGN(c, r, f))
#define SET_FIELD(m, c, r, f, d) \
((m) = (((m) & ~BRCM_MASK(c, r, f)) | ((((d) >> BRCM_ALIGN(c, r, f)) << \
BRCM_SHIFT(c, r, f)) & BRCM_MASK(c, r, f))) \
)
#define SET_TYPE_FIELD(m, c, r, f, d) SET_FIELD(m, c, r, f, c##_##d)
#define SET_NAME_FIELD(m, c, r, f, d) SET_FIELD(m, c, r, f, c##_##r##_##f##_##d)
#define SET_VALUE_FIELD(m, c, r, f, d) SET_FIELD(m, c, r, f, d)
#endif /* GET & SET */
/****************************************************************************
* Core Enums.
***************************************************************************/
/****************************************************************************
* Enums: AES_RGR_BRIDGE_RESET_CTRL
***************************************************************************/
#define AES_RGR_BRIDGE_RESET_CTRL_DEASSERT 0
#define AES_RGR_BRIDGE_RESET_CTRL_ASSERT 1
/****************************************************************************
* Enums: CCE_RGR_BRIDGE_RESET_CTRL
***************************************************************************/
#define CCE_RGR_BRIDGE_RESET_CTRL_DEASSERT 0
#define CCE_RGR_BRIDGE_RESET_CTRL_ASSERT 1
/****************************************************************************
* Enums: DBU_RGR_BRIDGE_RESET_CTRL
***************************************************************************/
#define DBU_RGR_BRIDGE_RESET_CTRL_DEASSERT 0
#define DBU_RGR_BRIDGE_RESET_CTRL_ASSERT 1
/****************************************************************************
* Enums: DCI_RGR_BRIDGE_RESET_CTRL
***************************************************************************/
#define DCI_RGR_BRIDGE_RESET_CTRL_DEASSERT 0
#define DCI_RGR_BRIDGE_RESET_CTRL_ASSERT 1
/****************************************************************************
* Enums: GISB_ARBITER_DEASSERT_ASSERT
***************************************************************************/
#define GISB_ARBITER_DEASSERT_ASSERT_DEASSERT 0
#define GISB_ARBITER_DEASSERT_ASSERT_ASSERT 1
/****************************************************************************
* Enums: GISB_ARBITER_UNMASK_MASK
***************************************************************************/
#define GISB_ARBITER_UNMASK_MASK_UNMASK 0
#define GISB_ARBITER_UNMASK_MASK_MASK 1
/****************************************************************************
* Enums: GISB_ARBITER_DISABLE_ENABLE
***************************************************************************/
#define GISB_ARBITER_DISABLE_ENABLE_DISABLE 0
#define GISB_ARBITER_DISABLE_ENABLE_ENABLE 1
/****************************************************************************
* Enums: I2C_GR_BRIDGE_RESET_CTRL
***************************************************************************/
#define I2C_GR_BRIDGE_RESET_CTRL_DEASSERT 0
#define I2C_GR_BRIDGE_RESET_CTRL_ASSERT 1
/****************************************************************************
* Enums: MISC_GR_BRIDGE_RESET_CTRL
***************************************************************************/
#define MISC_GR_BRIDGE_RESET_CTRL_DEASSERT 0
#define MISC_GR_BRIDGE_RESET_CTRL_ASSERT 1
/****************************************************************************
* Enums: OTP_GR_BRIDGE_RESET_CTRL
***************************************************************************/
#define OTP_GR_BRIDGE_RESET_CTRL_DEASSERT 0
#define OTP_GR_BRIDGE_RESET_CTRL_ASSERT 1
/****************************************************************************
* BCM70012_TGT_TOP_PCIE_CFG
***************************************************************************/
#define PCIE_CFG_DEVICE_VENDOR_ID 0x00000000 /* DEVICE_VENDOR_ID Register */
#define PCIE_CFG_STATUS_COMMAND 0x00000004 /* STATUS_COMMAND Register */
#define PCIE_CFG_PCI_CLASSCODE_AND_REVISION_ID 0x00000008 /* PCI_CLASSCODE_AND_REVISION_ID Register */
#define PCIE_CFG_BIST_HEADER_TYPE_LATENCY_TIMER_CACHE_LINE_SIZE 0x0000000c /* BIST_HEADER_TYPE_LATENCY_TIMER_CACHE_LINE_SIZE Register */
#define PCIE_CFG_BASE_ADDRESS_1 0x00000010 /* BASE_ADDRESS_1 Register */
#define PCIE_CFG_BASE_ADDRESS_2 0x00000014 /* BASE_ADDRESS_2 Register */
#define PCIE_CFG_BASE_ADDRESS_3 0x00000018 /* BASE_ADDRESS_3 Register */
#define PCIE_CFG_BASE_ADDRESS_4 0x0000001c /* BASE_ADDRESS_4 Register */
#define PCIE_CFG_CARDBUS_CIS_POINTER 0x00000028 /* CARDBUS_CIS_POINTER Register */
#define PCIE_CFG_SUBSYSTEM_DEVICE_VENDOR_ID 0x0000002c /* SUBSYSTEM_DEVICE_VENDOR_ID Register */
#define PCIE_CFG_EXPANSION_ROM_BASE_ADDRESS 0x00000030 /* EXPANSION_ROM_BASE_ADDRESS Register */
#define PCIE_CFG_CAPABILITIES_POINTER 0x00000034 /* CAPABILITIES_POINTER Register */
#define PCIE_CFG_INTERRUPT 0x0000003c /* INTERRUPT Register */
#define PCIE_CFG_VPD_CAPABILITIES 0x00000040 /* VPD_CAPABILITIES Register */
#define PCIE_CFG_VPD_DATA 0x00000044 /* VPD_DATA Register */
#define PCIE_CFG_POWER_MANAGEMENT_CAPABILITY 0x00000048 /* POWER_MANAGEMENT_CAPABILITY Register */
#define PCIE_CFG_POWER_MANAGEMENT_CONTROL_STATUS 0x0000004c /* POWER_MANAGEMENT_CONTROL_STATUS Register */
#define PCIE_CFG_MSI_CAPABILITY_HEADER 0x00000050 /* MSI_CAPABILITY_HEADER Register */
#define PCIE_CFG_MSI_LOWER_ADDRESS 0x00000054 /* MSI_LOWER_ADDRESS Register */
#define PCIE_CFG_MSI_UPPER_ADDRESS_REGISTER 0x00000058 /* MSI_UPPER_ADDRESS_REGISTER Register */
#define PCIE_CFG_MSI_DATA 0x0000005c /* MSI_DATA Register */
#define PCIE_CFG_BROADCOM_VENDOR_SPECIFIC_CAPABILITY_HEADER 0x00000060 /* BROADCOM_VENDOR_SPECIFIC_CAPABILITY_HEADER Register */
#define PCIE_CFG_RESET_COUNTERS_INITIAL_VALUES 0x00000064 /* RESET_COUNTERS_INITIAL_VALUES Register */
#define PCIE_CFG_MISCELLANEOUS_HOST_CONTROL 0x00000068 /* MISCELLANEOUS_HOST_CONTROL Register */
#define PCIE_CFG_SPARE 0x0000006c /* SPARE Register */
#define PCIE_CFG_PCI_STATE 0x00000070 /* PCI_STATE Register */
#define PCIE_CFG_CLOCK_CONTROL 0x00000074 /* CLOCK_CONTROL Register */
#define PCIE_CFG_REGISTER_BASE 0x00000078 /* REGISTER_BASE Register */
#define PCIE_CFG_MEMORY_BASE 0x0000007c /* MEMORY_BASE Register */
#define PCIE_CFG_REGISTER_DATA 0x00000080 /* REGISTER_DATA Register */
#define PCIE_CFG_MEMORY_DATA 0x00000084 /* MEMORY_DATA Register */
#define PCIE_CFG_EXPANSION_ROM_BAR_SIZE 0x00000088 /* EXPANSION_ROM_BAR_SIZE Register */
#define PCIE_CFG_EXPANSION_ROM_ADDRESS 0x0000008c /* EXPANSION_ROM_ADDRESS Register */
#define PCIE_CFG_EXPANSION_ROM_DATA 0x00000090 /* EXPANSION_ROM_DATA Register */
#define PCIE_CFG_VPD_INTERFACE 0x00000094 /* VPD_INTERFACE Register */
#define PCIE_CFG_UNDI_RECEIVE_BD_STANDARD_PRODUCER_RING_PRODUCER_INDEX_MAILBOX_UPPER 0x00000098 /* UNDI_RECEIVE_BD_STANDARD_PRODUCER_RING_PRODUCER_INDEX_MAILBOX_UPPER Register */
#define PCIE_CFG_UNDI_RECEIVE_BD_STANDARD_PRODUCER_RING_PRODUCER_INDEX_MAILBOX_LOWER 0x0000009c /* UNDI_RECEIVE_BD_STANDARD_PRODUCER_RING_PRODUCER_INDEX_MAILBOX_LOWER Register */
#define PCIE_CFG_UNDI_RECEIVE_RETURN_RING_CONSUMER_INDEX_UPPER 0x000000a0 /* UNDI_RECEIVE_RETURN_RING_CONSUMER_INDEX_UPPER Register */
#define PCIE_CFG_UNDI_RECEIVE_RETURN_RING_CONSUMER_INDEX_LOWER 0x000000a4 /* UNDI_RECEIVE_RETURN_RING_CONSUMER_INDEX_LOWER Register */
#define PCIE_CFG_UNDI_SEND_BD_PRODUCER_INDEX_MAILBOX_UPPER 0x000000a8 /* UNDI_SEND_BD_PRODUCER_INDEX_MAILBOX_UPPER Register */
#define PCIE_CFG_UNDI_SEND_BD_PRODUCER_INDEX_MAILBOX_LOWER 0x000000ac /* UNDI_SEND_BD_PRODUCER_INDEX_MAILBOX_LOWER Register */
#define PCIE_CFG_INT_MAILBOX_UPPER 0x000000b0 /* INT_MAILBOX_UPPER Register */
#define PCIE_CFG_INT_MAILBOX_LOWER 0x000000b4 /* INT_MAILBOX_LOWER Register */
#define PCIE_CFG_PRODUCT_ID_AND_ASIC_REVISION 0x000000bc /* PRODUCT_ID_AND_ASIC_REVISION Register */
#define PCIE_CFG_FUNCTION_EVENT 0x000000c0 /* FUNCTION_EVENT Register */
#define PCIE_CFG_FUNCTION_EVENT_MASK 0x000000c4 /* FUNCTION_EVENT_MASK Register */
#define PCIE_CFG_FUNCTION_PRESENT 0x000000c8 /* FUNCTION_PRESENT Register */
#define PCIE_CFG_PCIE_CAPABILITIES 0x000000cc /* PCIE_CAPABILITIES Register */
#define PCIE_CFG_DEVICE_CAPABILITIES 0x000000d0 /* DEVICE_CAPABILITIES Register */
#define PCIE_CFG_DEVICE_STATUS_CONTROL 0x000000d4 /* DEVICE_STATUS_CONTROL Register */
#define PCIE_CFG_LINK_CAPABILITY 0x000000d8 /* LINK_CAPABILITY Register */
#define PCIE_CFG_LINK_STATUS_CONTROL 0x000000dc /* LINK_STATUS_CONTROL Register */
#define PCIE_CFG_DEVICE_CAPABILITIES_2 0x000000f0 /* DEVICE_CAPABILITIES_2 Register */
#define PCIE_CFG_DEVICE_STATUS_CONTROL_2 0x000000f4 /* DEVICE_STATUS_CONTROL_2 Register */
#define PCIE_CFG_LINK_CAPABILITIES_2 0x000000f8 /* LINK_CAPABILITIES_2 Register */
#define PCIE_CFG_LINK_STATUS_CONTROL_2 0x000000fc /* LINK_STATUS_CONTROL_2 Register */
#define PCIE_CFG_ADVANCED_ERROR_REPORTING_ENHANCED_CAPABILITY_HEADER 0x00000100 /* ADVANCED_ERROR_REPORTING_ENHANCED_CAPABILITY_HEADER Register */
#define PCIE_CFG_UNCORRECTABLE_ERROR_STATUS 0x00000104 /* UNCORRECTABLE_ERROR_STATUS Register */
#define PCIE_CFG_UNCORRECTABLE_ERROR_MASK 0x00000108 /* UNCORRECTABLE_ERROR_MASK Register */
#define PCIE_CFG_UNCORRECTABLE_ERROR_SEVERITY 0x0000010c /* UNCORRECTABLE_ERROR_SEVERITY Register */
#define PCIE_CFG_CORRECTABLE_ERROR_STATUS 0x00000110 /* CORRECTABLE_ERROR_STATUS Register */
#define PCIE_CFG_CORRECTABLE_ERROR_MASK 0x00000114 /* CORRECTABLE_ERROR_MASK Register */
#define PCIE_CFG_ADVANCED_ERROR_CAPABILITIES_AND_CONTROL 0x00000118 /* ADVANCED_ERROR_CAPABILITIES_AND_CONTROL Register */
#define PCIE_CFG_HEADER_LOG_1 0x0000011c /* HEADER_LOG_1 Register */
#define PCIE_CFG_HEADER_LOG_2 0x00000120 /* HEADER_LOG_2 Register */
#define PCIE_CFG_HEADER_LOG_3 0x00000124 /* HEADER_LOG_3 Register */
#define PCIE_CFG_HEADER_LOG_4 0x00000128 /* HEADER_LOG_4 Register */
#define PCIE_CFG_VIRTUAL_CHANNEL_ENHANCED_CAPABILITY_HEADER 0x0000013c /* VIRTUAL_CHANNEL_ENHANCED_CAPABILITY_HEADER Register */
#define PCIE_CFG_PORT_VC_CAPABILITY 0x00000140 /* PORT_VC_CAPABILITY Register */
#define PCIE_CFG_PORT_VC_CAPABILITY_2 0x00000144 /* PORT_VC_CAPABILITY_2 Register */
#define PCIE_CFG_PORT_VC_STATUS_CONTROL 0x00000148 /* PORT_VC_STATUS_CONTROL Register */
#define PCIE_CFG_VC_RESOURCE_CAPABILITY 0x0000014c /* VC_RESOURCE_CAPABILITY Register */
#define PCIE_CFG_VC_RESOURCE_CONTROL 0x00000150 /* VC_RESOURCE_CONTROL Register */
#define PCIE_CFG_VC_RESOURCE_STATUS 0x00000154 /* VC_RESOURCE_STATUS Register */
#define PCIE_CFG_DEVICE_SERIAL_NO_ENHANCED_CAPABILITY_HEADER 0x00000160 /* DEVICE_SERIAL_NO_ENHANCED_CAPABILITY_HEADER Register */
#define PCIE_CFG_DEVICE_SERIAL_NO_LOWER_DW 0x00000164 /* DEVICE_SERIAL_NO_LOWER_DW Register */
#define PCIE_CFG_DEVICE_SERIAL_NO_UPPER_DW 0x00000168 /* DEVICE_SERIAL_NO_UPPER_DW Register */
#define PCIE_CFG_POWER_BUDGETING_ENHANCED_CAPABILITY_HEADER 0x0000016c /* POWER_BUDGETING_ENHANCED_CAPABILITY_HEADER Register */
#define PCIE_CFG_POWER_BUDGETING_DATA_SELECT 0x00000170 /* POWER_BUDGETING_DATA_SELECT Register */
#define PCIE_CFG_POWER_BUDGETING_DATA 0x00000174 /* POWER_BUDGETING_DATA Register */
#define PCIE_CFG_POWER_BUDGETING_CAPABILITY 0x00000178 /* POWER_BUDGETING_CAPABILITY Register */
#define PCIE_CFG_FIRMWARE_POWER_BUDGETING_2_1 0x0000017c /* FIRMWARE_POWER_BUDGETING_2_1 Register */
#define PCIE_CFG_FIRMWARE_POWER_BUDGETING_4_3 0x00000180 /* FIRMWARE_POWER_BUDGETING_4_3 Register */
#define PCIE_CFG_FIRMWARE_POWER_BUDGETING_6_5 0x00000184 /* FIRMWARE_POWER_BUDGETING_6_5 Register */
#define PCIE_CFG_FIRMWARE_POWER_BUDGETING_8_7 0x00000188 /* FIRMWARE_POWER_BUDGETING_8_7 Register */
#define PCIE_CFG_PCIE_1_1_ADVISORY_NON_FATAL_ERROR_MASKING 0x0000018c /* PCIE_1_1_ADVISORY_NON_FATAL_ERROR_MASKING Register */
/****************************************************************************
* BCM70012_TGT_TOP_PCIE_TL
***************************************************************************/
#define PCIE_TL_TL_CONTROL 0x00000400 /* TL_CONTROL Register */
#define PCIE_TL_TRANSACTION_CONFIGURATION 0x00000404 /* TRANSACTION_CONFIGURATION Register */
/****************************************************************************
* BCM70012_TGT_TOP_PCIE_DLL
***************************************************************************/
#define PCIE_DLL_DATA_LINK_CONTROL 0x00000500 /* DATA_LINK_CONTROL Register */
#define PCIE_DLL_DATA_LINK_STATUS 0x00000504 /* DATA_LINK_STATUS Register */
/****************************************************************************
* BCM70012_TGT_TOP_INTR
***************************************************************************/
#define INTR_INTR_STATUS 0x00000700 /* Interrupt Status Register */
#define INTR_INTR_SET 0x00000704 /* Interrupt Set Register */
#define INTR_INTR_CLR_REG 0x00000708 /* Interrupt Clear Register */
#define INTR_INTR_MSK_STS_REG 0x0000070c /* Interrupt Mask Status Register */
#define INTR_INTR_MSK_SET_REG 0x00000710 /* Interrupt Mask Set Register */
#define INTR_INTR_MSK_CLR_REG 0x00000714 /* Interrupt Mask Clear Register */
#define INTR_EOI_CTRL 0x00000720 /* End of interrupt control register */
/****************************************************************************
* BCM70012_MISC_TOP_MISC1
***************************************************************************/
#define MISC1_TX_FIRST_DESC_L_ADDR_LIST0 0x00000c00 /* Tx DMA Descriptor List0 First Descriptor lower Address */
#define MISC1_TX_FIRST_DESC_U_ADDR_LIST0 0x00000c04 /* Tx DMA Descriptor List0 First Descriptor Upper Address */
#define MISC1_TX_FIRST_DESC_L_ADDR_LIST1 0x00000c08 /* Tx DMA Descriptor List1 First Descriptor Lower Address */
#define MISC1_TX_FIRST_DESC_U_ADDR_LIST1 0x00000c0c /* Tx DMA Descriptor List1 First Descriptor Upper Address */
#define MISC1_TX_SW_DESC_LIST_CTRL_STS 0x00000c10 /* Tx DMA Software Descriptor List Control and Status */
#define MISC1_TX_DMA_ERROR_STATUS 0x00000c18 /* Tx DMA Engine Error Status */
#define MISC1_TX_DMA_LIST0_CUR_DESC_L_ADDR 0x00000c1c /* Tx DMA List0 Current Descriptor Lower Address */
#define MISC1_TX_DMA_LIST0_CUR_DESC_U_ADDR 0x00000c20 /* Tx DMA List0 Current Descriptor Upper Address */
#define MISC1_TX_DMA_LIST0_CUR_BYTE_CNT_REM 0x00000c24 /* Tx DMA List0 Current Descriptor Upper Address */
#define MISC1_TX_DMA_LIST1_CUR_DESC_L_ADDR 0x00000c28 /* Tx DMA List1 Current Descriptor Lower Address */
#define MISC1_TX_DMA_LIST1_CUR_DESC_U_ADDR 0x00000c2c /* Tx DMA List1 Current Descriptor Upper Address */
#define MISC1_TX_DMA_LIST1_CUR_BYTE_CNT_REM 0x00000c30 /* Tx DMA List1 Current Descriptor Upper Address */
#define MISC1_Y_RX_FIRST_DESC_L_ADDR_LIST0 0x00000c34 /* Y Rx Descriptor List0 First Descriptor Lower Address */
#define MISC1_Y_RX_FIRST_DESC_U_ADDR_LIST0 0x00000c38 /* Y Rx Descriptor List0 First Descriptor Upper Address */
#define MISC1_Y_RX_FIRST_DESC_L_ADDR_LIST1 0x00000c3c /* Y Rx Descriptor List1 First Descriptor Lower Address */
#define MISC1_Y_RX_FIRST_DESC_U_ADDR_LIST1 0x00000c40 /* Y Rx Descriptor List1 First Descriptor Upper Address */
#define MISC1_Y_RX_SW_DESC_LIST_CTRL_STS 0x00000c44 /* Y Rx Software Descriptor List Control and Status */
#define MISC1_Y_RX_ERROR_STATUS 0x00000c4c /* Y Rx Engine Error Status */
#define MISC1_Y_RX_LIST0_CUR_DESC_L_ADDR 0x00000c50 /* Y Rx List0 Current Descriptor Lower Address */
#define MISC1_Y_RX_LIST0_CUR_DESC_U_ADDR 0x00000c54 /* Y Rx List0 Current Descriptor Upper Address */
#define MISC1_Y_RX_LIST0_CUR_BYTE_CNT 0x00000c58 /* Y Rx List0 Current Descriptor Byte Count */
#define MISC1_Y_RX_LIST1_CUR_DESC_L_ADDR 0x00000c5c /* Y Rx List1 Current Descriptor Lower address */
#define MISC1_Y_RX_LIST1_CUR_DESC_U_ADDR 0x00000c60 /* Y Rx List1 Current Descriptor Upper address */
#define MISC1_Y_RX_LIST1_CUR_BYTE_CNT 0x00000c64 /* Y Rx List1 Current Descriptor Byte Count */
#define MISC1_UV_RX_FIRST_DESC_L_ADDR_LIST0 0x00000c68 /* UV Rx Descriptor List0 First Descriptor lower Address */
#define MISC1_UV_RX_FIRST_DESC_U_ADDR_LIST0 0x00000c6c /* UV Rx Descriptor List0 First Descriptor Upper Address */
#define MISC1_UV_RX_FIRST_DESC_L_ADDR_LIST1 0x00000c70 /* UV Rx Descriptor List1 First Descriptor Lower Address */
#define MISC1_UV_RX_FIRST_DESC_U_ADDR_LIST1 0x00000c74 /* UV Rx Descriptor List1 First Descriptor Upper Address */
#define MISC1_UV_RX_SW_DESC_LIST_CTRL_STS 0x00000c78 /* UV Rx Software Descriptor List Control and Status */
#define MISC1_UV_RX_ERROR_STATUS 0x00000c7c /* UV Rx Engine Error Status */
#define MISC1_UV_RX_LIST0_CUR_DESC_L_ADDR 0x00000c80 /* UV Rx List0 Current Descriptor Lower Address */
#define MISC1_UV_RX_LIST0_CUR_DESC_U_ADDR 0x00000c84 /* UV Rx List0 Current Descriptor Upper Address */
#define MISC1_UV_RX_LIST0_CUR_BYTE_CNT 0x00000c88 /* UV Rx List0 Current Descriptor Byte Count */
#define MISC1_UV_RX_LIST1_CUR_DESC_L_ADDR 0x00000c8c /* UV Rx List1 Current Descriptor Lower Address */
#define MISC1_UV_RX_LIST1_CUR_DESC_U_ADDR 0x00000c90 /* UV Rx List1 Current Descriptor Upper Address */
#define MISC1_UV_RX_LIST1_CUR_BYTE_CNT 0x00000c94 /* UV Rx List1 Current Descriptor Byte Count */
#define MISC1_DMA_DEBUG_OPTIONS_REG 0x00000c98 /* DMA Debug Options Register */
#define MISC1_READ_CHANNEL_ERROR_STATUS 0x00000c9c /* Read Channel Error Status */
#define MISC1_PCIE_DMA_CTRL 0x00000ca0 /* PCIE DMA Control Register */
/****************************************************************************
* BCM70012_MISC_TOP_MISC2
***************************************************************************/
#define MISC2_GLOBAL_CTRL 0x00000d00 /* Global Control Register */
#define MISC2_INTERNAL_STATUS 0x00000d04 /* Internal Status Register */
#define MISC2_INTERNAL_STATUS_MUX_CTRL 0x00000d08 /* Internal Debug Mux Control */
#define MISC2_DEBUG_FIFO_LENGTH 0x00000d0c /* Debug FIFO Length */
/****************************************************************************
* BCM70012_MISC_TOP_MISC3
***************************************************************************/
#define MISC3_RESET_CTRL 0x00000e00 /* Reset Control Register */
#define MISC3_BIST_CTRL 0x00000e04 /* BIST Control Register */
#define MISC3_BIST_STATUS 0x00000e08 /* BIST Status Register */
#define MISC3_RX_CHECKSUM 0x00000e0c /* Receive Checksum */
#define MISC3_TX_CHECKSUM 0x00000e10 /* Transmit Checksum */
#define MISC3_ECO_CTRL_CORE 0x00000e14 /* ECO Core Reset Control Register */
#define MISC3_CSI_TEST_CTRL 0x00000e18 /* CSI Test Control Register */
#define MISC3_HD_DVI_TEST_CTRL 0x00000e1c /* HD DVI Test Control Register */
/****************************************************************************
* BCM70012_MISC_TOP_MISC_PERST
***************************************************************************/
#define MISC_PERST_ECO_CTRL_PERST 0x00000e80 /* ECO PCIE Reset Control Register */
#define MISC_PERST_DECODER_CTRL 0x00000e84 /* Decoder Control Register */
#define MISC_PERST_CCE_STATUS 0x00000e88 /* Config Copy Engine Status */
#define MISC_PERST_PCIE_DEBUG 0x00000e8c /* PCIE Debug Control Register */
#define MISC_PERST_PCIE_DEBUG_STATUS 0x00000e90 /* PCIE Debug Status Register */
#define MISC_PERST_VREG_CTRL 0x00000e94 /* Voltage Regulator Control Register */
#define MISC_PERST_MEM_CTRL 0x00000e98 /* Memory Control Register */
#define MISC_PERST_CLOCK_CTRL 0x00000e9c /* Clock Control Register */
/****************************************************************************
* BCM70012_MISC_TOP_GISB_ARBITER
***************************************************************************/
#define GISB_ARBITER_REVISION 0x00000f00 /* GISB ARBITER REVISION */
#define GISB_ARBITER_SCRATCH 0x00000f04 /* GISB ARBITER Scratch Register */
#define GISB_ARBITER_REQ_MASK 0x00000f08 /* GISB ARBITER Master Request Mask Register */
#define GISB_ARBITER_TIMER 0x00000f0c /* GISB ARBITER Timer Value Register */
/****************************************************************************
* BCM70012_OTP_TOP_OTP
***************************************************************************/
#define OTP_CONFIG_INFO 0x00001400 /* OTP Configuration Register */
#define OTP_CMD 0x00001404 /* OTP Command Register */
#define OTP_STATUS 0x00001408 /* OTP Status Register */
#define OTP_CONTENT_MISC 0x0000140c /* Content : Miscellaneous Register */
#define OTP_CONTENT_AES_0 0x00001410 /* Content : AES Key 0 Register */
#define OTP_CONTENT_AES_1 0x00001414 /* Content : AES Key 1 Register */
#define OTP_CONTENT_AES_2 0x00001418 /* Content : AES Key 2 Register */
#define OTP_CONTENT_AES_3 0x0000141c /* Content : AES Key 3 Register */
#define OTP_CONTENT_SHA_0 0x00001420 /* Content : SHA Key 0 Register */
#define OTP_CONTENT_SHA_1 0x00001424 /* Content : SHA Key 1 Register */
#define OTP_CONTENT_SHA_2 0x00001428 /* Content : SHA Key 2 Register */
#define OTP_CONTENT_SHA_3 0x0000142c /* Content : SHA Key 3 Register */
#define OTP_CONTENT_SHA_4 0x00001430 /* Content : SHA Key 4 Register */
#define OTP_CONTENT_SHA_5 0x00001434 /* Content : SHA Key 5 Register */
#define OTP_CONTENT_SHA_6 0x00001438 /* Content : SHA Key 6 Register */
#define OTP_CONTENT_SHA_7 0x0000143c /* Content : SHA Key 7 Register */
#define OTP_CONTENT_CHECKSUM 0x00001440 /* Content : Checksum Register */
#define OTP_PROG_CTRL 0x00001444 /* Programming Control Register */
#define OTP_PROG_STATUS 0x00001448 /* Programming Status Register */
#define OTP_PROG_PULSE 0x0000144c /* Program Pulse Width Register */
#define OTP_VERIFY_PULSE 0x00001450 /* Verify Pulse Width Register */
#define OTP_PROG_MASK 0x00001454 /* Program Mask Register */
#define OTP_DATA_INPUT 0x00001458 /* Data Input Register */
#define OTP_DATA_OUTPUT 0x0000145c /* Data Output Register */
/****************************************************************************
* BCM70012_AES_TOP_AES
***************************************************************************/
#define AES_CONFIG_INFO 0x00001800 /* AES Configuration Information Register */
#define AES_CMD 0x00001804 /* AES Command Register */
#define AES_STATUS 0x00001808 /* AES Status Register */
#define AES_EEPROM_CONFIG 0x0000180c /* AES EEPROM Configuration Register */
#define AES_EEPROM_DATA_0 0x00001810 /* AES EEPROM Data Register 0 */
#define AES_EEPROM_DATA_1 0x00001814 /* AES EEPROM Data Register 1 */
#define AES_EEPROM_DATA_2 0x00001818 /* AES EEPROM Data Register 2 */
#define AES_EEPROM_DATA_3 0x0000181c /* AES EEPROM Data Register 3 */
/****************************************************************************
* BCM70012_DCI_TOP_DCI
***************************************************************************/
#define DCI_CMD 0x00001c00 /* DCI Command Register */
#define DCI_STATUS 0x00001c04 /* DCI Status Register */
#define DCI_DRAM_BASE_ADDR 0x00001c08 /* DRAM Base Address Register */
#define DCI_FIRMWARE_ADDR 0x00001c0c /* Firmware Address Register */
#define DCI_FIRMWARE_DATA 0x00001c10 /* Firmware Data Register */
#define DCI_SIGNATURE_DATA_0 0x00001c14 /* Signature Data Register 0 */
#define DCI_SIGNATURE_DATA_1 0x00001c18 /* Signature Data Register 1 */
#define DCI_SIGNATURE_DATA_2 0x00001c1c /* Signature Data Register 2 */
#define DCI_SIGNATURE_DATA_3 0x00001c20 /* Signature Data Register 3 */
#define DCI_SIGNATURE_DATA_4 0x00001c24 /* Signature Data Register 4 */
#define DCI_SIGNATURE_DATA_5 0x00001c28 /* Signature Data Register 5 */
#define DCI_SIGNATURE_DATA_6 0x00001c2c /* Signature Data Register 6 */
#define DCI_SIGNATURE_DATA_7 0x00001c30 /* Signature Data Register 7 */
/****************************************************************************
* BCM70012_TGT_TOP_INTR
***************************************************************************/
/****************************************************************************
* INTR :: INTR_STATUS
***************************************************************************/
/* INTR :: INTR_STATUS :: reserved0 [31:26] */
#define INTR_INTR_STATUS_reserved0_MASK 0xfc000000
#define INTR_INTR_STATUS_reserved0_ALIGN 0
#define INTR_INTR_STATUS_reserved0_BITS 6
#define INTR_INTR_STATUS_reserved0_SHIFT 26
/* INTR :: INTR_STATUS :: PCIE_TGT_CA_ATTN [25:25] */
#define INTR_INTR_STATUS_PCIE_TGT_CA_ATTN_MASK 0x02000000
#define INTR_INTR_STATUS_PCIE_TGT_CA_ATTN_ALIGN 0
#define INTR_INTR_STATUS_PCIE_TGT_CA_ATTN_BITS 1
#define INTR_INTR_STATUS_PCIE_TGT_CA_ATTN_SHIFT 25
/* INTR :: INTR_STATUS :: PCIE_TGT_UR_ATTN [24:24] */
#define INTR_INTR_STATUS_PCIE_TGT_UR_ATTN_MASK 0x01000000
#define INTR_INTR_STATUS_PCIE_TGT_UR_ATTN_ALIGN 0
#define INTR_INTR_STATUS_PCIE_TGT_UR_ATTN_BITS 1
#define INTR_INTR_STATUS_PCIE_TGT_UR_ATTN_SHIFT 24
/* INTR :: INTR_STATUS :: reserved1 [23:14] */
#define INTR_INTR_STATUS_reserved1_MASK 0x00ffc000
#define INTR_INTR_STATUS_reserved1_ALIGN 0
#define INTR_INTR_STATUS_reserved1_BITS 10
#define INTR_INTR_STATUS_reserved1_SHIFT 14
/* INTR :: INTR_STATUS :: L1_UV_RX_DMA_ERR_INTR [13:13] */
#define INTR_INTR_STATUS_L1_UV_RX_DMA_ERR_INTR_MASK 0x00002000
#define INTR_INTR_STATUS_L1_UV_RX_DMA_ERR_INTR_ALIGN 0
#define INTR_INTR_STATUS_L1_UV_RX_DMA_ERR_INTR_BITS 1
#define INTR_INTR_STATUS_L1_UV_RX_DMA_ERR_INTR_SHIFT 13
/* INTR :: INTR_STATUS :: L1_UV_RX_DMA_DONE_INTR [12:12] */
#define INTR_INTR_STATUS_L1_UV_RX_DMA_DONE_INTR_MASK 0x00001000
#define INTR_INTR_STATUS_L1_UV_RX_DMA_DONE_INTR_ALIGN 0
#define INTR_INTR_STATUS_L1_UV_RX_DMA_DONE_INTR_BITS 1
#define INTR_INTR_STATUS_L1_UV_RX_DMA_DONE_INTR_SHIFT 12
/* INTR :: INTR_STATUS :: L1_Y_RX_DMA_ERR_INTR [11:11] */
#define INTR_INTR_STATUS_L1_Y_RX_DMA_ERR_INTR_MASK 0x00000800
#define INTR_INTR_STATUS_L1_Y_RX_DMA_ERR_INTR_ALIGN 0
#define INTR_INTR_STATUS_L1_Y_RX_DMA_ERR_INTR_BITS 1
#define INTR_INTR_STATUS_L1_Y_RX_DMA_ERR_INTR_SHIFT 11
/* INTR :: INTR_STATUS :: L1_Y_RX_DMA_DONE_INTR [10:10] */
#define INTR_INTR_STATUS_L1_Y_RX_DMA_DONE_INTR_MASK 0x00000400
#define INTR_INTR_STATUS_L1_Y_RX_DMA_DONE_INTR_ALIGN 0
#define INTR_INTR_STATUS_L1_Y_RX_DMA_DONE_INTR_BITS 1
#define INTR_INTR_STATUS_L1_Y_RX_DMA_DONE_INTR_SHIFT 10
/* INTR :: INTR_STATUS :: L1_TX_DMA_ERR_INTR [09:09] */
#define INTR_INTR_STATUS_L1_TX_DMA_ERR_INTR_MASK 0x00000200
#define INTR_INTR_STATUS_L1_TX_DMA_ERR_INTR_ALIGN 0
#define INTR_INTR_STATUS_L1_TX_DMA_ERR_INTR_BITS 1
#define INTR_INTR_STATUS_L1_TX_DMA_ERR_INTR_SHIFT 9
/* INTR :: INTR_STATUS :: L1_TX_DMA_DONE_INTR [08:08] */
#define INTR_INTR_STATUS_L1_TX_DMA_DONE_INTR_MASK 0x00000100
#define INTR_INTR_STATUS_L1_TX_DMA_DONE_INTR_ALIGN 0
#define INTR_INTR_STATUS_L1_TX_DMA_DONE_INTR_BITS 1
#define INTR_INTR_STATUS_L1_TX_DMA_DONE_INTR_SHIFT 8
/* INTR :: INTR_STATUS :: reserved2 [07:06] */
#define INTR_INTR_STATUS_reserved2_MASK 0x000000c0
#define INTR_INTR_STATUS_reserved2_ALIGN 0
#define INTR_INTR_STATUS_reserved2_BITS 2
#define INTR_INTR_STATUS_reserved2_SHIFT 6
/* INTR :: INTR_STATUS :: L0_UV_RX_DMA_ERR_INTR [05:05] */
#define INTR_INTR_STATUS_L0_UV_RX_DMA_ERR_INTR_MASK 0x00000020
#define INTR_INTR_STATUS_L0_UV_RX_DMA_ERR_INTR_ALIGN 0
#define INTR_INTR_STATUS_L0_UV_RX_DMA_ERR_INTR_BITS 1
#define INTR_INTR_STATUS_L0_UV_RX_DMA_ERR_INTR_SHIFT 5
/* INTR :: INTR_STATUS :: L0_UV_RX_DMA_DONE_INTR [04:04] */
#define INTR_INTR_STATUS_L0_UV_RX_DMA_DONE_INTR_MASK 0x00000010
#define INTR_INTR_STATUS_L0_UV_RX_DMA_DONE_INTR_ALIGN 0
#define INTR_INTR_STATUS_L0_UV_RX_DMA_DONE_INTR_BITS 1
#define INTR_INTR_STATUS_L0_UV_RX_DMA_DONE_INTR_SHIFT 4
/* INTR :: INTR_STATUS :: L0_Y_RX_DMA_ERR_INTR [03:03] */
#define INTR_INTR_STATUS_L0_Y_RX_DMA_ERR_INTR_MASK 0x00000008
#define INTR_INTR_STATUS_L0_Y_RX_DMA_ERR_INTR_ALIGN 0
#define INTR_INTR_STATUS_L0_Y_RX_DMA_ERR_INTR_BITS 1
#define INTR_INTR_STATUS_L0_Y_RX_DMA_ERR_INTR_SHIFT 3
/* INTR :: INTR_STATUS :: L0_Y_RX_DMA_DONE_INTR [02:02] */
#define INTR_INTR_STATUS_L0_Y_RX_DMA_DONE_INTR_MASK 0x00000004
#define INTR_INTR_STATUS_L0_Y_RX_DMA_DONE_INTR_ALIGN 0
#define INTR_INTR_STATUS_L0_Y_RX_DMA_DONE_INTR_BITS 1
#define INTR_INTR_STATUS_L0_Y_RX_DMA_DONE_INTR_SHIFT 2
/* INTR :: INTR_STATUS :: L0_TX_DMA_ERR_INTR [01:01] */
#define INTR_INTR_STATUS_L0_TX_DMA_ERR_INTR_MASK 0x00000002
#define INTR_INTR_STATUS_L0_TX_DMA_ERR_INTR_ALIGN 0
#define INTR_INTR_STATUS_L0_TX_DMA_ERR_INTR_BITS 1
#define INTR_INTR_STATUS_L0_TX_DMA_ERR_INTR_SHIFT 1
/* INTR :: INTR_STATUS :: L0_TX_DMA_DONE_INTR [00:00] */
#define INTR_INTR_STATUS_L0_TX_DMA_DONE_INTR_MASK 0x00000001
#define INTR_INTR_STATUS_L0_TX_DMA_DONE_INTR_ALIGN 0
#define INTR_INTR_STATUS_L0_TX_DMA_DONE_INTR_BITS 1
#define INTR_INTR_STATUS_L0_TX_DMA_DONE_INTR_SHIFT 0
/****************************************************************************
* MISC1 :: TX_SW_DESC_LIST_CTRL_STS
***************************************************************************/
/* MISC1 :: TX_SW_DESC_LIST_CTRL_STS :: reserved0 [31:04] */
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_reserved0_MASK 0xfffffff0
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_reserved0_ALIGN 0
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_reserved0_BITS 28
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_reserved0_SHIFT 4
/* MISC1 :: TX_SW_DESC_LIST_CTRL_STS :: DMA_DATA_SERV_PTR [03:03] */
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_DMA_DATA_SERV_PTR_MASK 0x00000008
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_DMA_DATA_SERV_PTR_ALIGN 0
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_DMA_DATA_SERV_PTR_BITS 1
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_DMA_DATA_SERV_PTR_SHIFT 3
/* MISC1 :: TX_SW_DESC_LIST_CTRL_STS :: DESC_SERV_PTR [02:02] */
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_DESC_SERV_PTR_MASK 0x00000004
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_DESC_SERV_PTR_ALIGN 0
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_DESC_SERV_PTR_BITS 1
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_DESC_SERV_PTR_SHIFT 2
/* MISC1 :: TX_SW_DESC_LIST_CTRL_STS :: TX_DMA_HALT_ON_ERROR [01:01] */
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_TX_DMA_HALT_ON_ERROR_MASK 0x00000002
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_TX_DMA_HALT_ON_ERROR_ALIGN 0
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_TX_DMA_HALT_ON_ERROR_BITS 1
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_TX_DMA_HALT_ON_ERROR_SHIFT 1
/* MISC1 :: TX_SW_DESC_LIST_CTRL_STS :: TX_DMA_RUN_STOP [00:00] */
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_TX_DMA_RUN_STOP_MASK 0x00000001
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_TX_DMA_RUN_STOP_ALIGN 0
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_TX_DMA_RUN_STOP_BITS 1
#define MISC1_TX_SW_DESC_LIST_CTRL_STS_TX_DMA_RUN_STOP_SHIFT 0
/****************************************************************************
* MISC1 :: TX_DMA_ERROR_STATUS
***************************************************************************/
/* MISC1 :: TX_DMA_ERROR_STATUS :: reserved0 [31:10] */
#define MISC1_TX_DMA_ERROR_STATUS_reserved0_MASK 0xfffffc00
#define MISC1_TX_DMA_ERROR_STATUS_reserved0_ALIGN 0
#define MISC1_TX_DMA_ERROR_STATUS_reserved0_BITS 22
#define MISC1_TX_DMA_ERROR_STATUS_reserved0_SHIFT 10
/* MISC1 :: TX_DMA_ERROR_STATUS :: TX_L1_DESC_TX_ABORT_ERRORS [09:09] */
#define MISC1_TX_DMA_ERROR_STATUS_TX_L1_DESC_TX_ABORT_ERRORS_MASK 0x00000200
#define MISC1_TX_DMA_ERROR_STATUS_TX_L1_DESC_TX_ABORT_ERRORS_ALIGN 0
#define MISC1_TX_DMA_ERROR_STATUS_TX_L1_DESC_TX_ABORT_ERRORS_BITS 1
#define MISC1_TX_DMA_ERROR_STATUS_TX_L1_DESC_TX_ABORT_ERRORS_SHIFT 9
/* MISC1 :: TX_DMA_ERROR_STATUS :: reserved1 [08:08] */
#define MISC1_TX_DMA_ERROR_STATUS_reserved1_MASK 0x00000100
#define MISC1_TX_DMA_ERROR_STATUS_reserved1_ALIGN 0
#define MISC1_TX_DMA_ERROR_STATUS_reserved1_BITS 1
#define MISC1_TX_DMA_ERROR_STATUS_reserved1_SHIFT 8
/* MISC1 :: TX_DMA_ERROR_STATUS :: TX_L0_DESC_TX_ABORT_ERRORS [07:07] */
#define MISC1_TX_DMA_ERROR_STATUS_TX_L0_DESC_TX_ABORT_ERRORS_MASK 0x00000080
#define MISC1_TX_DMA_ERROR_STATUS_TX_L0_DESC_TX_ABORT_ERRORS_ALIGN 0
#define MISC1_TX_DMA_ERROR_STATUS_TX_L0_DESC_TX_ABORT_ERRORS_BITS 1
#define MISC1_TX_DMA_ERROR_STATUS_TX_L0_DESC_TX_ABORT_ERRORS_SHIFT 7
/* MISC1 :: TX_DMA_ERROR_STATUS :: reserved2 [06:06] */
#define MISC1_TX_DMA_ERROR_STATUS_reserved2_MASK 0x00000040
#define MISC1_TX_DMA_ERROR_STATUS_reserved2_ALIGN 0
#define MISC1_TX_DMA_ERROR_STATUS_reserved2_BITS 1
#define MISC1_TX_DMA_ERROR_STATUS_reserved2_SHIFT 6
/* MISC1 :: TX_DMA_ERROR_STATUS :: TX_L1_DMA_DATA_TX_ABORT_ERRORS [05:05] */
#define MISC1_TX_DMA_ERROR_STATUS_TX_L1_DMA_DATA_TX_ABORT_ERRORS_MASK 0x00000020
#define MISC1_TX_DMA_ERROR_STATUS_TX_L1_DMA_DATA_TX_ABORT_ERRORS_ALIGN 0
#define MISC1_TX_DMA_ERROR_STATUS_TX_L1_DMA_DATA_TX_ABORT_ERRORS_BITS 1
#define MISC1_TX_DMA_ERROR_STATUS_TX_L1_DMA_DATA_TX_ABORT_ERRORS_SHIFT 5
/* MISC1 :: TX_DMA_ERROR_STATUS :: TX_L1_FIFO_FULL_ERRORS [04:04] */
#define MISC1_TX_DMA_ERROR_STATUS_TX_L1_FIFO_FULL_ERRORS_MASK 0x00000010
#define MISC1_TX_DMA_ERROR_STATUS_TX_L1_FIFO_FULL_ERRORS_ALIGN 0
#define MISC1_TX_DMA_ERROR_STATUS_TX_L1_FIFO_FULL_ERRORS_BITS 1
#define MISC1_TX_DMA_ERROR_STATUS_TX_L1_FIFO_FULL_ERRORS_SHIFT 4
/* MISC1 :: TX_DMA_ERROR_STATUS :: reserved3 [03:03] */
#define MISC1_TX_DMA_ERROR_STATUS_reserved3_MASK 0x00000008
#define MISC1_TX_DMA_ERROR_STATUS_reserved3_ALIGN 0
#define MISC1_TX_DMA_ERROR_STATUS_reserved3_BITS 1
#define MISC1_TX_DMA_ERROR_STATUS_reserved3_SHIFT 3
/* MISC1 :: TX_DMA_ERROR_STATUS :: TX_L0_DMA_DATA_TX_ABORT_ERRORS [02:02] */
#define MISC1_TX_DMA_ERROR_STATUS_TX_L0_DMA_DATA_TX_ABORT_ERRORS_MASK 0x00000004
#define MISC1_TX_DMA_ERROR_STATUS_TX_L0_DMA_DATA_TX_ABORT_ERRORS_ALIGN 0
#define MISC1_TX_DMA_ERROR_STATUS_TX_L0_DMA_DATA_TX_ABORT_ERRORS_BITS 1
#define MISC1_TX_DMA_ERROR_STATUS_TX_L0_DMA_DATA_TX_ABORT_ERRORS_SHIFT 2
/* MISC1 :: TX_DMA_ERROR_STATUS :: TX_L0_FIFO_FULL_ERRORS [01:01] */
#define MISC1_TX_DMA_ERROR_STATUS_TX_L0_FIFO_FULL_ERRORS_MASK 0x00000002
#define MISC1_TX_DMA_ERROR_STATUS_TX_L0_FIFO_FULL_ERRORS_ALIGN 0
#define MISC1_TX_DMA_ERROR_STATUS_TX_L0_FIFO_FULL_ERRORS_BITS 1
#define MISC1_TX_DMA_ERROR_STATUS_TX_L0_FIFO_FULL_ERRORS_SHIFT 1
/* MISC1 :: TX_DMA_ERROR_STATUS :: reserved4 [00:00] */
#define MISC1_TX_DMA_ERROR_STATUS_reserved4_MASK 0x00000001
#define MISC1_TX_DMA_ERROR_STATUS_reserved4_ALIGN 0
#define MISC1_TX_DMA_ERROR_STATUS_reserved4_BITS 1
#define MISC1_TX_DMA_ERROR_STATUS_reserved4_SHIFT 0
/****************************************************************************
* MISC1 :: Y_RX_ERROR_STATUS
***************************************************************************/
/* MISC1 :: Y_RX_ERROR_STATUS :: reserved0 [31:14] */
#define MISC1_Y_RX_ERROR_STATUS_reserved0_MASK 0xffffc000
#define MISC1_Y_RX_ERROR_STATUS_reserved0_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_reserved0_BITS 18
#define MISC1_Y_RX_ERROR_STATUS_reserved0_SHIFT 14
/* MISC1 :: Y_RX_ERROR_STATUS :: RX_L1_UNDERRUN_ERROR [13:13] */
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_MASK 0x00002000
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_BITS 1
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_SHIFT 13
/* MISC1 :: Y_RX_ERROR_STATUS :: RX_L1_OVERRUN_ERROR [12:12] */
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_OVERRUN_ERROR_MASK 0x00001000
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_OVERRUN_ERROR_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_OVERRUN_ERROR_BITS 1
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_OVERRUN_ERROR_SHIFT 12
/* MISC1 :: Y_RX_ERROR_STATUS :: RX_L0_UNDERRUN_ERROR [11:11] */
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_MASK 0x00000800
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_BITS 1
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_SHIFT 11
/* MISC1 :: Y_RX_ERROR_STATUS :: RX_L0_OVERRUN_ERROR [10:10] */
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_OVERRUN_ERROR_MASK 0x00000400
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_OVERRUN_ERROR_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_OVERRUN_ERROR_BITS 1
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_OVERRUN_ERROR_SHIFT 10
/* MISC1 :: Y_RX_ERROR_STATUS :: RX_L1_DESC_TX_ABORT_ERRORS [09:09] */
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_DESC_TX_ABORT_ERRORS_MASK 0x00000200
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_DESC_TX_ABORT_ERRORS_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_DESC_TX_ABORT_ERRORS_BITS 1
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_DESC_TX_ABORT_ERRORS_SHIFT 9
/* MISC1 :: Y_RX_ERROR_STATUS :: reserved1 [08:08] */
#define MISC1_Y_RX_ERROR_STATUS_reserved1_MASK 0x00000100
#define MISC1_Y_RX_ERROR_STATUS_reserved1_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_reserved1_BITS 1
#define MISC1_Y_RX_ERROR_STATUS_reserved1_SHIFT 8
/* MISC1 :: Y_RX_ERROR_STATUS :: RX_L0_DESC_TX_ABORT_ERRORS [07:07] */
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_DESC_TX_ABORT_ERRORS_MASK 0x00000080
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_DESC_TX_ABORT_ERRORS_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_DESC_TX_ABORT_ERRORS_BITS 1
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_DESC_TX_ABORT_ERRORS_SHIFT 7
/* MISC1 :: Y_RX_ERROR_STATUS :: reserved2 [06:05] */
#define MISC1_Y_RX_ERROR_STATUS_reserved2_MASK 0x00000060
#define MISC1_Y_RX_ERROR_STATUS_reserved2_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_reserved2_BITS 2
#define MISC1_Y_RX_ERROR_STATUS_reserved2_SHIFT 5
/* MISC1 :: Y_RX_ERROR_STATUS :: RX_L1_FIFO_FULL_ERRORS [04:04] */
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_MASK 0x00000010
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_BITS 1
#define MISC1_Y_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_SHIFT 4
/* MISC1 :: Y_RX_ERROR_STATUS :: reserved3 [03:02] */
#define MISC1_Y_RX_ERROR_STATUS_reserved3_MASK 0x0000000c
#define MISC1_Y_RX_ERROR_STATUS_reserved3_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_reserved3_BITS 2
#define MISC1_Y_RX_ERROR_STATUS_reserved3_SHIFT 2
/* MISC1 :: Y_RX_ERROR_STATUS :: RX_L0_FIFO_FULL_ERRORS [01:01] */
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_MASK 0x00000002
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_BITS 1
#define MISC1_Y_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_SHIFT 1
/* MISC1 :: Y_RX_ERROR_STATUS :: reserved4 [00:00] */
#define MISC1_Y_RX_ERROR_STATUS_reserved4_MASK 0x00000001
#define MISC1_Y_RX_ERROR_STATUS_reserved4_ALIGN 0
#define MISC1_Y_RX_ERROR_STATUS_reserved4_BITS 1
#define MISC1_Y_RX_ERROR_STATUS_reserved4_SHIFT 0
/****************************************************************************
* MISC1 :: UV_RX_ERROR_STATUS
***************************************************************************/
/* MISC1 :: UV_RX_ERROR_STATUS :: reserved0 [31:14] */
#define MISC1_UV_RX_ERROR_STATUS_reserved0_MASK 0xffffc000
#define MISC1_UV_RX_ERROR_STATUS_reserved0_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_reserved0_BITS 18
#define MISC1_UV_RX_ERROR_STATUS_reserved0_SHIFT 14
/* MISC1 :: UV_RX_ERROR_STATUS :: RX_L1_UNDERRUN_ERROR [13:13] */
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_MASK 0x00002000
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_BITS 1
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_SHIFT 13
/* MISC1 :: UV_RX_ERROR_STATUS :: RX_L1_OVERRUN_ERROR [12:12] */
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_OVERRUN_ERROR_MASK 0x00001000
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_OVERRUN_ERROR_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_OVERRUN_ERROR_BITS 1
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_OVERRUN_ERROR_SHIFT 12
/* MISC1 :: UV_RX_ERROR_STATUS :: RX_L0_UNDERRUN_ERROR [11:11] */
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_MASK 0x00000800
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_BITS 1
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_SHIFT 11
/* MISC1 :: UV_RX_ERROR_STATUS :: RX_L0_OVERRUN_ERROR [10:10] */
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_OVERRUN_ERROR_MASK 0x00000400
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_OVERRUN_ERROR_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_OVERRUN_ERROR_BITS 1
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_OVERRUN_ERROR_SHIFT 10
/* MISC1 :: UV_RX_ERROR_STATUS :: RX_L1_DESC_TX_ABORT_ERRORS [09:09] */
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_DESC_TX_ABORT_ERRORS_MASK 0x00000200
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_DESC_TX_ABORT_ERRORS_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_DESC_TX_ABORT_ERRORS_BITS 1
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_DESC_TX_ABORT_ERRORS_SHIFT 9
/* MISC1 :: UV_RX_ERROR_STATUS :: reserved1 [08:08] */
#define MISC1_UV_RX_ERROR_STATUS_reserved1_MASK 0x00000100
#define MISC1_UV_RX_ERROR_STATUS_reserved1_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_reserved1_BITS 1
#define MISC1_UV_RX_ERROR_STATUS_reserved1_SHIFT 8
/* MISC1 :: UV_RX_ERROR_STATUS :: RX_L0_DESC_TX_ABORT_ERRORS [07:07] */
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_DESC_TX_ABORT_ERRORS_MASK 0x00000080
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_DESC_TX_ABORT_ERRORS_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_DESC_TX_ABORT_ERRORS_BITS 1
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_DESC_TX_ABORT_ERRORS_SHIFT 7
/* MISC1 :: UV_RX_ERROR_STATUS :: reserved2 [06:05] */
#define MISC1_UV_RX_ERROR_STATUS_reserved2_MASK 0x00000060
#define MISC1_UV_RX_ERROR_STATUS_reserved2_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_reserved2_BITS 2
#define MISC1_UV_RX_ERROR_STATUS_reserved2_SHIFT 5
/* MISC1 :: UV_RX_ERROR_STATUS :: RX_L1_FIFO_FULL_ERRORS [04:04] */
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_MASK 0x00000010
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_BITS 1
#define MISC1_UV_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_SHIFT 4
/* MISC1 :: UV_RX_ERROR_STATUS :: reserved3 [03:02] */
#define MISC1_UV_RX_ERROR_STATUS_reserved3_MASK 0x0000000c
#define MISC1_UV_RX_ERROR_STATUS_reserved3_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_reserved3_BITS 2
#define MISC1_UV_RX_ERROR_STATUS_reserved3_SHIFT 2
/* MISC1 :: UV_RX_ERROR_STATUS :: RX_L0_FIFO_FULL_ERRORS [01:01] */
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_MASK 0x00000002
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_BITS 1
#define MISC1_UV_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_SHIFT 1
/* MISC1 :: UV_RX_ERROR_STATUS :: reserved4 [00:00] */
#define MISC1_UV_RX_ERROR_STATUS_reserved4_MASK 0x00000001
#define MISC1_UV_RX_ERROR_STATUS_reserved4_ALIGN 0
#define MISC1_UV_RX_ERROR_STATUS_reserved4_BITS 1
#define MISC1_UV_RX_ERROR_STATUS_reserved4_SHIFT 0
/****************************************************************************
* Datatype Definitions.
***************************************************************************/
#endif /* #ifndef MACFILE_H__ */
/* End of File */
drivers/staging/crystalhd/crystalhd.h deleted 100644 → 0
View file @ 895ae876
#ifndef _CRYSTALHD_H_
#define _CRYSTALHD_H_
#include "bc_dts_defs.h"
#include "crystalhd_misc.h"
#include "bc_dts_glob_lnx.h"
#include "crystalhd_hw.h"
#include "crystalhd_cmds.h"
#include "crystalhd_lnx.h"
#include "bcm_70012_regs.h"
#include "crystalhd_fw_if.h"
#endif
drivers/staging/crystalhd/crystalhd_cmds.c deleted 100644 → 0
View file @ 895ae876
/***************************************************************************
* Copyright (c) 2005-2009, Broadcom Corporation.
*
* Name: crystalhd_cmds . c
*
* Description:
* BCM70010 Linux driver user command interfaces.
*
* HISTORY:
*
**********************************************************************
* This file is part of the crystalhd device driver.
*
* This driver 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, version 2 of the License.
*
* This driver is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this driver. If not, see <http://www.gnu.org/licenses/>.
**********************************************************************/
#include "crystalhd.h"
static struct crystalhd_user *bc_cproc_get_uid(struct crystalhd_cmd *ctx)
{
struct crystalhd_user *user = NULL;
int i;
for (i = 0; i < BC_LINK_MAX_OPENS; i++) {
if (!ctx->user[i].in_use) {
user = &ctx->user[i];
break;
}
}
return user;
}
static int bc_cproc_get_user_count(struct crystalhd_cmd *ctx)
{
int i, count = 0;
for (i = 0; i < BC_LINK_MAX_OPENS; i++) {
if (ctx->user[i].in_use)
count++;
}
return count;
}
static void bc_cproc_mark_pwr_state(struct crystalhd_cmd *ctx)
{
int i;
for (i = 0; i < BC_LINK_MAX_OPENS; i++) {
if (!ctx->user[i].in_use)
continue;
if (ctx->user[i].mode == DTS_DIAG_MODE ||
ctx->user[i].mode == DTS_PLAYBACK_MODE) {
ctx->pwr_state_change = 1;
break;
}
}
}
static enum BC_STATUS bc_cproc_notify_mode(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
int rc = 0, i = 0;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
if (ctx->user[idata->u_id].mode != DTS_MODE_INV) {
BCMLOG_ERR("Close the handle first..\n");
return BC_STS_ERR_USAGE;
}
if (idata->udata.u.NotifyMode.Mode == DTS_MONITOR_MODE) {
ctx->user[idata->u_id].mode = idata->udata.u.NotifyMode.Mode;
return BC_STS_SUCCESS;
}
if (ctx->state != BC_LINK_INVALID) {
BCMLOG_ERR("Link invalid state %d\n", ctx->state);
return BC_STS_ERR_USAGE;
}
/* Check for duplicate playback sessions..*/
for (i = 0; i < BC_LINK_MAX_OPENS; i++) {
if (ctx->user[i].mode == DTS_DIAG_MODE ||
ctx->user[i].mode == DTS_PLAYBACK_MODE) {
BCMLOG_ERR("multiple playback sessions are not supported..\n");
return BC_STS_ERR_USAGE;
}
}
ctx->cin_wait_exit = 0;
ctx->user[idata->u_id].mode = idata->udata.u.NotifyMode.Mode;
/* Setup mmap pool for uaddr sgl mapping..*/
rc = crystalhd_create_dio_pool(ctx->adp, BC_LINK_MAX_SGLS);
if (rc)
return BC_STS_ERROR;
/* Setup Hardware DMA rings */
return crystalhd_hw_setup_dma_rings(&ctx->hw_ctx);
}
static enum BC_STATUS bc_cproc_get_version(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
idata->udata.u.VerInfo.DriverMajor = crystalhd_kmod_major;
idata->udata.u.VerInfo.DriverMinor = crystalhd_kmod_minor;
idata->udata.u.VerInfo.DriverRevision = crystalhd_kmod_rev;
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_get_hwtype(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
crystalhd_pci_cfg_rd(ctx->adp, 0, 2,
(uint32_t *)&idata->udata.u.hwType.PciVenId);
crystalhd_pci_cfg_rd(ctx->adp, 2, 2,
(uint32_t *)&idata->udata.u.hwType.PciDevId);
crystalhd_pci_cfg_rd(ctx->adp, 8, 1,
(uint32_t *)&idata->udata.u.hwType.HwRev);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_reg_rd(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
if (!ctx || !idata)
return BC_STS_INV_ARG;
idata->udata.u.regAcc.Value = bc_dec_reg_rd(ctx->adp,
idata->udata.u.regAcc.Offset);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_reg_wr(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
if (!ctx || !idata)
return BC_STS_INV_ARG;
bc_dec_reg_wr(ctx->adp, idata->udata.u.regAcc.Offset,
idata->udata.u.regAcc.Value);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_link_reg_rd(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
if (!ctx || !idata)
return BC_STS_INV_ARG;
idata->udata.u.regAcc.Value = crystalhd_reg_rd(ctx->adp,
idata->udata.u.regAcc.Offset);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_link_reg_wr(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
if (!ctx || !idata)
return BC_STS_INV_ARG;
crystalhd_reg_wr(ctx->adp, idata->udata.u.regAcc.Offset,
idata->udata.u.regAcc.Value);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_mem_rd(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata || !idata->add_cdata)
return BC_STS_INV_ARG;
if (idata->udata.u.devMem.NumDwords > (idata->add_cdata_sz / 4)) {
BCMLOG_ERR("insufficient buffer\n");
return BC_STS_INV_ARG;
}
sts = crystalhd_mem_rd(ctx->adp, idata->udata.u.devMem.StartOff,
idata->udata.u.devMem.NumDwords,
(uint32_t *)idata->add_cdata);
return sts;
}
static enum BC_STATUS bc_cproc_mem_wr(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata || !idata->add_cdata)
return BC_STS_INV_ARG;
if (idata->udata.u.devMem.NumDwords > (idata->add_cdata_sz / 4)) {
BCMLOG_ERR("insufficient buffer\n");
return BC_STS_INV_ARG;
}
sts = crystalhd_mem_wr(ctx->adp, idata->udata.u.devMem.StartOff,
idata->udata.u.devMem.NumDwords,
(uint32_t *)idata->add_cdata);
return sts;
}
static enum BC_STATUS bc_cproc_cfg_rd(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
uint32_t ix, cnt, off, len;
enum BC_STATUS sts = BC_STS_SUCCESS;
uint32_t *temp;
if (!ctx || !idata)
return BC_STS_INV_ARG;
temp = (uint32_t *) idata->udata.u.pciCfg.pci_cfg_space;
off = idata->udata.u.pciCfg.Offset;
len = idata->udata.u.pciCfg.Size;
if (len <= 4)
return crystalhd_pci_cfg_rd(ctx->adp, off, len, temp);
/* Truncate to dword alignment..*/
len = 4;
cnt = idata->udata.u.pciCfg.Size / len;
for (ix = 0; ix < cnt; ix++) {
sts = crystalhd_pci_cfg_rd(ctx->adp, off, len, &temp[ix]);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("config read : %d\n", sts);
return sts;
}
off += len;
}
return sts;
}
static enum BC_STATUS bc_cproc_cfg_wr(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
uint32_t ix, cnt, off, len;
enum BC_STATUS sts = BC_STS_SUCCESS;
uint32_t *temp;
if (!ctx || !idata)
return BC_STS_INV_ARG;
temp = (uint32_t *) idata->udata.u.pciCfg.pci_cfg_space;
off = idata->udata.u.pciCfg.Offset;
len = idata->udata.u.pciCfg.Size;
if (len <= 4)
return crystalhd_pci_cfg_wr(ctx->adp, off, len, temp[0]);
/* Truncate to dword alignment..*/
len = 4;
cnt = idata->udata.u.pciCfg.Size / len;
for (ix = 0; ix < cnt; ix++) {
sts = crystalhd_pci_cfg_wr(ctx->adp, off, len, temp[ix]);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("config write : %d\n", sts);
return sts;
}
off += len;
}
return sts;
}
static enum BC_STATUS bc_cproc_download_fw(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata || !idata->add_cdata || !idata->add_cdata_sz) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
if (ctx->state != BC_LINK_INVALID) {
BCMLOG_ERR("Link invalid state %d\n", ctx->state);
return BC_STS_ERR_USAGE;
}
sts = crystalhd_download_fw(ctx->adp, (uint8_t *)idata->add_cdata,
idata->add_cdata_sz);
if (sts != BC_STS_SUCCESS)
BCMLOG_ERR("Firmware Download Failure!! - %d\n", sts);
else
ctx->state |= BC_LINK_INIT;
return sts;
}
/*
* We use the FW_CMD interface to sync up playback state with application
* and firmware. This function will perform the required pre and post
* processing of the Firmware commands.
*
* Pause -
* Disable capture after decoder pause.
* Resume -
* First enable capture and issue decoder resume command.
* Flush -
* Abort pending input transfers and issue decoder flush command.
*
*/
static enum BC_STATUS bc_cproc_do_fw_cmd(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
enum BC_STATUS sts;
uint32_t *cmd;
if (!(ctx->state & BC_LINK_INIT)) {
BCMLOG_ERR("Link invalid state %d\n", ctx->state);
return BC_STS_ERR_USAGE;
}
cmd = idata->udata.u.fwCmd.cmd;
/* Pre-Process */
if (cmd[0] == eCMD_C011_DEC_CHAN_PAUSE) {
if (!cmd[3]) {
ctx->state &= ~BC_LINK_PAUSED;
crystalhd_hw_unpause(&ctx->hw_ctx);
}
} else if (cmd[0] == eCMD_C011_DEC_CHAN_FLUSH) {
BCMLOG(BCMLOG_INFO, "Flush issued\n");
if (cmd[3])
ctx->cin_wait_exit = 1;
}
sts = crystalhd_do_fw_cmd(&ctx->hw_ctx, &idata->udata.u.fwCmd);
if (sts != BC_STS_SUCCESS) {
BCMLOG(BCMLOG_INFO, "fw cmd %x failed\n", cmd[0]);
return sts;
}
/* Post-Process */
if (cmd[0] == eCMD_C011_DEC_CHAN_PAUSE) {
if (cmd[3]) {
ctx->state |= BC_LINK_PAUSED;
crystalhd_hw_pause(&ctx->hw_ctx);
}
}
return sts;
}
static void bc_proc_in_completion(struct crystalhd_dio_req *dio_hnd,
wait_queue_head_t *event, enum BC_STATUS sts)
{
if (!dio_hnd || !event) {
BCMLOG_ERR("Invalid Arg!!\n");
return;
}
if (sts == BC_STS_IO_USER_ABORT)
return;
dio_hnd->uinfo.comp_sts = sts;
dio_hnd->uinfo.ev_sts = 1;
crystalhd_set_event(event);
}
static enum BC_STATUS bc_cproc_codein_sleep(struct crystalhd_cmd *ctx)
{
wait_queue_head_t sleep_ev;
int rc = 0;
if (ctx->state & BC_LINK_SUSPEND)
return BC_STS_IO_USER_ABORT;
if (ctx->cin_wait_exit) {
ctx->cin_wait_exit = 0;
return BC_STS_CMD_CANCELLED;
}
crystalhd_create_event(&sleep_ev);
crystalhd_wait_on_event(&sleep_ev, 0, 100, rc, 0);
if (rc == -EINTR)
return BC_STS_IO_USER_ABORT;
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_hw_txdma(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata,
struct crystalhd_dio_req *dio)
{
uint32_t tx_listid = 0;
enum BC_STATUS sts = BC_STS_SUCCESS;
wait_queue_head_t event;
int rc = 0;
if (!ctx || !idata || !dio) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
crystalhd_create_event(&event);
ctx->tx_list_id = 0;
/* msleep_interruptible(2000); */
sts = crystalhd_hw_post_tx(&ctx->hw_ctx, dio, bc_proc_in_completion,
&event, &tx_listid,
idata->udata.u.ProcInput.Encrypted);
while (sts == BC_STS_BUSY) {
sts = bc_cproc_codein_sleep(ctx);
if (sts != BC_STS_SUCCESS)
break;
sts = crystalhd_hw_post_tx(&ctx->hw_ctx, dio,
bc_proc_in_completion,
&event, &tx_listid,
idata->udata.u.ProcInput.Encrypted);
}
if (sts != BC_STS_SUCCESS) {
BCMLOG(BCMLOG_DBG, "_hw_txdma returning sts:%d\n", sts);
return sts;
}
if (ctx->cin_wait_exit)
ctx->cin_wait_exit = 0;
ctx->tx_list_id = tx_listid;
/* _post() succeeded.. wait for the completion. */
crystalhd_wait_on_event(&event, (dio->uinfo.ev_sts), 3000, rc, 0);
ctx->tx_list_id = 0;
if (!rc) {
return dio->uinfo.comp_sts;
} else if (rc == -EBUSY) {
BCMLOG(BCMLOG_DBG, "_tx_post() T/O\n");
sts = BC_STS_TIMEOUT;
} else if (rc == -EINTR) {
BCMLOG(BCMLOG_DBG, "Tx Wait Signal int.\n");
sts = BC_STS_IO_USER_ABORT;
} else {
sts = BC_STS_IO_ERROR;
}
/* We are cancelling the IO from the same context as the _post().
* so no need to wait on the event again.. the return itself
* ensures the release of our resources.
*/
crystalhd_hw_cancel_tx(&ctx->hw_ctx, tx_listid);
return sts;
}
/* Helper function to check on user buffers */
static enum BC_STATUS bc_cproc_check_inbuffs(bool pin, void *ubuff,
uint32_t ub_sz, uint32_t uv_off, bool en_422)
{
if (!ubuff || !ub_sz) {
BCMLOG_ERR("%s->Invalid Arg %p %x\n",
((pin) ? "TX" : "RX"), ubuff, ub_sz);
return BC_STS_INV_ARG;
}
/* Check for alignment */
if (((uintptr_t)ubuff) & 0x03) {
BCMLOG_ERR(
"%s-->Un-aligned address not implemented yet.. %p\n",
((pin) ? "TX" : "RX"), ubuff);
return BC_STS_NOT_IMPL;
}
if (pin)
return BC_STS_SUCCESS;
if (!en_422 && !uv_off) {
BCMLOG_ERR("Need UV offset for 420 mode.\n");
return BC_STS_INV_ARG;
}
if (en_422 && uv_off) {
BCMLOG_ERR("UV offset in 422 mode ??\n");
return BC_STS_INV_ARG;
}
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_proc_input(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
void *ubuff;
uint32_t ub_sz;
struct crystalhd_dio_req *dio_hnd = NULL;
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
ubuff = idata->udata.u.ProcInput.pDmaBuff;
ub_sz = idata->udata.u.ProcInput.BuffSz;
sts = bc_cproc_check_inbuffs(1, ubuff, ub_sz, 0, 0);
if (sts != BC_STS_SUCCESS)
return sts;
sts = crystalhd_map_dio(ctx->adp, ubuff, ub_sz, 0, 0, 1, &dio_hnd);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("dio map - %d\n", sts);
return sts;
}
if (!dio_hnd)
return BC_STS_ERROR;
sts = bc_cproc_hw_txdma(ctx, idata, dio_hnd);
crystalhd_unmap_dio(ctx->adp, dio_hnd);
return sts;
}
static enum BC_STATUS bc_cproc_add_cap_buff(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
void *ubuff;
uint32_t ub_sz, uv_off;
bool en_422;
struct crystalhd_dio_req *dio_hnd = NULL;
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
ubuff = idata->udata.u.RxBuffs.YuvBuff;
ub_sz = idata->udata.u.RxBuffs.YuvBuffSz;
uv_off = idata->udata.u.RxBuffs.UVbuffOffset;
en_422 = idata->udata.u.RxBuffs.b422Mode;
sts = bc_cproc_check_inbuffs(0, ubuff, ub_sz, uv_off, en_422);
if (sts != BC_STS_SUCCESS)
return sts;
sts = crystalhd_map_dio(ctx->adp, ubuff, ub_sz, uv_off,
en_422, 0, &dio_hnd);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("dio map - %d\n", sts);
return sts;
}
if (!dio_hnd)
return BC_STS_ERROR;
sts = crystalhd_hw_add_cap_buffer(&ctx->hw_ctx, dio_hnd,
(ctx->state == BC_LINK_READY));
if ((sts != BC_STS_SUCCESS) && (sts != BC_STS_BUSY)) {
crystalhd_unmap_dio(ctx->adp, dio_hnd);
return sts;
}
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_fmt_change(struct crystalhd_cmd *ctx,
struct crystalhd_dio_req *dio)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
sts = crystalhd_hw_add_cap_buffer(&ctx->hw_ctx, dio, 0);
if (sts != BC_STS_SUCCESS)
return sts;
ctx->state |= BC_LINK_FMT_CHG;
if (ctx->state == BC_LINK_READY)
sts = crystalhd_hw_start_capture(&ctx->hw_ctx);
return sts;
}
static enum BC_STATUS bc_cproc_fetch_frame(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
struct crystalhd_dio_req *dio = NULL;
enum BC_STATUS sts = BC_STS_SUCCESS;
struct BC_DEC_OUT_BUFF *frame;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
if (!(ctx->state & BC_LINK_CAP_EN)) {
BCMLOG(BCMLOG_DBG, "Capture not enabled..%x\n", ctx->state);
return BC_STS_ERR_USAGE;
}
frame = &idata->udata.u.DecOutData;
sts = crystalhd_hw_get_cap_buffer(&ctx->hw_ctx, &frame->PibInfo, &dio);
if (sts != BC_STS_SUCCESS)
return (ctx->state & BC_LINK_SUSPEND) ?
BC_STS_IO_USER_ABORT : sts;
frame->Flags = dio->uinfo.comp_flags;
if (frame->Flags & COMP_FLAG_FMT_CHANGE)
return bc_cproc_fmt_change(ctx, dio);
frame->OutPutBuffs.YuvBuff = dio->uinfo.xfr_buff;
frame->OutPutBuffs.YuvBuffSz = dio->uinfo.xfr_len;
frame->OutPutBuffs.UVbuffOffset = dio->uinfo.uv_offset;
frame->OutPutBuffs.b422Mode = dio->uinfo.b422mode;
frame->OutPutBuffs.YBuffDoneSz = dio->uinfo.y_done_sz;
frame->OutPutBuffs.UVBuffDoneSz = dio->uinfo.uv_done_sz;
crystalhd_unmap_dio(ctx->adp, dio);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_start_capture(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
ctx->state |= BC_LINK_CAP_EN;
if (ctx->state == BC_LINK_READY)
return crystalhd_hw_start_capture(&ctx->hw_ctx);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_flush_cap_buffs(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
struct crystalhd_dio_req *dio = NULL;
enum BC_STATUS sts = BC_STS_SUCCESS;
struct BC_DEC_OUT_BUFF *frame;
uint32_t count;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
if (!(ctx->state & BC_LINK_CAP_EN))
return BC_STS_ERR_USAGE;
/* We should ack flush even when we are in paused/suspend state */
if (!(ctx->state & BC_LINK_READY))
return crystalhd_hw_stop_capture(&ctx->hw_ctx);
ctx->state &= ~(BC_LINK_CAP_EN|BC_LINK_FMT_CHG);
frame = &idata->udata.u.DecOutData;
for (count = 0; count < BC_RX_LIST_CNT; count++) {
sts = crystalhd_hw_get_cap_buffer(&ctx->hw_ctx,
&frame->PibInfo, &dio);
if (sts != BC_STS_SUCCESS)
break;
crystalhd_unmap_dio(ctx->adp, dio);
}
return crystalhd_hw_stop_capture(&ctx->hw_ctx);
}
static enum BC_STATUS bc_cproc_get_stats(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
struct BC_DTS_STATS *stats;
struct crystalhd_hw_stats hw_stats;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
crystalhd_hw_stats(&ctx->hw_ctx, &hw_stats);
stats = &idata->udata.u.drvStat;
stats->drvRLL = hw_stats.rdyq_count;
stats->drvFLL = hw_stats.freeq_count;
stats->DrvTotalFrmDropped = hw_stats.rx_errors;
stats->DrvTotalHWErrs = hw_stats.rx_errors + hw_stats.tx_errors;
stats->intCount = hw_stats.num_interrupts;
stats->DrvIgnIntrCnt = hw_stats.num_interrupts -
hw_stats.dev_interrupts;
stats->TxFifoBsyCnt = hw_stats.cin_busy;
stats->pauseCount = hw_stats.pause_cnt;
if (ctx->pwr_state_change)
stats->pwr_state_change = 1;
if (ctx->state & BC_LINK_PAUSED)
stats->DrvPauseTime = 1;
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_reset_stats(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
crystalhd_hw_stats(&ctx->hw_ctx, NULL);
return BC_STS_SUCCESS;
}
static enum BC_STATUS bc_cproc_chg_clk(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
struct BC_CLOCK *clock;
uint32_t oldClk;
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
clock = &idata->udata.u.clockValue;
oldClk = ctx->hw_ctx.core_clock_mhz;
ctx->hw_ctx.core_clock_mhz = clock->clk;
if (ctx->state & BC_LINK_READY) {
sts = crystalhd_hw_set_core_clock(&ctx->hw_ctx);
if (sts == BC_STS_CLK_NOCHG)
ctx->hw_ctx.core_clock_mhz = oldClk;
}
clock->clk = ctx->hw_ctx.core_clock_mhz;
return sts;
}
/*=============== Cmd Proc Table.. ======================================*/
static const struct crystalhd_cmd_tbl g_crystalhd_cproc_tbl[] = {
{ BCM_IOC_GET_VERSION, bc_cproc_get_version, 0},
{ BCM_IOC_GET_HWTYPE, bc_cproc_get_hwtype, 0},
{ BCM_IOC_REG_RD, bc_cproc_reg_rd, 0},
{ BCM_IOC_REG_WR, bc_cproc_reg_wr, 0},
{ BCM_IOC_FPGA_RD, bc_cproc_link_reg_rd, 0},
{ BCM_IOC_FPGA_WR, bc_cproc_link_reg_wr, 0},
{ BCM_IOC_MEM_RD, bc_cproc_mem_rd, 0},
{ BCM_IOC_MEM_WR, bc_cproc_mem_wr, 0},
{ BCM_IOC_RD_PCI_CFG, bc_cproc_cfg_rd, 0},
{ BCM_IOC_WR_PCI_CFG, bc_cproc_cfg_wr, 1},
{ BCM_IOC_FW_DOWNLOAD, bc_cproc_download_fw, 1},
{ BCM_IOC_FW_CMD, bc_cproc_do_fw_cmd, 1},
{ BCM_IOC_PROC_INPUT, bc_cproc_proc_input, 1},
{ BCM_IOC_ADD_RXBUFFS, bc_cproc_add_cap_buff, 1},
{ BCM_IOC_FETCH_RXBUFF, bc_cproc_fetch_frame, 1},
{ BCM_IOC_START_RX_CAP, bc_cproc_start_capture, 1},
{ BCM_IOC_FLUSH_RX_CAP, bc_cproc_flush_cap_buffs, 1},
{ BCM_IOC_GET_DRV_STAT, bc_cproc_get_stats, 0},
{ BCM_IOC_RST_DRV_STAT, bc_cproc_reset_stats, 0},
{ BCM_IOC_NOTIFY_MODE, bc_cproc_notify_mode, 0},
{ BCM_IOC_CHG_CLK, bc_cproc_chg_clk, 0},
{ BCM_IOC_END, NULL},
};
/*=============== Cmd Proc Functions.. ===================================*/
/**
* crystalhd_suspend - Power management suspend request.
* @ctx: Command layer context.
* @idata: Iodata - required for internal use.
*
* Return:
* status
*
* 1. Set the state to Suspend.
* 2. Flush the Rx Buffers it will unmap all the buffers and
* stop the RxDMA engine.
* 3. Cancel The TX Io and Stop Dma Engine.
* 4. Put the DDR in to deep sleep.
* 5. Stop the hardware putting it in to Reset State.
*
* Current gstreamer frame work does not provide any power management
* related notification to user mode decoder plug-in. As a work-around
* we pass on the power management notification to our plug-in by completing
* all outstanding requests with BC_STS_IO_USER_ABORT return code.
*/
enum BC_STATUS crystalhd_suspend(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!ctx || !idata) {
BCMLOG_ERR("Invalid Parameters\n");
return BC_STS_ERROR;
}
if (ctx->state & BC_LINK_SUSPEND)
return BC_STS_SUCCESS;
if (ctx->state == BC_LINK_INVALID) {
BCMLOG(BCMLOG_DBG, "Nothing To Do Suspend Success\n");
return BC_STS_SUCCESS;
}
ctx->state |= BC_LINK_SUSPEND;
bc_cproc_mark_pwr_state(ctx);
if (ctx->state & BC_LINK_CAP_EN) {
sts = bc_cproc_flush_cap_buffs(ctx, idata);
if (sts != BC_STS_SUCCESS)
return sts;
}
if (ctx->tx_list_id) {
sts = crystalhd_hw_cancel_tx(&ctx->hw_ctx, ctx->tx_list_id);
if (sts != BC_STS_SUCCESS)
return sts;
}
sts = crystalhd_hw_suspend(&ctx->hw_ctx);
if (sts != BC_STS_SUCCESS)
return sts;
BCMLOG(BCMLOG_DBG, "BCM70012 suspend success\n");
return BC_STS_SUCCESS;
}
/**
* crystalhd_resume - Resume frame capture.
* @ctx: Command layer contextx.
*
* Return:
* status
*
*
* Resume frame capture.
*
* PM_Resume can't resume the playback state back to pre-suspend state
* because we don't keep video clip related information within driver.
* To get back to the pre-suspend state App will re-open the device and
* start a new playback session from the pre-suspend clip position.
*
*/
enum BC_STATUS crystalhd_resume(struct crystalhd_cmd *ctx)
{
BCMLOG(BCMLOG_DBG, "crystalhd_resume Success %x\n", ctx->state);
bc_cproc_mark_pwr_state(ctx);
return BC_STS_SUCCESS;
}
/**
* crystalhd_user_open - Create application handle.
* @ctx: Command layer contextx.
* @user_ctx: User ID context.
*
* Return:
* status
*
* Creates an application specific UID and allocates
* application specific resources. HW layer initialization
* is done for the first open request.
*/
enum BC_STATUS crystalhd_user_open(struct crystalhd_cmd *ctx,
struct crystalhd_user **user_ctx)
{
struct crystalhd_user *uc;
if (!ctx || !user_ctx) {
BCMLOG_ERR("Invalid arg..\n");
return BC_STS_INV_ARG;
}
uc = bc_cproc_get_uid(ctx);
if (!uc) {
BCMLOG(BCMLOG_INFO, "No free user context...\n");
return BC_STS_BUSY;
}
BCMLOG(BCMLOG_INFO, "Opening new user[%x] handle\n", uc->uid);
crystalhd_hw_open(&ctx->hw_ctx, ctx->adp);
uc->in_use = 1;
*user_ctx = uc;
return BC_STS_SUCCESS;
}
/**
* crystalhd_user_close - Close application handle.
* @ctx: Command layer contextx.
* @uc: User ID context.
*
* Return:
* status
*
* Closer application handle and release app specific
* resources.
*/
enum BC_STATUS crystalhd_user_close(struct crystalhd_cmd *ctx,
struct crystalhd_user *uc)
{
uint32_t mode = uc->mode;
ctx->user[uc->uid].mode = DTS_MODE_INV;
ctx->user[uc->uid].in_use = 0;
ctx->cin_wait_exit = 1;
ctx->pwr_state_change = 0;
BCMLOG(BCMLOG_INFO, "Closing user[%x] handle\n", uc->uid);
if ((mode == DTS_DIAG_MODE) || (mode == DTS_PLAYBACK_MODE)) {
crystalhd_hw_free_dma_rings(&ctx->hw_ctx);
crystalhd_destroy_dio_pool(ctx->adp);
} else if (bc_cproc_get_user_count(ctx)) {
return BC_STS_SUCCESS;
}
crystalhd_hw_close(&ctx->hw_ctx);
ctx->state = BC_LINK_INVALID;
return BC_STS_SUCCESS;
}
/**
* crystalhd_setup_cmd_context - Setup Command layer resources.
* @ctx: Command layer contextx.
* @adp: Adapter context
*
* Return:
* status
*
* Called at the time of driver load.
*/
enum BC_STATUS crystalhd_setup_cmd_context(struct crystalhd_cmd *ctx,
struct crystalhd_adp *adp)
{
int i = 0;
if (!ctx || !adp) {
BCMLOG_ERR("Invalid arg!!\n");
return BC_STS_INV_ARG;
}
if (ctx->adp)
BCMLOG(BCMLOG_DBG, "Resetting Cmd context delete missing..\n");
ctx->adp = adp;
for (i = 0; i < BC_LINK_MAX_OPENS; i++) {
ctx->user[i].uid = i;
ctx->user[i].in_use = 0;
ctx->user[i].mode = DTS_MODE_INV;
}
/*Open and Close the Hardware to put it in to sleep state*/
crystalhd_hw_open(&ctx->hw_ctx, ctx->adp);
crystalhd_hw_close(&ctx->hw_ctx);
return BC_STS_SUCCESS;
}
/**
* crystalhd_delete_cmd_context - Release Command layer resources.
* @ctx: Command layer contextx.
*
* Return:
* status
*
* Called at the time of driver un-load.
*/
enum BC_STATUS crystalhd_delete_cmd_context(struct crystalhd_cmd *ctx)
{
BCMLOG(BCMLOG_DBG, "Deleting Command context..\n");
ctx->adp = NULL;
return BC_STS_SUCCESS;
}
/**
* crystalhd_get_cmd_proc - Cproc table lookup.
* @ctx: Command layer contextx.
* @cmd: IOCTL command code.
* @uc: User ID context.
*
* Return:
* command proc function pointer
*
* This function checks the process context, application's
* mode of operation and returns the function pointer
* from the cproc table.
*/
crystalhd_cmd_proc crystalhd_get_cmd_proc(struct crystalhd_cmd *ctx,
uint32_t cmd, struct crystalhd_user *uc)
{
crystalhd_cmd_proc cproc = NULL;
unsigned int i, tbl_sz;
if (!ctx) {
BCMLOG_ERR("Invalid arg.. Cmd[%d]\n", cmd);
return NULL;
}
if ((cmd != BCM_IOC_GET_DRV_STAT) && (ctx->state & BC_LINK_SUSPEND)) {
BCMLOG_ERR("Invalid State [suspend Set].. Cmd[%d]\n", cmd);
return NULL;
}
tbl_sz = sizeof(g_crystalhd_cproc_tbl) /
sizeof(struct crystalhd_cmd_tbl);
for (i = 0; i < tbl_sz; i++) {
if (g_crystalhd_cproc_tbl[i].cmd_id == cmd) {
if ((uc->mode == DTS_MONITOR_MODE) &&
(g_crystalhd_cproc_tbl[i].block_mon)) {
BCMLOG(BCMLOG_INFO, "Blocking cmd %d\n", cmd);
break;
}
cproc = g_crystalhd_cproc_tbl[i].cmd_proc;
break;
}
}
return cproc;
}
/**
* crystalhd_cmd_interrupt - ISR entry point
* @ctx: Command layer contextx.
*
* Return:
* TRUE: If interrupt from bcm70012 device.
*
*
* ISR entry point from OS layer.
*/
bool crystalhd_cmd_interrupt(struct crystalhd_cmd *ctx)
{
if (!ctx) {
BCMLOG_ERR("Invalid arg..\n");
return false;
}
return crystalhd_hw_interrupt(ctx->adp, &ctx->hw_ctx);
}
drivers/staging/crystalhd/crystalhd_cmds.h deleted 100644 → 0
View file @ 895ae876
/***************************************************************************
* Copyright (c) 2005-2009, Broadcom Corporation.
*
* Name: crystalhd_cmds . h
*
* Description:
* BCM70010 Linux driver user command interfaces.
*
* HISTORY:
*
**********************************************************************
* This file is part of the crystalhd device driver.
*
* This driver 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, version 2 of the License.
*
* This driver is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this driver. If not, see <http://www.gnu.org/licenses/>.
**********************************************************************/
#ifndef _CRYSTALHD_CMDS_H_
#define _CRYSTALHD_CMDS_H_
/*
* NOTE:: This is the main interface file between the Linux layer
* and the hardware layer. This file will use the definitions
* from _dts_glob and dts_defs etc.. which are defined for
* windows.
*/
#include "crystalhd.h"
enum crystalhd_state {
BC_LINK_INVALID = 0x00,
BC_LINK_INIT = 0x01,
BC_LINK_CAP_EN = 0x02,
BC_LINK_FMT_CHG = 0x04,
BC_LINK_SUSPEND = 0x10,
BC_LINK_PAUSED = 0x20,
BC_LINK_READY = (BC_LINK_INIT | BC_LINK_CAP_EN | BC_LINK_FMT_CHG),
};
struct crystalhd_user {
uint32_t uid;
uint32_t in_use;
uint32_t mode;
};
#define DTS_MODE_INV (-1)
struct crystalhd_cmd {
uint32_t state;
struct crystalhd_adp *adp;
struct crystalhd_user user[BC_LINK_MAX_OPENS];
spinlock_t ctx_lock;
uint32_t tx_list_id;
uint32_t cin_wait_exit;
uint32_t pwr_state_change;
struct crystalhd_hw hw_ctx;
};
typedef enum BC_STATUS(*crystalhd_cmd_proc)(struct crystalhd_cmd *,
struct crystalhd_ioctl_data *);
struct crystalhd_cmd_tbl {
uint32_t cmd_id;
const crystalhd_cmd_proc cmd_proc;
uint32_t block_mon;
};
enum BC_STATUS crystalhd_suspend(struct crystalhd_cmd *ctx,
struct crystalhd_ioctl_data *idata);
enum BC_STATUS crystalhd_resume(struct crystalhd_cmd *ctx);
crystalhd_cmd_proc crystalhd_get_cmd_proc(struct crystalhd_cmd *ctx,
uint32_t cmd, struct crystalhd_user *uc);
enum BC_STATUS crystalhd_user_open(struct crystalhd_cmd *ctx,
struct crystalhd_user **user_ctx);
enum BC_STATUS crystalhd_user_close(struct crystalhd_cmd *ctx,
struct crystalhd_user *uc);
enum BC_STATUS crystalhd_setup_cmd_context(struct crystalhd_cmd *ctx,
struct crystalhd_adp *adp);
enum BC_STATUS crystalhd_delete_cmd_context(struct crystalhd_cmd *ctx);
bool crystalhd_cmd_interrupt(struct crystalhd_cmd *ctx);
#endif
drivers/staging/crystalhd/crystalhd_fw_if.h deleted 100644 → 0
View file @ 895ae876
/***************************************************************************
* Copyright (c) 2005-2009, Broadcom Corporation.
*
* Name: crystalhd_fw_if . h
*
* Description:
* BCM70012 Firmware interface definitions.
*
* HISTORY:
*
**********************************************************************
* This file is part of the crystalhd device driver.
*
* This driver 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, version 2 of the License.
*
* This driver is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this driver. If not, see <http://www.gnu.org/licenses/>.
**********************************************************************/
#ifndef _CRYSTALHD_FW_IF_H_
#define _CRYSTALHD_FW_IF_H_
/* TBD: Pull in only required defs into this file.. */
/* User Data Header */
struct user_data {
struct user_data *next;
uint32_t type;
uint32_t size;
};
/*------------------------------------------------------*
* MPEG Extension to the PPB *
*------------------------------------------------------*/
struct ppb_mpeg {
uint32_t to_be_defined;
uint32_t valid;
/* Always valid, defaults to picture size if no
sequence display extension in the stream. */
uint32_t display_horizontal_size;
uint32_t display_vertical_size;
/* MPEG_VALID_PANSCAN
Offsets are a copy values from the MPEG stream. */
uint32_t offset_count;
int32_t horizontal_offset[3];
int32_t vertical_offset[3];
/* MPEG_VALID_USERDATA
User data is in the form of a linked list. */
int32_t userDataSize;
struct user_data *userData;
};
/*------------------------------------------------------*
* VC1 Extension to the PPB *
*------------------------------------------------------*/
struct ppb_vc1 {
uint32_t to_be_defined;
uint32_t valid;
/* Always valid, defaults to picture size if no
sequence display extension in the stream. */
uint32_t display_horizontal_size;
uint32_t display_vertical_size;
/* VC1 pan scan windows */
uint32_t num_panscan_windows;
int32_t ps_horiz_offset[4];
int32_t ps_vert_offset[4];
int32_t ps_width[4];
int32_t ps_height[4];
/* VC1_VALID_USERDATA
User data is in the form of a linked list. */
int32_t userDataSize;
struct user_data *userData;
};
/*------------------------------------------------------*
* H.264 Extension to the PPB *
*------------------------------------------------------*/
/**
* @brief Film grain SEI message.
*
* Content of the film grain SEI message.
*/
/* maximum number of model-values as for Thomson spec(standard says 5) */
#define MAX_FGT_MODEL_VALUE (3)
/* maximum number of intervals(as many as 256 intervals?) */
#define MAX_FGT_VALUE_INTERVAL (256)
struct fgt_sei {
struct fgt_sei *next;
unsigned char
model_values[3][MAX_FGT_VALUE_INTERVAL][MAX_FGT_MODEL_VALUE];
unsigned char upper_bound[3][MAX_FGT_VALUE_INTERVAL];
unsigned char lower_bound[3][MAX_FGT_VALUE_INTERVAL];
unsigned char cancel_flag; /* Cancel flag: 1 no film grain. */
unsigned char model_id; /* Model id. */
/* +unused SE based on Thomson spec */
unsigned char color_desc_flag; /* Separate color description flag. */
unsigned char bit_depth_luma; /* Bit depth luma minus 8. */
unsigned char bit_depth_chroma; /* Bit depth chroma minus 8. */
unsigned char full_range_flag; /* Full range flag. */
unsigned char color_primaries; /* Color primaries. */
unsigned char transfer_charact; /* Transfer characteristics. */
unsigned char matrix_coeff; /*< Matrix coefficients. */
/* -unused SE based on Thomson spec */
unsigned char blending_mode_id; /* Blending mode. */
unsigned char log2_scale_factor; /* Log2 scale factor (2-7). */
unsigned char comp_flag[3]; /* Components [0,2]
parameters present flag. */
unsigned char num_intervals_minus1[3]; /* Number of
intensity level intervals. */
unsigned char num_model_values[3]; /* Number of model values. */
uint16_t repetition_period; /* Repetition period (0-16384) */
};
struct ppb_h264 {
/* 'valid' specifies which fields (or sets of
* fields) below are valid. If the corresponding
* bit in 'valid' is NOT set then that field(s)
* is (are) not initialized. */
uint32_t valid;
int32_t poc_top; /* POC for Top Field/Frame */
int32_t poc_bottom; /* POC for Bottom Field */
uint32_t idr_pic_id;
/* H264_VALID_PANSCAN */
uint32_t pan_scan_count;
int32_t pan_scan_left[3];
int32_t pan_scan_right[3];
int32_t pan_scan_top[3];
int32_t pan_scan_bottom[3];
/* H264_VALID_CT_TYPE */
uint32_t ct_type_count;
uint32_t ct_type[3];
/* H264_VALID_SPS_CROP */
int32_t sps_crop_left;
int32_t sps_crop_right;
int32_t sps_crop_top;
int32_t sps_crop_bottom;
/* H264_VALID_VUI */
uint32_t chroma_top;
uint32_t chroma_bottom;
/* H264_VALID_USER */
uint32_t user_data_size;
struct user_data *user_data;
/* H264 VALID FGT */
struct fgt_sei *pfgt;
};
struct ppb {
/* Common fields. */
uint32_t picture_number; /* Ordinal display number */
uint32_t video_buffer; /* Video (picbuf) number */
uint32_t video_address; /* Address of picbuf Y */
uint32_t video_address_uv; /* Address of picbuf UV */
uint32_t video_stripe; /* Picbuf stripe */
uint32_t video_width; /* Picbuf width */
uint32_t video_height; /* Picbuf height */
uint32_t channel_id; /* Decoder channel ID */
uint32_t status; /* reserved */
uint32_t width; /* pixels */
uint32_t height; /* pixels */
uint32_t chroma_format; /* see above */
uint32_t pulldown; /* see above */
uint32_t flags; /* see above */
uint32_t pts; /* 32 LSBs of PTS */
uint32_t protocol; /* protocolXXX (above) */
uint32_t frame_rate; /* see above */
uint32_t matrix_coeff; /* see above */
uint32_t aspect_ratio; /* see above */
uint32_t colour_primaries; /* see above */
uint32_t transfer_char; /* see above */
uint32_t pcr_offset; /* 45kHz if PCR type; else 27MHz */
uint32_t n_drop; /* Number of pictures to be dropped */
uint32_t custom_aspect_ratio_width_height;
/* upper 16-bits is Y and lower 16-bits is X */
uint32_t picture_tag; /* Indexing tag from BUD packets */
uint32_t picture_done_payload;
uint32_t picture_meta_payload;
uint32_t reserved[1];
/* Protocol-specific extensions. */
union {
struct ppb_h264 h264;
struct ppb_mpeg mpeg;
struct ppb_vc1 vc1;
} other;
};
struct c011_pib {
uint32_t bFormatChange;
uint32_t resolution;
uint32_t channelId;
uint32_t ppbPtr;
int32_t ptsStcOffset;
uint32_t zeroPanscanValid;
uint32_t dramOutBufAddr;
uint32_t yComponent;
struct ppb ppb;
};
struct dec_rsp_channel_start_video {
uint32_t command;
uint32_t sequence;
uint32_t status;
uint32_t picBuf;
uint32_t picRelBuf;
uint32_t picInfoDeliveryQ;
uint32_t picInfoReleaseQ;
uint32_t channelStatus;
uint32_t userDataDeliveryQ;
uint32_t userDataReleaseQ;
uint32_t transportStreamCaptureAddr;
uint32_t asyncEventQ;
};
#define eCMD_C011_CMD_BASE (0x73763000)
/* host commands */
enum c011_ts_cmd {
eCMD_TS_GET_NEXT_PIC = 0x7376F100, /* debug get next picture */
eCMD_TS_GET_LAST_PIC = 0x7376F102, /* debug get last pic status */
eCMD_TS_READ_WRITE_MEM = 0x7376F104, /* debug read write memory */
/* New API commands */
/* General commands */
eCMD_C011_INIT = eCMD_C011_CMD_BASE + 0x01,
eCMD_C011_RESET = eCMD_C011_CMD_BASE + 0x02,
eCMD_C011_SELF_TEST = eCMD_C011_CMD_BASE + 0x03,
eCMD_C011_GET_VERSION = eCMD_C011_CMD_BASE + 0x04,
eCMD_C011_GPIO = eCMD_C011_CMD_BASE + 0x05,
eCMD_C011_DEBUG_SETUP = eCMD_C011_CMD_BASE + 0x06,
/* Decoding commands */
eCMD_C011_DEC_CHAN_OPEN = eCMD_C011_CMD_BASE + 0x100,
eCMD_C011_DEC_CHAN_CLOSE = eCMD_C011_CMD_BASE + 0x101,
eCMD_C011_DEC_CHAN_ACTIVATE = eCMD_C011_CMD_BASE + 0x102,
eCMD_C011_DEC_CHAN_STATUS = eCMD_C011_CMD_BASE + 0x103,
eCMD_C011_DEC_CHAN_FLUSH = eCMD_C011_CMD_BASE + 0x104,
eCMD_C011_DEC_CHAN_TRICK_PLAY = eCMD_C011_CMD_BASE + 0x105,
eCMD_C011_DEC_CHAN_TS_PIDS = eCMD_C011_CMD_BASE + 0x106,
eCMD_C011_DEC_CHAN_PS_STREAM_ID = eCMD_C011_CMD_BASE + 0x107,
eCMD_C011_DEC_CHAN_INPUT_PARAMS = eCMD_C011_CMD_BASE + 0x108,
eCMD_C011_DEC_CHAN_VIDEO_OUTPUT = eCMD_C011_CMD_BASE + 0x109,
eCMD_C011_DEC_CHAN_OUTPUT_FORMAT = eCMD_C011_CMD_BASE + 0x10A,
eCMD_C011_DEC_CHAN_SCALING_FILTERS = eCMD_C011_CMD_BASE + 0x10B,
eCMD_C011_DEC_CHAN_OSD_MODE = eCMD_C011_CMD_BASE + 0x10D,
eCMD_C011_DEC_CHAN_DROP = eCMD_C011_CMD_BASE + 0x10E,
eCMD_C011_DEC_CHAN_RELEASE = eCMD_C011_CMD_BASE + 0x10F,
eCMD_C011_DEC_CHAN_STREAM_SETTINGS = eCMD_C011_CMD_BASE + 0x110,
eCMD_C011_DEC_CHAN_PAUSE_OUTPUT = eCMD_C011_CMD_BASE + 0x111,
eCMD_C011_DEC_CHAN_CHANGE = eCMD_C011_CMD_BASE + 0x112,
eCMD_C011_DEC_CHAN_SET_STC = eCMD_C011_CMD_BASE + 0x113,
eCMD_C011_DEC_CHAN_SET_PTS = eCMD_C011_CMD_BASE + 0x114,
eCMD_C011_DEC_CHAN_CC_MODE = eCMD_C011_CMD_BASE + 0x115,
eCMD_C011_DEC_CREATE_AUDIO_CONTEXT = eCMD_C011_CMD_BASE + 0x116,
eCMD_C011_DEC_COPY_AUDIO_CONTEXT = eCMD_C011_CMD_BASE + 0x117,
eCMD_C011_DEC_DELETE_AUDIO_CONTEXT = eCMD_C011_CMD_BASE + 0x118,
eCMD_C011_DEC_CHAN_SET_DECYPTION = eCMD_C011_CMD_BASE + 0x119,
eCMD_C011_DEC_CHAN_START_VIDEO = eCMD_C011_CMD_BASE + 0x11A,
eCMD_C011_DEC_CHAN_STOP_VIDEO = eCMD_C011_CMD_BASE + 0x11B,
eCMD_C011_DEC_CHAN_PIC_CAPTURE = eCMD_C011_CMD_BASE + 0x11C,
eCMD_C011_DEC_CHAN_PAUSE = eCMD_C011_CMD_BASE + 0x11D,
eCMD_C011_DEC_CHAN_PAUSE_STATE = eCMD_C011_CMD_BASE + 0x11E,
eCMD_C011_DEC_CHAN_SET_SLOWM_RATE = eCMD_C011_CMD_BASE + 0x11F,
eCMD_C011_DEC_CHAN_GET_SLOWM_RATE = eCMD_C011_CMD_BASE + 0x120,
eCMD_C011_DEC_CHAN_SET_FF_RATE = eCMD_C011_CMD_BASE + 0x121,
eCMD_C011_DEC_CHAN_GET_FF_RATE = eCMD_C011_CMD_BASE + 0x122,
eCMD_C011_DEC_CHAN_FRAME_ADVANCE = eCMD_C011_CMD_BASE + 0x123,
eCMD_C011_DEC_CHAN_SET_SKIP_PIC_MODE = eCMD_C011_CMD_BASE + 0x124,
eCMD_C011_DEC_CHAN_GET_SKIP_PIC_MODE = eCMD_C011_CMD_BASE + 0x125,
eCMD_C011_DEC_CHAN_FILL_PIC_BUF = eCMD_C011_CMD_BASE + 0x126,
eCMD_C011_DEC_CHAN_SET_CONTINUITY_CHECK = eCMD_C011_CMD_BASE + 0x127,
eCMD_C011_DEC_CHAN_GET_CONTINUITY_CHECK = eCMD_C011_CMD_BASE + 0x128,
eCMD_C011_DEC_CHAN_SET_BRCM_TRICK_MODE = eCMD_C011_CMD_BASE + 0x129,
eCMD_C011_DEC_CHAN_GET_BRCM_TRICK_MODE = eCMD_C011_CMD_BASE + 0x12A,
eCMD_C011_DEC_CHAN_REVERSE_FIELD_STATUS = eCMD_C011_CMD_BASE + 0x12B,
eCMD_C011_DEC_CHAN_I_PICTURE_FOUND = eCMD_C011_CMD_BASE + 0x12C,
eCMD_C011_DEC_CHAN_SET_PARAMETER = eCMD_C011_CMD_BASE + 0x12D,
eCMD_C011_DEC_CHAN_SET_USER_DATA_MODE = eCMD_C011_CMD_BASE + 0x12E,
eCMD_C011_DEC_CHAN_SET_PAUSE_DISPLAY_MODE = eCMD_C011_CMD_BASE + 0x12F,
eCMD_C011_DEC_CHAN_SET_SLOW_DISPLAY_MODE = eCMD_C011_CMD_BASE + 0x130,
eCMD_C011_DEC_CHAN_SET_FF_DISPLAY_MODE = eCMD_C011_CMD_BASE + 0x131,
eCMD_C011_DEC_CHAN_SET_DISPLAY_TIMING_MODE = eCMD_C011_CMD_BASE +
0x132,
eCMD_C011_DEC_CHAN_SET_DISPLAY_MODE = eCMD_C011_CMD_BASE + 0x133,
eCMD_C011_DEC_CHAN_GET_DISPLAY_MODE = eCMD_C011_CMD_BASE + 0x134,
eCMD_C011_DEC_CHAN_SET_REVERSE_FIELD = eCMD_C011_CMD_BASE + 0x135,
eCMD_C011_DEC_CHAN_STREAM_OPEN = eCMD_C011_CMD_BASE + 0x136,
eCMD_C011_DEC_CHAN_SET_PCR_PID = eCMD_C011_CMD_BASE + 0x137,
eCMD_C011_DEC_CHAN_SET_VID_PID = eCMD_C011_CMD_BASE + 0x138,
eCMD_C011_DEC_CHAN_SET_PAN_SCAN_MODE = eCMD_C011_CMD_BASE + 0x139,
eCMD_C011_DEC_CHAN_START_DISPLAY_AT_PTS = eCMD_C011_CMD_BASE + 0x140,
eCMD_C011_DEC_CHAN_STOP_DISPLAY_AT_PTS = eCMD_C011_CMD_BASE + 0x141,
eCMD_C011_DEC_CHAN_SET_DISPLAY_ORDER = eCMD_C011_CMD_BASE + 0x142,
eCMD_C011_DEC_CHAN_GET_DISPLAY_ORDER = eCMD_C011_CMD_BASE + 0x143,
eCMD_C011_DEC_CHAN_SET_HOST_TRICK_MODE = eCMD_C011_CMD_BASE + 0x144,
eCMD_C011_DEC_CHAN_SET_OPERATION_MODE = eCMD_C011_CMD_BASE + 0x145,
eCMD_C011_DEC_CHAN_DISPLAY_PAUSE_UNTO_PTS = eCMD_C011_CMD_BASE + 0x146,
eCMD_C011_DEC_CHAN_SET_PTS_STC_DIFF_THRESHOLD = eCMD_C011_CMD_BASE +
0x147,
eCMD_C011_DEC_CHAN_SEND_COMPRESSED_BUF = eCMD_C011_CMD_BASE + 0x148,
eCMD_C011_DEC_CHAN_SET_CLIPPING = eCMD_C011_CMD_BASE + 0x149,
eCMD_C011_DEC_CHAN_SET_PARAMETERS_FOR_HARD_RESET_INTERRUPT_TO_HOST
= eCMD_C011_CMD_BASE + 0x150,
/* Decoder RevD commands */
eCMD_C011_DEC_CHAN_SET_CSC = eCMD_C011_CMD_BASE + 0x180, /* color
space conversion */
eCMD_C011_DEC_CHAN_SET_RANGE_REMAP = eCMD_C011_CMD_BASE + 0x181,
eCMD_C011_DEC_CHAN_SET_FGT = eCMD_C011_CMD_BASE + 0x182,
/* Note: 0x183 not implemented yet in Rev D main */
eCMD_C011_DEC_CHAN_SET_LASTPICTURE_PADDING = eCMD_C011_CMD_BASE +
0x183,
/* Decoder 7412 commands (7412-only) */
eCMD_C011_DEC_CHAN_SET_CONTENT_KEY = eCMD_C011_CMD_BASE + 0x190,
eCMD_C011_DEC_CHAN_SET_SESSION_KEY = eCMD_C011_CMD_BASE + 0x191,
eCMD_C011_DEC_CHAN_FMT_CHANGE_ACK = eCMD_C011_CMD_BASE + 0x192,
eCMD_C011_DEC_CHAN_CUSTOM_VIDOUT = eCMD_C011_CMD_BASE + 0x1FF,
/* Encoding commands */
eCMD_C011_ENC_CHAN_OPEN = eCMD_C011_CMD_BASE + 0x200,
eCMD_C011_ENC_CHAN_CLOSE = eCMD_C011_CMD_BASE + 0x201,
eCMD_C011_ENC_CHAN_ACTIVATE = eCMD_C011_CMD_BASE + 0x202,
eCMD_C011_ENC_CHAN_CONTROL = eCMD_C011_CMD_BASE + 0x203,
eCMD_C011_ENC_CHAN_STATISTICS = eCMD_C011_CMD_BASE + 0x204,
eNOTIFY_C011_ENC_CHAN_EVENT = eCMD_C011_CMD_BASE + 0x210,
};
#endif
drivers/staging/crystalhd/crystalhd_hw.c deleted 100644 → 0
View file @ 895ae876
/***************************************************************************
* Copyright (c) 2005-2009, Broadcom Corporation.
*
* Name: crystalhd_hw . c
*
* Description:
* BCM70010 Linux driver HW layer.
*
**********************************************************************
* This file is part of the crystalhd device driver.
*
* This driver 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, version 2 of the License.
*
* This driver is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this driver. If not, see <http://www.gnu.org/licenses/>.
**********************************************************************/
#include "crystalhd.h"
#include <linux/pci.h>
#include <linux/slab.h>
#include <linux/delay.h>
/* Functions internal to this file */
static void crystalhd_enable_uarts(struct crystalhd_adp *adp)
{
bc_dec_reg_wr(adp, UartSelectA, BSVS_UART_STREAM);
bc_dec_reg_wr(adp, UartSelectB, BSVS_UART_DEC_OUTER);
}
static void crystalhd_start_dram(struct crystalhd_adp *adp)
{
bc_dec_reg_wr(adp, SDRAM_PARAM, ((40 / 5 - 1) << 0) |
/* tras (40ns tras)/(5ns period) -1 ((15/5 - 1) << 4) | // trcd */
((15 / 5 - 1) << 7) | /* trp */
((10 / 5 - 1) << 10) | /* trrd */
((15 / 5 + 1) << 12) | /* twr */
((2 + 1) << 16) | /* twtr */
((70 / 5 - 2) << 19) | /* trfc */
(0 << 23));
bc_dec_reg_wr(adp, SDRAM_PRECHARGE, 0);
bc_dec_reg_wr(adp, SDRAM_EXT_MODE, 2);
bc_dec_reg_wr(adp, SDRAM_MODE, 0x132);
bc_dec_reg_wr(adp, SDRAM_PRECHARGE, 0);
bc_dec_reg_wr(adp, SDRAM_REFRESH, 0);
bc_dec_reg_wr(adp, SDRAM_REFRESH, 0);
bc_dec_reg_wr(adp, SDRAM_MODE, 0x32);
/* setting the refresh rate here */
bc_dec_reg_wr(adp, SDRAM_REF_PARAM, ((1 << 12) | 96));
}
static bool crystalhd_bring_out_of_rst(struct crystalhd_adp *adp)
{
union link_misc_perst_deco_ctrl rst_deco_cntrl;
union link_misc_perst_clk_ctrl rst_clk_cntrl;
uint32_t temp;
/*
* Link clocks: MISC_PERST_CLOCK_CTRL Clear PLL power down bit,
* delay to allow PLL to lock Clear alternate clock, stop clock bits
*/
rst_clk_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC_PERST_CLOCK_CTRL);
rst_clk_cntrl.pll_pwr_dn = 0;
crystalhd_reg_wr(adp, MISC_PERST_CLOCK_CTRL, rst_clk_cntrl.whole_reg);
msleep_interruptible(50);
rst_clk_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC_PERST_CLOCK_CTRL);
rst_clk_cntrl.stop_core_clk = 0;
rst_clk_cntrl.sel_alt_clk = 0;
crystalhd_reg_wr(adp, MISC_PERST_CLOCK_CTRL, rst_clk_cntrl.whole_reg);
msleep_interruptible(50);
/*
* Bus Arbiter Timeout: GISB_ARBITER_TIMER
* Set internal bus arbiter timeout to 40us based on core clock speed
* (63MHz * 40us = 0x9D8)
*/
crystalhd_reg_wr(adp, GISB_ARBITER_TIMER, 0x9D8);
/*
* Decoder clocks: MISC_PERST_DECODER_CTRL
* Enable clocks while 7412 reset is asserted, delay
* De-assert 7412 reset
*/
rst_deco_cntrl.whole_reg = crystalhd_reg_rd(adp,
MISC_PERST_DECODER_CTRL);
rst_deco_cntrl.stop_bcm_7412_clk = 0;
rst_deco_cntrl.bcm7412_rst = 1;
crystalhd_reg_wr(adp, MISC_PERST_DECODER_CTRL,
rst_deco_cntrl.whole_reg);
msleep_interruptible(10);
rst_deco_cntrl.whole_reg = crystalhd_reg_rd(adp,
MISC_PERST_DECODER_CTRL);
rst_deco_cntrl.bcm7412_rst = 0;
crystalhd_reg_wr(adp, MISC_PERST_DECODER_CTRL,
rst_deco_cntrl.whole_reg);
msleep_interruptible(50);
/* Disable OTP_CONTENT_MISC to 0 to disable all secure modes */
crystalhd_reg_wr(adp, OTP_CONTENT_MISC, 0);
/* Clear bit 29 of 0x404 */
temp = crystalhd_reg_rd(adp, PCIE_TL_TRANSACTION_CONFIGURATION);
temp &= ~BC_BIT(29);
crystalhd_reg_wr(adp, PCIE_TL_TRANSACTION_CONFIGURATION, temp);
/* 2.5V regulator must be set to 2.6 volts (+6%) */
/* FIXME: jarod: what's the point of this reg read? */
temp = crystalhd_reg_rd(adp, MISC_PERST_VREG_CTRL);
crystalhd_reg_wr(adp, MISC_PERST_VREG_CTRL, 0xF3);
return true;
}
static bool crystalhd_put_in_reset(struct crystalhd_adp *adp)
{
union link_misc_perst_deco_ctrl rst_deco_cntrl;
union link_misc_perst_clk_ctrl rst_clk_cntrl;
uint32_t temp;
/*
* Decoder clocks: MISC_PERST_DECODER_CTRL
* Assert 7412 reset, delay
* Assert 7412 stop clock
*/
rst_deco_cntrl.whole_reg = crystalhd_reg_rd(adp,
MISC_PERST_DECODER_CTRL);
rst_deco_cntrl.stop_bcm_7412_clk = 1;
crystalhd_reg_wr(adp, MISC_PERST_DECODER_CTRL,
rst_deco_cntrl.whole_reg);
msleep_interruptible(50);
/* Bus Arbiter Timeout: GISB_ARBITER_TIMER
* Set internal bus arbiter timeout to 40us based on core clock speed
* (6.75MHZ * 40us = 0x10E)
*/
crystalhd_reg_wr(adp, GISB_ARBITER_TIMER, 0x10E);
/* Link clocks: MISC_PERST_CLOCK_CTRL
* Stop core clk, delay
* Set alternate clk, delay, set PLL power down
*/
rst_clk_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC_PERST_CLOCK_CTRL);
rst_clk_cntrl.stop_core_clk = 1;
rst_clk_cntrl.sel_alt_clk = 1;
crystalhd_reg_wr(adp, MISC_PERST_CLOCK_CTRL, rst_clk_cntrl.whole_reg);
msleep_interruptible(50);
rst_clk_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC_PERST_CLOCK_CTRL);
rst_clk_cntrl.pll_pwr_dn = 1;
crystalhd_reg_wr(adp, MISC_PERST_CLOCK_CTRL, rst_clk_cntrl.whole_reg);
/*
* Read and restore the Transaction Configuration Register
* after core reset
*/
temp = crystalhd_reg_rd(adp, PCIE_TL_TRANSACTION_CONFIGURATION);
/*
* Link core soft reset: MISC3_RESET_CTRL
* - Write BIT[0]=1 and read it back for core reset to take place
*/
crystalhd_reg_wr(adp, MISC3_RESET_CTRL, 1);
rst_deco_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC3_RESET_CTRL);
msleep_interruptible(50);
/* restore the transaction configuration register */
crystalhd_reg_wr(adp, PCIE_TL_TRANSACTION_CONFIGURATION, temp);
return true;
}
static void crystalhd_disable_interrupts(struct crystalhd_adp *adp)
{
union intr_mask_reg intr_mask;
intr_mask.whole_reg = crystalhd_reg_rd(adp, INTR_INTR_MSK_STS_REG);
intr_mask.mask_pcie_err = 1;
intr_mask.mask_pcie_rbusmast_err = 1;
intr_mask.mask_pcie_rgr_bridge = 1;
intr_mask.mask_rx_done = 1;
intr_mask.mask_rx_err = 1;
intr_mask.mask_tx_done = 1;
intr_mask.mask_tx_err = 1;
crystalhd_reg_wr(adp, INTR_INTR_MSK_SET_REG, intr_mask.whole_reg);
return;
}
static void crystalhd_enable_interrupts(struct crystalhd_adp *adp)
{
union intr_mask_reg intr_mask;
intr_mask.whole_reg = crystalhd_reg_rd(adp, INTR_INTR_MSK_STS_REG);
intr_mask.mask_pcie_err = 1;
intr_mask.mask_pcie_rbusmast_err = 1;
intr_mask.mask_pcie_rgr_bridge = 1;
intr_mask.mask_rx_done = 1;
intr_mask.mask_rx_err = 1;
intr_mask.mask_tx_done = 1;
intr_mask.mask_tx_err = 1;
crystalhd_reg_wr(adp, INTR_INTR_MSK_CLR_REG, intr_mask.whole_reg);
return;
}
static void crystalhd_clear_errors(struct crystalhd_adp *adp)
{
uint32_t reg;
/* FIXME: jarod: wouldn't we want to write a 0 to the reg?
Or does the write clear the bits specified? */
reg = crystalhd_reg_rd(adp, MISC1_Y_RX_ERROR_STATUS);
if (reg)
crystalhd_reg_wr(adp, MISC1_Y_RX_ERROR_STATUS, reg);
reg = crystalhd_reg_rd(adp, MISC1_UV_RX_ERROR_STATUS);
if (reg)
crystalhd_reg_wr(adp, MISC1_UV_RX_ERROR_STATUS, reg);
reg = crystalhd_reg_rd(adp, MISC1_TX_DMA_ERROR_STATUS);
if (reg)
crystalhd_reg_wr(adp, MISC1_TX_DMA_ERROR_STATUS, reg);
}
static void crystalhd_clear_interrupts(struct crystalhd_adp *adp)
{
uint32_t intr_sts = crystalhd_reg_rd(adp, INTR_INTR_STATUS);
if (intr_sts) {
crystalhd_reg_wr(adp, INTR_INTR_CLR_REG, intr_sts);
/* Write End Of Interrupt for PCIE */
crystalhd_reg_wr(adp, INTR_EOI_CTRL, 1);
}
}
static void crystalhd_soft_rst(struct crystalhd_adp *adp)
{
uint32_t val;
/* Assert c011 soft reset*/
bc_dec_reg_wr(adp, DecHt_HostSwReset, 0x00000001);
msleep_interruptible(50);
/* Release c011 soft reset*/
bc_dec_reg_wr(adp, DecHt_HostSwReset, 0x00000000);
/* Disable Stuffing..*/
val = crystalhd_reg_rd(adp, MISC2_GLOBAL_CTRL);
val |= BC_BIT(8);
crystalhd_reg_wr(adp, MISC2_GLOBAL_CTRL, val);
}
static bool crystalhd_load_firmware_config(struct crystalhd_adp *adp)
{
uint32_t i = 0, reg;
crystalhd_reg_wr(adp, DCI_DRAM_BASE_ADDR, (BC_DRAM_FW_CFG_ADDR >> 19));
crystalhd_reg_wr(adp, AES_CMD, 0);
crystalhd_reg_wr(adp, AES_CONFIG_INFO,
(BC_DRAM_FW_CFG_ADDR & 0x7FFFF));
crystalhd_reg_wr(adp, AES_CMD, 0x1);
/* FIXME: jarod: I've seen this fail,
and introducing extra delays helps... */
for (i = 0; i < 100; ++i) {
reg = crystalhd_reg_rd(adp, AES_STATUS);
if (reg & 0x1)
return true;
msleep_interruptible(10);
}
return false;
}
static bool crystalhd_start_device(struct crystalhd_adp *adp)
{
uint32_t dbg_options, glb_cntrl = 0, reg_pwrmgmt = 0;
BCMLOG(BCMLOG_INFO, "Starting BCM70012 Device\n");
reg_pwrmgmt = crystalhd_reg_rd(adp, PCIE_DLL_DATA_LINK_CONTROL);
reg_pwrmgmt &= ~ASPM_L1_ENABLE;
crystalhd_reg_wr(adp, PCIE_DLL_DATA_LINK_CONTROL, reg_pwrmgmt);
if (!crystalhd_bring_out_of_rst(adp)) {
BCMLOG_ERR("Failed To Bring Link Out Of Reset\n");
return false;
}
crystalhd_disable_interrupts(adp);
crystalhd_clear_errors(adp);
crystalhd_clear_interrupts(adp);
crystalhd_enable_interrupts(adp);
/* Enable the option for getting the total no. of DWORDS
* that have been transferred by the RXDMA engine
*/
dbg_options = crystalhd_reg_rd(adp, MISC1_DMA_DEBUG_OPTIONS_REG);
dbg_options |= 0x10;
crystalhd_reg_wr(adp, MISC1_DMA_DEBUG_OPTIONS_REG, dbg_options);
/* Enable PCI Global Control options */
glb_cntrl = crystalhd_reg_rd(adp, MISC2_GLOBAL_CTRL);
glb_cntrl |= 0x100;
glb_cntrl |= 0x8000;
crystalhd_reg_wr(adp, MISC2_GLOBAL_CTRL, glb_cntrl);
crystalhd_enable_interrupts(adp);
crystalhd_soft_rst(adp);
crystalhd_start_dram(adp);
crystalhd_enable_uarts(adp);
return true;
}
static bool crystalhd_stop_device(struct crystalhd_adp *adp)
{
uint32_t reg;
BCMLOG(BCMLOG_INFO, "Stopping BCM70012 Device\n");
/* Clear and disable interrupts */
crystalhd_disable_interrupts(adp);
crystalhd_clear_errors(adp);
crystalhd_clear_interrupts(adp);
if (!crystalhd_put_in_reset(adp))
BCMLOG_ERR("Failed to Put Link To Reset State\n");
reg = crystalhd_reg_rd(adp, PCIE_DLL_DATA_LINK_CONTROL);
reg |= ASPM_L1_ENABLE;
crystalhd_reg_wr(adp, PCIE_DLL_DATA_LINK_CONTROL, reg);
/* Set PCI Clk Req */
reg = crystalhd_reg_rd(adp, PCIE_CLK_REQ_REG);
reg |= PCI_CLK_REQ_ENABLE;
crystalhd_reg_wr(adp, PCIE_CLK_REQ_REG, reg);
return true;
}
static struct crystalhd_rx_dma_pkt *crystalhd_hw_alloc_rx_pkt(
struct crystalhd_hw *hw)
{
unsigned long flags = 0;
struct crystalhd_rx_dma_pkt *temp = NULL;
if (!hw)
return NULL;
spin_lock_irqsave(&hw->lock, flags);
temp = hw->rx_pkt_pool_head;
if (temp) {
hw->rx_pkt_pool_head = hw->rx_pkt_pool_head->next;
temp->dio_req = NULL;
temp->pkt_tag = 0;
temp->flags = 0;
}
spin_unlock_irqrestore(&hw->lock, flags);
return temp;
}
static void crystalhd_hw_free_rx_pkt(struct crystalhd_hw *hw,
struct crystalhd_rx_dma_pkt *pkt)
{
unsigned long flags = 0;
if (!hw || !pkt)
return;
spin_lock_irqsave(&hw->lock, flags);
pkt->next = hw->rx_pkt_pool_head;
hw->rx_pkt_pool_head = pkt;
spin_unlock_irqrestore(&hw->lock, flags);
}
/*
* Call back from TX - IOQ deletion.
*
* This routine will release the TX DMA rings allocated
* during setup_dma rings interface.
*
* Memory is allocated per DMA ring basis. This is just
* a place holder to be able to create the dio queues.
*/
static void crystalhd_tx_desc_rel_call_back(void *context, void *data)
{
}
/*
* Rx Packet release callback..
*
* Release All user mapped capture buffers and Our DMA packets
* back to our free pool. The actual cleanup of the DMA
* ring descriptors happen during dma ring release.
*/
static void crystalhd_rx_pkt_rel_call_back(void *context, void *data)
{
struct crystalhd_hw *hw = (struct crystalhd_hw *)context;
struct crystalhd_rx_dma_pkt *pkt = (struct crystalhd_rx_dma_pkt *)data;
if (!pkt || !hw) {
BCMLOG_ERR("Invalid arg - %p %p\n", hw, pkt);
return;
}
if (pkt->dio_req)
crystalhd_unmap_dio(hw->adp, pkt->dio_req);
else
BCMLOG_ERR("Missing dio_req: 0x%x\n", pkt->pkt_tag);
crystalhd_hw_free_rx_pkt(hw, pkt);
}
#define crystalhd_hw_delete_ioq(adp, q) \
do { \
if (q) { \
crystalhd_delete_dioq(adp, q); \
q = NULL; \
} \
} while (0)
static void crystalhd_hw_delete_ioqs(struct crystalhd_hw *hw)
{
if (!hw)
return;
BCMLOG(BCMLOG_DBG, "Deleting IOQs\n");
crystalhd_hw_delete_ioq(hw->adp, hw->tx_actq);
crystalhd_hw_delete_ioq(hw->adp, hw->tx_freeq);
crystalhd_hw_delete_ioq(hw->adp, hw->rx_actq);
crystalhd_hw_delete_ioq(hw->adp, hw->rx_freeq);
crystalhd_hw_delete_ioq(hw->adp, hw->rx_rdyq);
}
#define crystalhd_hw_create_ioq(sts, hw, q, cb) \
do { \
sts = crystalhd_create_dioq(hw->adp, &q, cb, hw); \
if (sts != BC_STS_SUCCESS) \
goto hw_create_ioq_err; \
} while (0)
/*
* Create IOQs..
*
* TX - Active & Free
* RX - Active, Ready and Free.
*/
static enum BC_STATUS crystalhd_hw_create_ioqs(struct crystalhd_hw *hw)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!hw) {
BCMLOG_ERR("Invalid Arg!!\n");
return BC_STS_INV_ARG;
}
crystalhd_hw_create_ioq(sts, hw, hw->tx_freeq,
crystalhd_tx_desc_rel_call_back);
crystalhd_hw_create_ioq(sts, hw, hw->tx_actq,
crystalhd_tx_desc_rel_call_back);
crystalhd_hw_create_ioq(sts, hw, hw->rx_freeq,
crystalhd_rx_pkt_rel_call_back);
crystalhd_hw_create_ioq(sts, hw, hw->rx_rdyq,
crystalhd_rx_pkt_rel_call_back);
crystalhd_hw_create_ioq(sts, hw, hw->rx_actq,
crystalhd_rx_pkt_rel_call_back);
return sts;
hw_create_ioq_err:
crystalhd_hw_delete_ioqs(hw);
return sts;
}
static bool crystalhd_code_in_full(struct crystalhd_adp *adp,
uint32_t needed_sz, bool b_188_byte_pkts, uint8_t flags)
{
uint32_t base, end, writep, readp;
uint32_t cpbSize, cpbFullness, fifoSize;
if (flags & 0x02) { /* ASF Bit is set */
base = bc_dec_reg_rd(adp, REG_Dec_TsAudCDB2Base);
end = bc_dec_reg_rd(adp, REG_Dec_TsAudCDB2End);
writep = bc_dec_reg_rd(adp, REG_Dec_TsAudCDB2Wrptr);
readp = bc_dec_reg_rd(adp, REG_Dec_TsAudCDB2Rdptr);
} else if (b_188_byte_pkts) { /*Encrypted 188 byte packets*/
base = bc_dec_reg_rd(adp, REG_Dec_TsUser0Base);
end = bc_dec_reg_rd(adp, REG_Dec_TsUser0End);
writep = bc_dec_reg_rd(adp, REG_Dec_TsUser0Wrptr);
readp = bc_dec_reg_rd(adp, REG_Dec_TsUser0Rdptr);
} else {
base = bc_dec_reg_rd(adp, REG_DecCA_RegCinBase);
end = bc_dec_reg_rd(adp, REG_DecCA_RegCinEnd);
writep = bc_dec_reg_rd(adp, REG_DecCA_RegCinWrPtr);
readp = bc_dec_reg_rd(adp, REG_DecCA_RegCinRdPtr);
}
cpbSize = end - base;
if (writep >= readp)
cpbFullness = writep - readp;
else
cpbFullness = (end - base) - (readp - writep);
fifoSize = cpbSize - cpbFullness;
if (fifoSize < BC_INFIFO_THRESHOLD)
return true;
if (needed_sz > (fifoSize - BC_INFIFO_THRESHOLD))
return true;
return false;
}
static enum BC_STATUS crystalhd_hw_tx_req_complete(struct crystalhd_hw *hw,
uint32_t list_id, enum BC_STATUS cs)
{
struct tx_dma_pkt *tx_req;
if (!hw || !list_id) {
BCMLOG_ERR("Invalid Arg..\n");
return BC_STS_INV_ARG;
}
hw->pwr_lock--;
tx_req = (struct tx_dma_pkt *)crystalhd_dioq_find_and_fetch(
hw->tx_actq, list_id);
if (!tx_req) {
if (cs != BC_STS_IO_USER_ABORT)
BCMLOG_ERR("Find and Fetch Did not find req\n");
return BC_STS_NO_DATA;
}
if (tx_req->call_back) {
tx_req->call_back(tx_req->dio_req, tx_req->cb_event, cs);
tx_req->dio_req = NULL;
tx_req->cb_event = NULL;
tx_req->call_back = NULL;
} else {
BCMLOG(BCMLOG_DBG, "Missing Tx Callback - %X\n",
tx_req->list_tag);
}
/* Now put back the tx_list back in FreeQ */
tx_req->list_tag = 0;
return crystalhd_dioq_add(hw->tx_freeq, tx_req, false, 0);
}
static bool crystalhd_tx_list0_handler(struct crystalhd_hw *hw,
uint32_t err_sts)
{
uint32_t err_mask, tmp;
unsigned long flags = 0;
err_mask = MISC1_TX_DMA_ERROR_STATUS_TX_L0_DESC_TX_ABORT_ERRORS_MASK |
MISC1_TX_DMA_ERROR_STATUS_TX_L0_DMA_DATA_TX_ABORT_ERRORS_MASK |
MISC1_TX_DMA_ERROR_STATUS_TX_L0_FIFO_FULL_ERRORS_MASK;
if (!(err_sts & err_mask))
return false;
BCMLOG_ERR("Error on Tx-L0 %x\n", err_sts);
tmp = err_mask;
if (err_sts & MISC1_TX_DMA_ERROR_STATUS_TX_L0_FIFO_FULL_ERRORS_MASK)
tmp &= ~MISC1_TX_DMA_ERROR_STATUS_TX_L0_FIFO_FULL_ERRORS_MASK;
if (tmp) {
spin_lock_irqsave(&hw->lock, flags);
/* reset list index.*/
hw->tx_list_post_index = 0;
spin_unlock_irqrestore(&hw->lock, flags);
}
tmp = err_sts & err_mask;
crystalhd_reg_wr(hw->adp, MISC1_TX_DMA_ERROR_STATUS, tmp);
return true;
}
static bool crystalhd_tx_list1_handler(struct crystalhd_hw *hw,
uint32_t err_sts)
{
uint32_t err_mask, tmp;
unsigned long flags = 0;
err_mask = MISC1_TX_DMA_ERROR_STATUS_TX_L1_DESC_TX_ABORT_ERRORS_MASK |
MISC1_TX_DMA_ERROR_STATUS_TX_L1_DMA_DATA_TX_ABORT_ERRORS_MASK |
MISC1_TX_DMA_ERROR_STATUS_TX_L1_FIFO_FULL_ERRORS_MASK;
if (!(err_sts & err_mask))
return false;
BCMLOG_ERR("Error on Tx-L1 %x\n", err_sts);
tmp = err_mask;
if (err_sts & MISC1_TX_DMA_ERROR_STATUS_TX_L1_FIFO_FULL_ERRORS_MASK)
tmp &= ~MISC1_TX_DMA_ERROR_STATUS_TX_L1_FIFO_FULL_ERRORS_MASK;
if (tmp) {
spin_lock_irqsave(&hw->lock, flags);
/* reset list index.*/
hw->tx_list_post_index = 0;
spin_unlock_irqrestore(&hw->lock, flags);
}
tmp = err_sts & err_mask;
crystalhd_reg_wr(hw->adp, MISC1_TX_DMA_ERROR_STATUS, tmp);
return true;
}
static void crystalhd_tx_isr(struct crystalhd_hw *hw, uint32_t int_sts)
{
uint32_t err_sts;
if (int_sts & INTR_INTR_STATUS_L0_TX_DMA_DONE_INTR_MASK)
crystalhd_hw_tx_req_complete(hw, hw->tx_ioq_tag_seed + 0,
BC_STS_SUCCESS);
if (int_sts & INTR_INTR_STATUS_L1_TX_DMA_DONE_INTR_MASK)
crystalhd_hw_tx_req_complete(hw, hw->tx_ioq_tag_seed + 1,
BC_STS_SUCCESS);
if (!(int_sts & (INTR_INTR_STATUS_L0_TX_DMA_ERR_INTR_MASK |
INTR_INTR_STATUS_L1_TX_DMA_ERR_INTR_MASK))) {
/* No error mask set.. */
return;
}
/* Handle Tx errors. */
err_sts = crystalhd_reg_rd(hw->adp, MISC1_TX_DMA_ERROR_STATUS);
if (crystalhd_tx_list0_handler(hw, err_sts))
crystalhd_hw_tx_req_complete(hw, hw->tx_ioq_tag_seed + 0,
BC_STS_ERROR);
if (crystalhd_tx_list1_handler(hw, err_sts))
crystalhd_hw_tx_req_complete(hw, hw->tx_ioq_tag_seed + 1,
BC_STS_ERROR);
hw->stats.tx_errors++;
}
static void crystalhd_hw_dump_desc(struct dma_descriptor *p_dma_desc,
uint32_t ul_desc_index, uint32_t cnt)
{
uint32_t ix, ll = 0;
if (!p_dma_desc || !cnt)
return;
/* FIXME: jarod: perhaps a modparam desc_debug to enable this,
rather than setting ll (log level, I presume) to non-zero? */
if (!ll)
return;
for (ix = ul_desc_index; ix < (ul_desc_index + cnt); ix++) {
BCMLOG(ll,
"%s[%d] Buff[%x:%x] Next:[%x:%x] XferSz:%x Intr:%x,Last:%x\n",
((p_dma_desc[ul_desc_index].dma_dir) ? "TDesc" : "RDesc"),
ul_desc_index,
p_dma_desc[ul_desc_index].buff_addr_high,
p_dma_desc[ul_desc_index].buff_addr_low,
p_dma_desc[ul_desc_index].next_desc_addr_high,
p_dma_desc[ul_desc_index].next_desc_addr_low,
p_dma_desc[ul_desc_index].xfer_size,
p_dma_desc[ul_desc_index].intr_enable,
p_dma_desc[ul_desc_index].last_rec_indicator);
}
}
static enum BC_STATUS crystalhd_hw_fill_desc(struct crystalhd_dio_req *ioreq,
struct dma_descriptor *desc,
dma_addr_t desc_paddr_base,
uint32_t sg_cnt, uint32_t sg_st_ix,
uint32_t sg_st_off, uint32_t xfr_sz)
{
uint32_t count = 0, ix = 0, sg_ix = 0, len = 0, last_desc_ix = 0;
dma_addr_t desc_phy_addr = desc_paddr_base;
union addr_64 addr_temp;
if (!ioreq || !desc || !desc_paddr_base || !xfr_sz ||
(!sg_cnt && !ioreq->uinfo.dir_tx)) {
BCMLOG_ERR("Invalid Args\n");
return BC_STS_INV_ARG;
}
for (ix = 0; ix < sg_cnt; ix++) {
/* Setup SGLE index. */
sg_ix = ix + sg_st_ix;
/* Get SGLE length */
len = crystalhd_get_sgle_len(ioreq, sg_ix);
if (len % 4) {
BCMLOG_ERR(" len in sg %d %d %d\n", len, sg_ix,
sg_cnt);
return BC_STS_NOT_IMPL;
}
/* Setup DMA desc with Phy addr & Length at current index. */
addr_temp.full_addr = crystalhd_get_sgle_paddr(ioreq, sg_ix);
if (sg_ix == sg_st_ix) {
addr_temp.full_addr += sg_st_off;
len -= sg_st_off;
}
memset(&desc[ix], 0, sizeof(desc[ix]));
desc[ix].buff_addr_low = addr_temp.low_part;
desc[ix].buff_addr_high = addr_temp.high_part;
desc[ix].dma_dir = ioreq->uinfo.dir_tx;
/* Chain DMA descriptor. */
addr_temp.full_addr = desc_phy_addr +
sizeof(struct dma_descriptor);
desc[ix].next_desc_addr_low = addr_temp.low_part;
desc[ix].next_desc_addr_high = addr_temp.high_part;
if ((count + len) > xfr_sz)
len = xfr_sz - count;
/* Debug.. */
if ((!len) || (len > crystalhd_get_sgle_len(ioreq, sg_ix))) {
BCMLOG_ERR(
"inv-len(%x) Ix(%d) count:%x xfr_sz:%x sg_cnt:%d\n",
len, ix, count, xfr_sz, sg_cnt);
return BC_STS_ERROR;
}
/* Length expects Multiple of 4 */
desc[ix].xfer_size = (len / 4);
crystalhd_hw_dump_desc(desc, ix, 1);
count += len;
desc_phy_addr += sizeof(struct dma_descriptor);
}
last_desc_ix = ix - 1;
if (ioreq->fb_size) {
memset(&desc[ix], 0, sizeof(desc[ix]));
addr_temp.full_addr = ioreq->fb_pa;
desc[ix].buff_addr_low = addr_temp.low_part;
desc[ix].buff_addr_high = addr_temp.high_part;
desc[ix].dma_dir = ioreq->uinfo.dir_tx;
desc[ix].xfer_size = 1;
desc[ix].fill_bytes = 4 - ioreq->fb_size;
count += ioreq->fb_size;
last_desc_ix++;
}
/* setup last descriptor..*/
desc[last_desc_ix].last_rec_indicator = 1;
desc[last_desc_ix].next_desc_addr_low = 0;
desc[last_desc_ix].next_desc_addr_high = 0;
desc[last_desc_ix].intr_enable = 1;
crystalhd_hw_dump_desc(desc, last_desc_ix, 1);
if (count != xfr_sz) {
BCMLOG_ERR("internal error sz curr:%x exp:%x\n", count, xfr_sz);
return BC_STS_ERROR;
}
return BC_STS_SUCCESS;
}
static enum BC_STATUS crystalhd_xlat_sgl_to_dma_desc(
struct crystalhd_dio_req *ioreq,
struct dma_desc_mem *pdesc_mem,
uint32_t *uv_desc_index)
{
struct dma_descriptor *desc = NULL;
dma_addr_t desc_paddr_base = 0;
uint32_t sg_cnt = 0, sg_st_ix = 0, sg_st_off = 0;
uint32_t xfr_sz = 0;
enum BC_STATUS sts = BC_STS_SUCCESS;
/* Check params.. */
if (!ioreq || !pdesc_mem || !uv_desc_index) {
BCMLOG_ERR("Invalid Args\n");
return BC_STS_INV_ARG;
}
if (!pdesc_mem->sz || !pdesc_mem->pdma_desc_start ||
!ioreq->sg || (!ioreq->sg_cnt && !ioreq->uinfo.dir_tx)) {
BCMLOG_ERR("Invalid Args\n");
return BC_STS_INV_ARG;
}
if ((ioreq->uinfo.dir_tx) && (ioreq->uinfo.uv_offset)) {
BCMLOG_ERR("UV offset for TX??\n");
return BC_STS_INV_ARG;
}
desc = pdesc_mem->pdma_desc_start;
desc_paddr_base = pdesc_mem->phy_addr;
if (ioreq->uinfo.dir_tx || (ioreq->uinfo.uv_offset == 0)) {
sg_cnt = ioreq->sg_cnt;
xfr_sz = ioreq->uinfo.xfr_len;
} else {
sg_cnt = ioreq->uinfo.uv_sg_ix + 1;
xfr_sz = ioreq->uinfo.uv_offset;
}
sts = crystalhd_hw_fill_desc(ioreq, desc, desc_paddr_base, sg_cnt,
sg_st_ix, sg_st_off, xfr_sz);
if ((sts != BC_STS_SUCCESS) || !ioreq->uinfo.uv_offset)
return sts;
/* Prepare for UV mapping.. */
desc = &pdesc_mem->pdma_desc_start[sg_cnt];
desc_paddr_base = pdesc_mem->phy_addr +
(sg_cnt * sizeof(struct dma_descriptor));
/* Done with desc addr.. now update sg stuff.*/
sg_cnt = ioreq->sg_cnt - ioreq->uinfo.uv_sg_ix;
xfr_sz = ioreq->uinfo.xfr_len - ioreq->uinfo.uv_offset;
sg_st_ix = ioreq->uinfo.uv_sg_ix;
sg_st_off = ioreq->uinfo.uv_sg_off;
sts = crystalhd_hw_fill_desc(ioreq, desc, desc_paddr_base, sg_cnt,
sg_st_ix, sg_st_off, xfr_sz);
if (sts != BC_STS_SUCCESS)
return sts;
*uv_desc_index = sg_st_ix;
return sts;
}
static void crystalhd_start_tx_dma_engine(struct crystalhd_hw *hw)
{
uint32_t dma_cntrl;
dma_cntrl = crystalhd_reg_rd(hw->adp, MISC1_TX_SW_DESC_LIST_CTRL_STS);
if (!(dma_cntrl & DMA_START_BIT)) {
dma_cntrl |= DMA_START_BIT;
crystalhd_reg_wr(hw->adp, MISC1_TX_SW_DESC_LIST_CTRL_STS,
dma_cntrl);
}
return;
}
/* _CHECK_THIS_
*
* Verify if the Stop generates a completion interrupt or not.
* if it does not generate an interrupt, then add polling here.
*/
static enum BC_STATUS crystalhd_stop_tx_dma_engine(struct crystalhd_hw *hw)
{
uint32_t dma_cntrl, cnt = 30;
uint32_t l1 = 1, l2 = 1;
unsigned long flags = 0;
dma_cntrl = crystalhd_reg_rd(hw->adp, MISC1_TX_SW_DESC_LIST_CTRL_STS);
BCMLOG(BCMLOG_DBG, "Stopping TX DMA Engine..\n");
if (!(dma_cntrl & DMA_START_BIT)) {
BCMLOG(BCMLOG_DBG, "Already Stopped\n");
return BC_STS_SUCCESS;
}
crystalhd_disable_interrupts(hw->adp);
/* Issue stop to HW */
/* This bit when set gave problems. Please check*/
dma_cntrl &= ~DMA_START_BIT;
crystalhd_reg_wr(hw->adp, MISC1_TX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
BCMLOG(BCMLOG_DBG, "Cleared the DMA Start bit\n");
/* Poll for 3seconds (30 * 100ms) on both the lists..*/
while ((l1 || l2) && cnt) {
if (l1) {
l1 = crystalhd_reg_rd(hw->adp,
MISC1_TX_FIRST_DESC_L_ADDR_LIST0);
l1 &= DMA_START_BIT;
}
if (l2) {
l2 = crystalhd_reg_rd(hw->adp,
MISC1_TX_FIRST_DESC_L_ADDR_LIST1);
l2 &= DMA_START_BIT;
}
msleep_interruptible(100);
cnt--;
}
if (!cnt) {
BCMLOG_ERR("Failed to stop TX DMA.. l1 %d, l2 %d\n", l1, l2);
crystalhd_enable_interrupts(hw->adp);
return BC_STS_ERROR;
}
spin_lock_irqsave(&hw->lock, flags);
hw->tx_list_post_index = 0;
spin_unlock_irqrestore(&hw->lock, flags);
BCMLOG(BCMLOG_DBG, "stopped TX DMA..\n");
crystalhd_enable_interrupts(hw->adp);
return BC_STS_SUCCESS;
}
static uint32_t crystalhd_get_pib_avail_cnt(struct crystalhd_hw *hw)
{
/*
* Position of the PIB Entries can be found at
* 0th and the 1st location of the Circular list.
*/
uint32_t Q_addr;
uint32_t pib_cnt, r_offset, w_offset;
Q_addr = hw->pib_del_Q_addr;
/* Get the Read Pointer */
crystalhd_mem_rd(hw->adp, Q_addr, 1, &r_offset);
/* Get the Write Pointer */
crystalhd_mem_rd(hw->adp, Q_addr + sizeof(uint32_t), 1, &w_offset);
if (r_offset == w_offset)
return 0; /* Queue is empty */
if (w_offset > r_offset)
pib_cnt = w_offset - r_offset;
else
pib_cnt = (w_offset + MAX_PIB_Q_DEPTH) -
(r_offset + MIN_PIB_Q_DEPTH);
if (pib_cnt > MAX_PIB_Q_DEPTH) {
BCMLOG_ERR("Invalid PIB Count (%u)\n", pib_cnt);
return 0;
}
return pib_cnt;
}
static uint32_t crystalhd_get_addr_from_pib_Q(struct crystalhd_hw *hw)
{
uint32_t Q_addr;
uint32_t addr_entry, r_offset, w_offset;
Q_addr = hw->pib_del_Q_addr;
/* Get the Read Pointer 0Th Location is Read Pointer */
crystalhd_mem_rd(hw->adp, Q_addr, 1, &r_offset);
/* Get the Write Pointer 1st Location is Write pointer */
crystalhd_mem_rd(hw->adp, Q_addr + sizeof(uint32_t), 1, &w_offset);
/* Queue is empty */
if (r_offset == w_offset)
return 0;
if ((r_offset < MIN_PIB_Q_DEPTH) || (r_offset >= MAX_PIB_Q_DEPTH))
return 0;
/* Get the Actual Address of the PIB */
crystalhd_mem_rd(hw->adp, Q_addr + (r_offset * sizeof(uint32_t)),
1, &addr_entry);
/* Increment the Read Pointer */
r_offset++;
if (MAX_PIB_Q_DEPTH == r_offset)
r_offset = MIN_PIB_Q_DEPTH;
/* Write back the read pointer to It's Location */
crystalhd_mem_wr(hw->adp, Q_addr, 1, &r_offset);
return addr_entry;
}
static bool crystalhd_rel_addr_to_pib_Q(struct crystalhd_hw *hw,
uint32_t addr_to_rel)
{
uint32_t Q_addr;
uint32_t r_offset, w_offset, n_offset;
Q_addr = hw->pib_rel_Q_addr;
/* Get the Read Pointer */
crystalhd_mem_rd(hw->adp, Q_addr, 1, &r_offset);
/* Get the Write Pointer */
crystalhd_mem_rd(hw->adp, Q_addr + sizeof(uint32_t), 1, &w_offset);
if ((r_offset < MIN_PIB_Q_DEPTH) ||
(r_offset >= MAX_PIB_Q_DEPTH))
return false;
n_offset = w_offset + 1;
if (MAX_PIB_Q_DEPTH == n_offset)
n_offset = MIN_PIB_Q_DEPTH;
if (r_offset == n_offset)
return false; /* should never happen */
/* Write the DRAM ADDR to the Queue at Next Offset */
crystalhd_mem_wr(hw->adp, Q_addr + (w_offset * sizeof(uint32_t)),
1, &addr_to_rel);
/* Put the New value of the write pointer in Queue */
crystalhd_mem_wr(hw->adp, Q_addr + sizeof(uint32_t), 1, &n_offset);
return true;
}
static void cpy_pib_to_app(struct c011_pib *src_pib,
struct BC_PIC_INFO_BLOCK *dst_pib)
{
if (!src_pib || !dst_pib) {
BCMLOG_ERR("Invalid Arguments\n");
return;
}
dst_pib->timeStamp = 0;
dst_pib->picture_number = src_pib->ppb.picture_number;
dst_pib->width = src_pib->ppb.width;
dst_pib->height = src_pib->ppb.height;
dst_pib->chroma_format = src_pib->ppb.chroma_format;
dst_pib->pulldown = src_pib->ppb.pulldown;
dst_pib->flags = src_pib->ppb.flags;
dst_pib->sess_num = src_pib->ptsStcOffset;
dst_pib->aspect_ratio = src_pib->ppb.aspect_ratio;
dst_pib->colour_primaries = src_pib->ppb.colour_primaries;
dst_pib->picture_meta_payload = src_pib->ppb.picture_meta_payload;
dst_pib->frame_rate = src_pib->resolution;
return;
}
static void crystalhd_hw_proc_pib(struct crystalhd_hw *hw)
{
unsigned int cnt;
struct c011_pib src_pib;
uint32_t pib_addr, pib_cnt;
struct BC_PIC_INFO_BLOCK *AppPib;
struct crystalhd_rx_dma_pkt *rx_pkt = NULL;
pib_cnt = crystalhd_get_pib_avail_cnt(hw);
if (!pib_cnt)
return;
for (cnt = 0; cnt < pib_cnt; cnt++) {
pib_addr = crystalhd_get_addr_from_pib_Q(hw);
crystalhd_mem_rd(hw->adp, pib_addr, sizeof(struct c011_pib) / 4,
(uint32_t *)&src_pib);
if (src_pib.bFormatChange) {
rx_pkt = (struct crystalhd_rx_dma_pkt *)
crystalhd_dioq_fetch(hw->rx_freeq);
if (!rx_pkt)
return;
rx_pkt->flags = 0;
rx_pkt->flags |= COMP_FLAG_PIB_VALID |
COMP_FLAG_FMT_CHANGE;
AppPib = &rx_pkt->pib;
cpy_pib_to_app(&src_pib, AppPib);
BCMLOG(BCMLOG_DBG,
"App PIB:%x %x %x %x %x %x %x %x %x %x\n",
rx_pkt->pib.picture_number,
rx_pkt->pib.aspect_ratio,
rx_pkt->pib.chroma_format,
rx_pkt->pib.colour_primaries,
rx_pkt->pib.frame_rate,
rx_pkt->pib.height,
rx_pkt->pib.height,
rx_pkt->pib.n_drop,
rx_pkt->pib.pulldown,
rx_pkt->pib.ycom);
crystalhd_dioq_add(hw->rx_rdyq, (void *)rx_pkt, true,
rx_pkt->pkt_tag);
}
crystalhd_rel_addr_to_pib_Q(hw, pib_addr);
}
}
static void crystalhd_start_rx_dma_engine(struct crystalhd_hw *hw)
{
uint32_t dma_cntrl;
dma_cntrl = crystalhd_reg_rd(hw->adp,
MISC1_Y_RX_SW_DESC_LIST_CTRL_STS);
if (!(dma_cntrl & DMA_START_BIT)) {
dma_cntrl |= DMA_START_BIT;
crystalhd_reg_wr(hw->adp,
MISC1_Y_RX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
}
dma_cntrl = crystalhd_reg_rd(hw->adp,
MISC1_UV_RX_SW_DESC_LIST_CTRL_STS);
if (!(dma_cntrl & DMA_START_BIT)) {
dma_cntrl |= DMA_START_BIT;
crystalhd_reg_wr(hw->adp,
MISC1_UV_RX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
}
return;
}
static void crystalhd_stop_rx_dma_engine(struct crystalhd_hw *hw)
{
uint32_t dma_cntrl = 0, count = 30;
uint32_t l0y = 1, l0uv = 1, l1y = 1, l1uv = 1;
dma_cntrl = crystalhd_reg_rd(hw->adp,
MISC1_Y_RX_SW_DESC_LIST_CTRL_STS);
if ((dma_cntrl & DMA_START_BIT)) {
dma_cntrl &= ~DMA_START_BIT;
crystalhd_reg_wr(hw->adp,
MISC1_Y_RX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
}
dma_cntrl = crystalhd_reg_rd(hw->adp,
MISC1_UV_RX_SW_DESC_LIST_CTRL_STS);
if ((dma_cntrl & DMA_START_BIT)) {
dma_cntrl &= ~DMA_START_BIT;
crystalhd_reg_wr(hw->adp,
MISC1_UV_RX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
}
/* Poll for 3seconds (30 * 100ms) on both the lists..*/
while ((l0y || l0uv || l1y || l1uv) && count) {
if (l0y) {
l0y = crystalhd_reg_rd(hw->adp,
MISC1_Y_RX_FIRST_DESC_L_ADDR_LIST0);
l0y &= DMA_START_BIT;
if (!l0y)
hw->rx_list_sts[0] &= ~rx_waiting_y_intr;
}
if (l1y) {
l1y = crystalhd_reg_rd(hw->adp,
MISC1_Y_RX_FIRST_DESC_L_ADDR_LIST1);
l1y &= DMA_START_BIT;
if (!l1y)
hw->rx_list_sts[1] &= ~rx_waiting_y_intr;
}
if (l0uv) {
l0uv = crystalhd_reg_rd(hw->adp,
MISC1_UV_RX_FIRST_DESC_L_ADDR_LIST0);
l0uv &= DMA_START_BIT;
if (!l0uv)
hw->rx_list_sts[0] &= ~rx_waiting_uv_intr;
}
if (l1uv) {
l1uv = crystalhd_reg_rd(hw->adp,
MISC1_UV_RX_FIRST_DESC_L_ADDR_LIST1);
l1uv &= DMA_START_BIT;
if (!l1uv)
hw->rx_list_sts[1] &= ~rx_waiting_uv_intr;
}
msleep_interruptible(100);
count--;
}
hw->rx_list_post_index = 0;
BCMLOG(BCMLOG_SSTEP, "Capture Stop: %d List0:Sts:%x List1:Sts:%x\n",
count, hw->rx_list_sts[0], hw->rx_list_sts[1]);
}
static enum BC_STATUS crystalhd_hw_prog_rxdma(struct crystalhd_hw *hw,
struct crystalhd_rx_dma_pkt *rx_pkt)
{
uint32_t y_low_addr_reg, y_high_addr_reg;
uint32_t uv_low_addr_reg, uv_high_addr_reg;
union addr_64 desc_addr;
unsigned long flags;
if (!hw || !rx_pkt) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
if (hw->rx_list_post_index >= DMA_ENGINE_CNT) {
BCMLOG_ERR("List Out Of bounds %x\n", hw->rx_list_post_index);
return BC_STS_INV_ARG;
}
spin_lock_irqsave(&hw->rx_lock, flags);
/* FIXME: jarod: sts_free is an enum for 0,
in crystalhd_hw.h... yuk... */
if (sts_free != hw->rx_list_sts[hw->rx_list_post_index]) {
spin_unlock_irqrestore(&hw->rx_lock, flags);
return BC_STS_BUSY;
}
if (!hw->rx_list_post_index) {
y_low_addr_reg = MISC1_Y_RX_FIRST_DESC_L_ADDR_LIST0;
y_high_addr_reg = MISC1_Y_RX_FIRST_DESC_U_ADDR_LIST0;
uv_low_addr_reg = MISC1_UV_RX_FIRST_DESC_L_ADDR_LIST0;
uv_high_addr_reg = MISC1_UV_RX_FIRST_DESC_U_ADDR_LIST0;
} else {
y_low_addr_reg = MISC1_Y_RX_FIRST_DESC_L_ADDR_LIST1;
y_high_addr_reg = MISC1_Y_RX_FIRST_DESC_U_ADDR_LIST1;
uv_low_addr_reg = MISC1_UV_RX_FIRST_DESC_L_ADDR_LIST1;
uv_high_addr_reg = MISC1_UV_RX_FIRST_DESC_U_ADDR_LIST1;
}
rx_pkt->pkt_tag = hw->rx_pkt_tag_seed + hw->rx_list_post_index;
hw->rx_list_sts[hw->rx_list_post_index] |= rx_waiting_y_intr;
if (rx_pkt->uv_phy_addr)
hw->rx_list_sts[hw->rx_list_post_index] |= rx_waiting_uv_intr;
hw->rx_list_post_index = (hw->rx_list_post_index + 1) % DMA_ENGINE_CNT;
spin_unlock_irqrestore(&hw->rx_lock, flags);
crystalhd_dioq_add(hw->rx_actq, (void *)rx_pkt, false,
rx_pkt->pkt_tag);
crystalhd_start_rx_dma_engine(hw);
/* Program the Y descriptor */
desc_addr.full_addr = rx_pkt->desc_mem.phy_addr;
crystalhd_reg_wr(hw->adp, y_high_addr_reg, desc_addr.high_part);
crystalhd_reg_wr(hw->adp, y_low_addr_reg, desc_addr.low_part | 0x01);
if (rx_pkt->uv_phy_addr) {
/* Program the UV descriptor */
desc_addr.full_addr = rx_pkt->uv_phy_addr;
crystalhd_reg_wr(hw->adp, uv_high_addr_reg,
desc_addr.high_part);
crystalhd_reg_wr(hw->adp, uv_low_addr_reg,
desc_addr.low_part | 0x01);
}
return BC_STS_SUCCESS;
}
static enum BC_STATUS crystalhd_hw_post_cap_buff(struct crystalhd_hw *hw,
struct crystalhd_rx_dma_pkt *rx_pkt)
{
enum BC_STATUS sts = crystalhd_hw_prog_rxdma(hw, rx_pkt);
if (sts == BC_STS_BUSY)
crystalhd_dioq_add(hw->rx_freeq, (void *)rx_pkt,
false, rx_pkt->pkt_tag);
return sts;
}
static void crystalhd_get_dnsz(struct crystalhd_hw *hw, uint32_t list_index,
uint32_t *y_dw_dnsz, uint32_t *uv_dw_dnsz)
{
uint32_t y_dn_sz_reg, uv_dn_sz_reg;
if (!list_index) {
y_dn_sz_reg = MISC1_Y_RX_LIST0_CUR_BYTE_CNT;
uv_dn_sz_reg = MISC1_UV_RX_LIST0_CUR_BYTE_CNT;
} else {
y_dn_sz_reg = MISC1_Y_RX_LIST1_CUR_BYTE_CNT;
uv_dn_sz_reg = MISC1_UV_RX_LIST1_CUR_BYTE_CNT;
}
*y_dw_dnsz = crystalhd_reg_rd(hw->adp, y_dn_sz_reg);
*uv_dw_dnsz = crystalhd_reg_rd(hw->adp, uv_dn_sz_reg);
}
/*
* This function should be called only after making sure that the two DMA
* lists are free. This function does not check if DMA's are active, before
* turning off the DMA.
*/
static void crystalhd_hw_finalize_pause(struct crystalhd_hw *hw)
{
uint32_t dma_cntrl, aspm;
hw->stop_pending = 0;
dma_cntrl = crystalhd_reg_rd(hw->adp,
MISC1_Y_RX_SW_DESC_LIST_CTRL_STS);
if (dma_cntrl & DMA_START_BIT) {
dma_cntrl &= ~DMA_START_BIT;
crystalhd_reg_wr(hw->adp,
MISC1_Y_RX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
}
dma_cntrl = crystalhd_reg_rd(hw->adp,
MISC1_UV_RX_SW_DESC_LIST_CTRL_STS);
if (dma_cntrl & DMA_START_BIT) {
dma_cntrl &= ~DMA_START_BIT;
crystalhd_reg_wr(hw->adp,
MISC1_UV_RX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
}
hw->rx_list_post_index = 0;
aspm = crystalhd_reg_rd(hw->adp, PCIE_DLL_DATA_LINK_CONTROL);
aspm |= ASPM_L1_ENABLE;
/* NAREN BCMLOG(BCMLOG_INFO, "aspm on\n"); */
crystalhd_reg_wr(hw->adp, PCIE_DLL_DATA_LINK_CONTROL, aspm);
}
static enum BC_STATUS crystalhd_rx_pkt_done(struct crystalhd_hw *hw,
uint32_t list_index, enum BC_STATUS comp_sts)
{
struct crystalhd_rx_dma_pkt *rx_pkt = NULL;
uint32_t y_dw_dnsz, uv_dw_dnsz;
enum BC_STATUS sts = BC_STS_SUCCESS;
if (!hw || list_index >= DMA_ENGINE_CNT) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
rx_pkt = crystalhd_dioq_find_and_fetch(hw->rx_actq,
hw->rx_pkt_tag_seed + list_index);
if (!rx_pkt) {
BCMLOG_ERR(
"Act-Q:PostIx:%x L0Sts:%x L1Sts:%x current L:%x tag:%x comp:%x\n",
hw->rx_list_post_index, hw->rx_list_sts[0],
hw->rx_list_sts[1], list_index,
hw->rx_pkt_tag_seed + list_index, comp_sts);
return BC_STS_INV_ARG;
}
if (comp_sts == BC_STS_SUCCESS) {
crystalhd_get_dnsz(hw, list_index, &y_dw_dnsz, &uv_dw_dnsz);
rx_pkt->dio_req->uinfo.y_done_sz = y_dw_dnsz;
rx_pkt->flags = COMP_FLAG_DATA_VALID;
if (rx_pkt->uv_phy_addr)
rx_pkt->dio_req->uinfo.uv_done_sz = uv_dw_dnsz;
crystalhd_dioq_add(hw->rx_rdyq, rx_pkt, true,
hw->rx_pkt_tag_seed + list_index);
return sts;
}
/* Check if we can post this DIO again. */
return crystalhd_hw_post_cap_buff(hw, rx_pkt);
}
static bool crystalhd_rx_list0_handler(struct crystalhd_hw *hw,
uint32_t int_sts, uint32_t y_err_sts, uint32_t uv_err_sts)
{
uint32_t tmp;
enum list_sts tmp_lsts;
if (!(y_err_sts & GET_Y0_ERR_MSK) && !(uv_err_sts & GET_UV0_ERR_MSK))
return false;
tmp_lsts = hw->rx_list_sts[0];
/* Y0 - DMA */
tmp = y_err_sts & GET_Y0_ERR_MSK;
if (int_sts & INTR_INTR_STATUS_L0_Y_RX_DMA_DONE_INTR_MASK)
hw->rx_list_sts[0] &= ~rx_waiting_y_intr;
if (y_err_sts & MISC1_Y_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_MASK) {
hw->rx_list_sts[0] &= ~rx_waiting_y_intr;
tmp &= ~MISC1_Y_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_MASK;
}
if (y_err_sts & MISC1_Y_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_MASK) {
hw->rx_list_sts[0] &= ~rx_y_mask;
hw->rx_list_sts[0] |= rx_y_error;
tmp &= ~MISC1_Y_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_MASK;
}
if (tmp) {
hw->rx_list_sts[0] &= ~rx_y_mask;
hw->rx_list_sts[0] |= rx_y_error;
hw->rx_list_post_index = 0;
}
/* UV0 - DMA */
tmp = uv_err_sts & GET_UV0_ERR_MSK;
if (int_sts & INTR_INTR_STATUS_L0_UV_RX_DMA_DONE_INTR_MASK)
hw->rx_list_sts[0] &= ~rx_waiting_uv_intr;
if (uv_err_sts & MISC1_UV_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_MASK) {
hw->rx_list_sts[0] &= ~rx_waiting_uv_intr;
tmp &= ~MISC1_UV_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_MASK;
}
if (uv_err_sts &
MISC1_UV_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_MASK) {
hw->rx_list_sts[0] &= ~rx_uv_mask;
hw->rx_list_sts[0] |= rx_uv_error;
tmp &= ~MISC1_UV_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_MASK;
}
if (tmp) {
hw->rx_list_sts[0] &= ~rx_uv_mask;
hw->rx_list_sts[0] |= rx_uv_error;
hw->rx_list_post_index = 0;
}
if (y_err_sts & GET_Y0_ERR_MSK) {
tmp = y_err_sts & GET_Y0_ERR_MSK;
crystalhd_reg_wr(hw->adp, MISC1_Y_RX_ERROR_STATUS, tmp);
}
if (uv_err_sts & GET_UV0_ERR_MSK) {
tmp = uv_err_sts & GET_UV0_ERR_MSK;
crystalhd_reg_wr(hw->adp, MISC1_UV_RX_ERROR_STATUS, tmp);
}
return tmp_lsts != hw->rx_list_sts[0];
}
static bool crystalhd_rx_list1_handler(struct crystalhd_hw *hw,
uint32_t int_sts, uint32_t y_err_sts, uint32_t uv_err_sts)
{
uint32_t tmp;
enum list_sts tmp_lsts;
if (!(y_err_sts & GET_Y1_ERR_MSK) && !(uv_err_sts & GET_UV1_ERR_MSK))
return false;
tmp_lsts = hw->rx_list_sts[1];
/* Y1 - DMA */
tmp = y_err_sts & GET_Y1_ERR_MSK;
if (int_sts & INTR_INTR_STATUS_L1_Y_RX_DMA_DONE_INTR_MASK)
hw->rx_list_sts[1] &= ~rx_waiting_y_intr;
if (y_err_sts & MISC1_Y_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_MASK) {
hw->rx_list_sts[1] &= ~rx_waiting_y_intr;
tmp &= ~MISC1_Y_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_MASK;
}
if (y_err_sts & MISC1_Y_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_MASK) {
/* Add retry-support..*/
hw->rx_list_sts[1] &= ~rx_y_mask;
hw->rx_list_sts[1] |= rx_y_error;
tmp &= ~MISC1_Y_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_MASK;
}
if (tmp) {
hw->rx_list_sts[1] &= ~rx_y_mask;
hw->rx_list_sts[1] |= rx_y_error;
hw->rx_list_post_index = 0;
}
/* UV1 - DMA */
tmp = uv_err_sts & GET_UV1_ERR_MSK;
if (int_sts & INTR_INTR_STATUS_L1_UV_RX_DMA_DONE_INTR_MASK)
hw->rx_list_sts[1] &= ~rx_waiting_uv_intr;
if (uv_err_sts & MISC1_UV_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_MASK) {
hw->rx_list_sts[1] &= ~rx_waiting_uv_intr;
tmp &= ~MISC1_UV_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_MASK;
}
if (uv_err_sts & MISC1_UV_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_MASK) {
/* Add retry-support*/
hw->rx_list_sts[1] &= ~rx_uv_mask;
hw->rx_list_sts[1] |= rx_uv_error;
tmp &= ~MISC1_UV_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_MASK;
}
if (tmp) {
hw->rx_list_sts[1] &= ~rx_uv_mask;
hw->rx_list_sts[1] |= rx_uv_error;
hw->rx_list_post_index = 0;
}
if (y_err_sts & GET_Y1_ERR_MSK) {
tmp = y_err_sts & GET_Y1_ERR_MSK;
crystalhd_reg_wr(hw->adp, MISC1_Y_RX_ERROR_STATUS, tmp);
}
if (uv_err_sts & GET_UV1_ERR_MSK) {
tmp = uv_err_sts & GET_UV1_ERR_MSK;
crystalhd_reg_wr(hw->adp, MISC1_UV_RX_ERROR_STATUS, tmp);
}
return tmp_lsts != hw->rx_list_sts[1];
}
static void crystalhd_rx_isr(struct crystalhd_hw *hw, uint32_t intr_sts)
{
unsigned long flags;
uint32_t i, list_avail = 0;
enum BC_STATUS comp_sts = BC_STS_NO_DATA;
uint32_t y_err_sts, uv_err_sts, y_dn_sz = 0, uv_dn_sz = 0;
bool ret = false;
if (!hw) {
BCMLOG_ERR("Invalid Arguments\n");
return;
}
if (!(intr_sts & GET_RX_INTR_MASK))
return;
y_err_sts = crystalhd_reg_rd(hw->adp, MISC1_Y_RX_ERROR_STATUS);
uv_err_sts = crystalhd_reg_rd(hw->adp, MISC1_UV_RX_ERROR_STATUS);
for (i = 0; i < DMA_ENGINE_CNT; i++) {
/* Update States..*/
spin_lock_irqsave(&hw->rx_lock, flags);
if (i == 0)
ret = crystalhd_rx_list0_handler(hw, intr_sts,
y_err_sts, uv_err_sts);
else
ret = crystalhd_rx_list1_handler(hw, intr_sts,
y_err_sts, uv_err_sts);
if (ret) {
switch (hw->rx_list_sts[i]) {
case sts_free:
comp_sts = BC_STS_SUCCESS;
list_avail = 1;
break;
case rx_y_error:
case rx_uv_error:
case rx_sts_error:
/* We got error on both or Y or uv. */
hw->stats.rx_errors++;
crystalhd_get_dnsz(hw, i, &y_dn_sz, &uv_dn_sz);
/* FIXME: jarod: this is where
my mini pci-e card is tripping up */
BCMLOG(BCMLOG_DBG, "list_index:%x rx[%d] Y:%x UV:%x Int:%x YDnSz:%x UVDnSz:%x\n",
i, hw->stats.rx_errors, y_err_sts,
uv_err_sts, intr_sts, y_dn_sz,
uv_dn_sz);
hw->rx_list_sts[i] = sts_free;
comp_sts = BC_STS_ERROR;
break;
default:
/* Wait for completion..*/
comp_sts = BC_STS_NO_DATA;
break;
}
}
spin_unlock_irqrestore(&hw->rx_lock, flags);
/* handle completion...*/
if (comp_sts != BC_STS_NO_DATA) {
crystalhd_rx_pkt_done(hw, i, comp_sts);
comp_sts = BC_STS_NO_DATA;
}
}
if (list_avail) {
if (hw->stop_pending) {
if ((hw->rx_list_sts[0] == sts_free) &&
(hw->rx_list_sts[1] == sts_free))
crystalhd_hw_finalize_pause(hw);
} else {
crystalhd_hw_start_capture(hw);
}
}
}
static enum BC_STATUS crystalhd_fw_cmd_post_proc(struct crystalhd_hw *hw,
struct BC_FW_CMD *fw_cmd)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
struct dec_rsp_channel_start_video *st_rsp = NULL;
switch (fw_cmd->cmd[0]) {
case eCMD_C011_DEC_CHAN_START_VIDEO:
st_rsp = (struct dec_rsp_channel_start_video *)fw_cmd->rsp;
hw->pib_del_Q_addr = st_rsp->picInfoDeliveryQ;
hw->pib_rel_Q_addr = st_rsp->picInfoReleaseQ;
BCMLOG(BCMLOG_DBG, "DelQAddr:%x RelQAddr:%x\n",
hw->pib_del_Q_addr, hw->pib_rel_Q_addr);
break;
case eCMD_C011_INIT:
if (!(crystalhd_load_firmware_config(hw->adp))) {
BCMLOG_ERR("Invalid Params.\n");
sts = BC_STS_FW_AUTH_FAILED;
}
break;
default:
break;
}
return sts;
}
static enum BC_STATUS crystalhd_put_ddr2sleep(struct crystalhd_hw *hw)
{
uint32_t reg;
union link_misc_perst_decoder_ctrl rst_cntrl_reg;
/* Pulse reset pin of 7412 (MISC_PERST_DECODER_CTRL) */
rst_cntrl_reg.whole_reg = crystalhd_reg_rd(hw->adp,
MISC_PERST_DECODER_CTRL);
rst_cntrl_reg.bcm_7412_rst = 1;
crystalhd_reg_wr(hw->adp, MISC_PERST_DECODER_CTRL,
rst_cntrl_reg.whole_reg);
msleep_interruptible(50);
rst_cntrl_reg.bcm_7412_rst = 0;
crystalhd_reg_wr(hw->adp, MISC_PERST_DECODER_CTRL,
rst_cntrl_reg.whole_reg);
/* Close all banks, put DDR in idle */
bc_dec_reg_wr(hw->adp, SDRAM_PRECHARGE, 0);
/* Set bit 25 (drop CKE pin of DDR) */
reg = bc_dec_reg_rd(hw->adp, SDRAM_PARAM);
reg |= 0x02000000;
bc_dec_reg_wr(hw->adp, SDRAM_PARAM, reg);
/* Reset the audio block */
bc_dec_reg_wr(hw->adp, AUD_DSP_MISC_SOFT_RESET, 0x1);
/* Power down Raptor PLL */
reg = bc_dec_reg_rd(hw->adp, DecHt_PllCCtl);
reg |= 0x00008000;
bc_dec_reg_wr(hw->adp, DecHt_PllCCtl, reg);
/* Power down all Audio PLL */
bc_dec_reg_wr(hw->adp, AIO_MISC_PLL_RESET, 0x1);
/* Power down video clock (75MHz) */
reg = bc_dec_reg_rd(hw->adp, DecHt_PllECtl);
reg |= 0x00008000;
bc_dec_reg_wr(hw->adp, DecHt_PllECtl, reg);
/* Power down video clock (75MHz) */
reg = bc_dec_reg_rd(hw->adp, DecHt_PllDCtl);
reg |= 0x00008000;
bc_dec_reg_wr(hw->adp, DecHt_PllDCtl, reg);
/* Power down core clock (200MHz) */
reg = bc_dec_reg_rd(hw->adp, DecHt_PllACtl);
reg |= 0x00008000;
bc_dec_reg_wr(hw->adp, DecHt_PllACtl, reg);
/* Power down core clock (200MHz) */
reg = bc_dec_reg_rd(hw->adp, DecHt_PllBCtl);
reg |= 0x00008000;
bc_dec_reg_wr(hw->adp, DecHt_PllBCtl, reg);
return BC_STS_SUCCESS;
}
/************************************************
**
*************************************************/
enum BC_STATUS crystalhd_download_fw(struct crystalhd_adp *adp, void *buffer,
uint32_t sz)
{
uint32_t reg_data, cnt, *temp_buff;
uint32_t fw_sig_len = 36;
uint32_t dram_offset = BC_FWIMG_ST_ADDR, sig_reg;
if (!adp || !buffer || !sz) {
BCMLOG_ERR("Invalid Params.\n");
return BC_STS_INV_ARG;
}
reg_data = crystalhd_reg_rd(adp, OTP_CMD);
if (!(reg_data & 0x02)) {
BCMLOG_ERR("Invalid hw config.. otp not programmed\n");
return BC_STS_ERROR;
}
reg_data = 0;
crystalhd_reg_wr(adp, DCI_CMD, 0);
reg_data |= BC_BIT(0);
crystalhd_reg_wr(adp, DCI_CMD, reg_data);
reg_data = 0;
cnt = 1000;
msleep_interruptible(10);
while (reg_data != BC_BIT(4)) {
reg_data = crystalhd_reg_rd(adp, DCI_STATUS);
reg_data &= BC_BIT(4);
if (--cnt == 0) {
BCMLOG_ERR("Firmware Download RDY Timeout.\n");
return BC_STS_TIMEOUT;
}
}
msleep_interruptible(10);
/* Load the FW to the FW_ADDR field in the DCI_FIRMWARE_ADDR */
crystalhd_reg_wr(adp, DCI_FIRMWARE_ADDR, dram_offset);
temp_buff = (uint32_t *)buffer;
for (cnt = 0; cnt < (sz - fw_sig_len); cnt += 4) {
crystalhd_reg_wr(adp, DCI_DRAM_BASE_ADDR, (dram_offset >> 19));
crystalhd_reg_wr(adp, DCI_FIRMWARE_DATA, *temp_buff);
dram_offset += 4;
temp_buff++;
}
msleep_interruptible(10);
temp_buff++;
sig_reg = (uint32_t)DCI_SIGNATURE_DATA_7;
for (cnt = 0; cnt < 8; cnt++) {
uint32_t swapped_data = *temp_buff;
swapped_data = bswap_32_1(swapped_data);
crystalhd_reg_wr(adp, sig_reg, swapped_data);
sig_reg -= 4;
temp_buff++;
}
msleep_interruptible(10);
reg_data = 0;
reg_data |= BC_BIT(1);
crystalhd_reg_wr(adp, DCI_CMD, reg_data);
msleep_interruptible(10);
reg_data = 0;
reg_data = crystalhd_reg_rd(adp, DCI_STATUS);
if ((reg_data & BC_BIT(9)) == BC_BIT(9)) {
cnt = 1000;
while ((reg_data & BC_BIT(0)) != BC_BIT(0)) {
reg_data = crystalhd_reg_rd(adp, DCI_STATUS);
reg_data &= BC_BIT(0);
if (!(--cnt))
break;
msleep_interruptible(10);
}
reg_data = 0;
reg_data = crystalhd_reg_rd(adp, DCI_CMD);
reg_data |= BC_BIT(4);
crystalhd_reg_wr(adp, DCI_CMD, reg_data);
} else {
BCMLOG_ERR("F/w Signature mismatch\n");
return BC_STS_FW_AUTH_FAILED;
}
BCMLOG(BCMLOG_INFO, "Firmware Downloaded Successfully\n");
return BC_STS_SUCCESS;
}
enum BC_STATUS crystalhd_do_fw_cmd(struct crystalhd_hw *hw,
struct BC_FW_CMD *fw_cmd)
{
uint32_t cnt = 0, cmd_res_addr;
uint32_t *cmd_buff, *res_buff;
wait_queue_head_t fw_cmd_event;
int rc = 0;
enum BC_STATUS sts;
crystalhd_create_event(&fw_cmd_event);
if (!hw || !fw_cmd) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
cmd_buff = fw_cmd->cmd;
res_buff = fw_cmd->rsp;
if (!cmd_buff || !res_buff) {
BCMLOG_ERR("Invalid Parameters for F/W Command\n");
return BC_STS_INV_ARG;
}
hw->pwr_lock++;
hw->fwcmd_evt_sts = 0;
hw->pfw_cmd_event = &fw_cmd_event;
/*Write the command to the memory*/
crystalhd_mem_wr(hw->adp, TS_Host2CpuSnd, FW_CMD_BUFF_SZ, cmd_buff);
/*Memory Read for memory arbitrator flush*/
crystalhd_mem_rd(hw->adp, TS_Host2CpuSnd, 1, &cnt);
/* Write the command address to mailbox */
bc_dec_reg_wr(hw->adp, Hst2CpuMbx1, TS_Host2CpuSnd);
msleep_interruptible(50);
crystalhd_wait_on_event(&fw_cmd_event, hw->fwcmd_evt_sts, 20000, rc, 0);
if (!rc) {
sts = BC_STS_SUCCESS;
} else if (rc == -EBUSY) {
BCMLOG_ERR("Firmware command T/O\n");
sts = BC_STS_TIMEOUT;
} else if (rc == -EINTR) {
BCMLOG(BCMLOG_DBG, "FwCmd Wait Signal int.\n");
sts = BC_STS_IO_USER_ABORT;
} else {
BCMLOG_ERR("FwCmd IO Error.\n");
sts = BC_STS_IO_ERROR;
}
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("FwCmd Failed.\n");
hw->pwr_lock--;
return sts;
}
/*Get the Response Address*/
cmd_res_addr = bc_dec_reg_rd(hw->adp, Cpu2HstMbx1);
/*Read the Response*/
crystalhd_mem_rd(hw->adp, cmd_res_addr, FW_CMD_BUFF_SZ, res_buff);
hw->pwr_lock--;
if (res_buff[2] != C011_RET_SUCCESS) {
BCMLOG_ERR("res_buff[2] != C011_RET_SUCCESS\n");
return BC_STS_FW_CMD_ERR;
}
sts = crystalhd_fw_cmd_post_proc(hw, fw_cmd);
if (sts != BC_STS_SUCCESS)
BCMLOG_ERR("crystalhd_fw_cmd_post_proc Failed.\n");
return sts;
}
bool crystalhd_hw_interrupt(struct crystalhd_adp *adp, struct crystalhd_hw *hw)
{
uint32_t intr_sts = 0;
uint32_t deco_intr = 0;
bool rc = false;
if (!adp || !hw->dev_started)
return rc;
hw->stats.num_interrupts++;
hw->pwr_lock++;
deco_intr = bc_dec_reg_rd(adp, Stream2Host_Intr_Sts);
intr_sts = crystalhd_reg_rd(adp, INTR_INTR_STATUS);
if (intr_sts) {
/* let system know we processed interrupt..*/
rc = true;
hw->stats.dev_interrupts++;
}
if (deco_intr && (deco_intr != 0xdeaddead)) {
if (deco_intr & 0x80000000) {
/*Set the Event and the status flag*/
if (hw->pfw_cmd_event) {
hw->fwcmd_evt_sts = 1;
crystalhd_set_event(hw->pfw_cmd_event);
}
}
if (deco_intr & BC_BIT(1))
crystalhd_hw_proc_pib(hw);
bc_dec_reg_wr(adp, Stream2Host_Intr_Sts, deco_intr);
/* FIXME: jarod: No udelay? might this be
the real reason mini pci-e cards were stalling out? */
bc_dec_reg_wr(adp, Stream2Host_Intr_Sts, 0);
rc = true;
}
/* Rx interrupts */
crystalhd_rx_isr(hw, intr_sts);
/* Tx interrupts*/
crystalhd_tx_isr(hw, intr_sts);
/* Clear interrupts */
if (rc) {
if (intr_sts)
crystalhd_reg_wr(adp, INTR_INTR_CLR_REG, intr_sts);
crystalhd_reg_wr(adp, INTR_EOI_CTRL, 1);
}
hw->pwr_lock--;
return rc;
}
enum BC_STATUS crystalhd_hw_open(struct crystalhd_hw *hw,
struct crystalhd_adp *adp)
{
if (!hw || !adp) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
if (hw->dev_started)
return BC_STS_SUCCESS;
memset(hw, 0, sizeof(struct crystalhd_hw));
hw->adp = adp;
spin_lock_init(&hw->lock);
spin_lock_init(&hw->rx_lock);
/* FIXME: jarod: what are these magic numbers?!? */
hw->tx_ioq_tag_seed = 0x70023070;
hw->rx_pkt_tag_seed = 0x70029070;
hw->stop_pending = 0;
crystalhd_start_device(hw->adp);
hw->dev_started = true;
/* set initial core clock */
hw->core_clock_mhz = CLOCK_PRESET;
hw->prev_n = 0;
hw->pwr_lock = 0;
crystalhd_hw_set_core_clock(hw);
return BC_STS_SUCCESS;
}
enum BC_STATUS crystalhd_hw_close(struct crystalhd_hw *hw)
{
if (!hw) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
if (!hw->dev_started)
return BC_STS_SUCCESS;
/* Stop and DDR sleep will happen in here */
crystalhd_hw_suspend(hw);
hw->dev_started = false;
return BC_STS_SUCCESS;
}
enum BC_STATUS crystalhd_hw_setup_dma_rings(struct crystalhd_hw *hw)
{
unsigned int i;
void *mem;
size_t mem_len;
dma_addr_t phy_addr;
enum BC_STATUS sts = BC_STS_SUCCESS;
struct crystalhd_rx_dma_pkt *rpkt;
if (!hw || !hw->adp) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
sts = crystalhd_hw_create_ioqs(hw);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("Failed to create IOQs..\n");
return sts;
}
mem_len = BC_LINK_MAX_SGLS * sizeof(struct dma_descriptor);
for (i = 0; i < BC_TX_LIST_CNT; i++) {
mem = bc_kern_dma_alloc(hw->adp, mem_len, &phy_addr);
if (mem) {
memset(mem, 0, mem_len);
} else {
BCMLOG_ERR("Insufficient Memory For TX\n");
crystalhd_hw_free_dma_rings(hw);
return BC_STS_INSUFF_RES;
}
/* rx_pkt_pool -- static memory allocation */
hw->tx_pkt_pool[i].desc_mem.pdma_desc_start = mem;
hw->tx_pkt_pool[i].desc_mem.phy_addr = phy_addr;
hw->tx_pkt_pool[i].desc_mem.sz = BC_LINK_MAX_SGLS *
sizeof(struct dma_descriptor);
hw->tx_pkt_pool[i].list_tag = 0;
/* Add TX dma requests to Free Queue..*/
sts = crystalhd_dioq_add(hw->tx_freeq,
&hw->tx_pkt_pool[i], false, 0);
if (sts != BC_STS_SUCCESS) {
crystalhd_hw_free_dma_rings(hw);
return sts;
}
}
for (i = 0; i < BC_RX_LIST_CNT; i++) {
rpkt = kzalloc(sizeof(*rpkt), GFP_KERNEL);
if (!rpkt) {
BCMLOG_ERR("Insufficient Memory For RX\n");
crystalhd_hw_free_dma_rings(hw);
return BC_STS_INSUFF_RES;
}
mem = bc_kern_dma_alloc(hw->adp, mem_len, &phy_addr);
if (mem) {
memset(mem, 0, mem_len);
} else {
BCMLOG_ERR("Insufficient Memory For RX\n");
crystalhd_hw_free_dma_rings(hw);
kfree(rpkt);
return BC_STS_INSUFF_RES;
}
rpkt->desc_mem.pdma_desc_start = mem;
rpkt->desc_mem.phy_addr = phy_addr;
rpkt->desc_mem.sz = BC_LINK_MAX_SGLS *
sizeof(struct dma_descriptor);
rpkt->pkt_tag = hw->rx_pkt_tag_seed + i;
crystalhd_hw_free_rx_pkt(hw, rpkt);
}
return BC_STS_SUCCESS;
}
enum BC_STATUS crystalhd_hw_free_dma_rings(struct crystalhd_hw *hw)
{
unsigned int i;
struct crystalhd_rx_dma_pkt *rpkt = NULL;
if (!hw || !hw->adp) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
/* Delete all IOQs.. */
crystalhd_hw_delete_ioqs(hw);
for (i = 0; i < BC_TX_LIST_CNT; i++) {
if (hw->tx_pkt_pool[i].desc_mem.pdma_desc_start) {
bc_kern_dma_free(hw->adp,
hw->tx_pkt_pool[i].desc_mem.sz,
hw->tx_pkt_pool[i].desc_mem.pdma_desc_start,
hw->tx_pkt_pool[i].desc_mem.phy_addr);
hw->tx_pkt_pool[i].desc_mem.pdma_desc_start = NULL;
}
}
BCMLOG(BCMLOG_DBG, "Releasing RX Pkt pool\n");
do {
rpkt = crystalhd_hw_alloc_rx_pkt(hw);
if (!rpkt)
break;
bc_kern_dma_free(hw->adp, rpkt->desc_mem.sz,
rpkt->desc_mem.pdma_desc_start,
rpkt->desc_mem.phy_addr);
kfree(rpkt);
} while (rpkt);
return BC_STS_SUCCESS;
}
enum BC_STATUS crystalhd_hw_post_tx(struct crystalhd_hw *hw,
struct crystalhd_dio_req *ioreq,
hw_comp_callback call_back,
wait_queue_head_t *cb_event, uint32_t *list_id,
uint8_t data_flags)
{
struct tx_dma_pkt *tx_dma_packet = NULL;
uint32_t first_desc_u_addr, first_desc_l_addr;
uint32_t low_addr, high_addr;
union addr_64 desc_addr;
enum BC_STATUS sts, add_sts;
uint32_t dummy_index = 0;
unsigned long flags;
bool rc;
if (!hw || !ioreq || !call_back || !cb_event || !list_id) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
/*
* Since we hit code in busy condition very frequently,
* we will check the code in status first before
* checking the availability of free elem.
*
* This will avoid the Q fetch/add in normal condition.
*/
rc = crystalhd_code_in_full(hw->adp, ioreq->uinfo.xfr_len,
false, data_flags);
if (rc) {
hw->stats.cin_busy++;
return BC_STS_BUSY;
}
/* Get a list from TxFreeQ */
tx_dma_packet = (struct tx_dma_pkt *)crystalhd_dioq_fetch(
hw->tx_freeq);
if (!tx_dma_packet) {
BCMLOG_ERR("No empty elements..\n");
return BC_STS_ERR_USAGE;
}
sts = crystalhd_xlat_sgl_to_dma_desc(ioreq,
&tx_dma_packet->desc_mem,
&dummy_index);
if (sts != BC_STS_SUCCESS) {
add_sts = crystalhd_dioq_add(hw->tx_freeq, tx_dma_packet,
false, 0);
if (add_sts != BC_STS_SUCCESS)
BCMLOG_ERR("double fault..\n");
return sts;
}
hw->pwr_lock++;
desc_addr.full_addr = tx_dma_packet->desc_mem.phy_addr;
low_addr = desc_addr.low_part;
high_addr = desc_addr.high_part;
tx_dma_packet->call_back = call_back;
tx_dma_packet->cb_event = cb_event;
tx_dma_packet->dio_req = ioreq;
spin_lock_irqsave(&hw->lock, flags);
if (hw->tx_list_post_index == 0) {
first_desc_u_addr = MISC1_TX_FIRST_DESC_U_ADDR_LIST0;
first_desc_l_addr = MISC1_TX_FIRST_DESC_L_ADDR_LIST0;
} else {
first_desc_u_addr = MISC1_TX_FIRST_DESC_U_ADDR_LIST1;
first_desc_l_addr = MISC1_TX_FIRST_DESC_L_ADDR_LIST1;
}
*list_id = tx_dma_packet->list_tag = hw->tx_ioq_tag_seed +
hw->tx_list_post_index;
hw->tx_list_post_index = (hw->tx_list_post_index + 1) % DMA_ENGINE_CNT;
spin_unlock_irqrestore(&hw->lock, flags);
/* Insert in Active Q..*/
crystalhd_dioq_add(hw->tx_actq, tx_dma_packet, false,
tx_dma_packet->list_tag);
/*
* Interrupt will come as soon as you write
* the valid bit. So be ready for that. All
* the initialization should happen before that.
*/
crystalhd_start_tx_dma_engine(hw);
crystalhd_reg_wr(hw->adp, first_desc_u_addr, desc_addr.high_part);
crystalhd_reg_wr(hw->adp, first_desc_l_addr, desc_addr.low_part |
0x01);
/* Be sure we set the valid bit ^^^^ */
return BC_STS_SUCCESS;
}
/*
* This is a force cancel and we are racing with ISR.
*
* Will try to remove the req from ActQ before ISR gets it.
* If ISR gets it first then the completion happens in the
* normal path and we will return _STS_NO_DATA from here.
*
* FIX_ME: Not Tested the actual condition..
*/
enum BC_STATUS crystalhd_hw_cancel_tx(struct crystalhd_hw *hw,
uint32_t list_id)
{
if (!hw || !list_id) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
crystalhd_stop_tx_dma_engine(hw);
crystalhd_hw_tx_req_complete(hw, list_id, BC_STS_IO_USER_ABORT);
return BC_STS_SUCCESS;
}
enum BC_STATUS crystalhd_hw_add_cap_buffer(struct crystalhd_hw *hw,
struct crystalhd_dio_req *ioreq, bool en_post)
{
struct crystalhd_rx_dma_pkt *rpkt;
uint32_t tag, uv_desc_ix = 0;
enum BC_STATUS sts;
if (!hw || !ioreq) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
rpkt = crystalhd_hw_alloc_rx_pkt(hw);
if (!rpkt) {
BCMLOG_ERR("Insufficient resources\n");
return BC_STS_INSUFF_RES;
}
rpkt->dio_req = ioreq;
tag = rpkt->pkt_tag;
sts = crystalhd_xlat_sgl_to_dma_desc(ioreq, &rpkt->desc_mem,
&uv_desc_ix);
if (sts != BC_STS_SUCCESS)
return sts;
rpkt->uv_phy_addr = 0;
/* Store the address of UV in the rx packet for post*/
if (uv_desc_ix)
rpkt->uv_phy_addr = rpkt->desc_mem.phy_addr +
(sizeof(struct dma_descriptor) * (uv_desc_ix + 1));
if (en_post)
sts = crystalhd_hw_post_cap_buff(hw, rpkt);
else
sts = crystalhd_dioq_add(hw->rx_freeq, rpkt, false, tag);
return sts;
}
enum BC_STATUS crystalhd_hw_get_cap_buffer(struct crystalhd_hw *hw,
struct BC_PIC_INFO_BLOCK *pib,
struct crystalhd_dio_req **ioreq)
{
struct crystalhd_rx_dma_pkt *rpkt;
uint32_t timeout = BC_PROC_OUTPUT_TIMEOUT / 1000;
uint32_t sig_pending = 0;
if (!hw || !ioreq || !pib) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
rpkt = crystalhd_dioq_fetch_wait(hw->rx_rdyq, timeout, &sig_pending);
if (!rpkt) {
if (sig_pending) {
BCMLOG(BCMLOG_INFO, "wait on frame time out %d\n",
sig_pending);
return BC_STS_IO_USER_ABORT;
} else {
return BC_STS_TIMEOUT;
}
}
rpkt->dio_req->uinfo.comp_flags = rpkt->flags;
if (rpkt->flags & COMP_FLAG_PIB_VALID)
memcpy(pib, &rpkt->pib, sizeof(*pib));
*ioreq = rpkt->dio_req;
crystalhd_hw_free_rx_pkt(hw, rpkt);
return BC_STS_SUCCESS;
}
enum BC_STATUS crystalhd_hw_start_capture(struct crystalhd_hw *hw)
{
struct crystalhd_rx_dma_pkt *rx_pkt;
enum BC_STATUS sts;
uint32_t i;
if (!hw) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
/* This is start of capture.. Post to both the lists.. */
for (i = 0; i < DMA_ENGINE_CNT; i++) {
rx_pkt = crystalhd_dioq_fetch(hw->rx_freeq);
if (!rx_pkt)
return BC_STS_NO_DATA;
sts = crystalhd_hw_post_cap_buff(hw, rx_pkt);
if (BC_STS_SUCCESS != sts)
break;
}
return BC_STS_SUCCESS;
}
enum BC_STATUS crystalhd_hw_stop_capture(struct crystalhd_hw *hw)
{
void *temp = NULL;
if (!hw) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
crystalhd_stop_rx_dma_engine(hw);
do {
temp = crystalhd_dioq_fetch(hw->rx_freeq);
if (temp)
crystalhd_rx_pkt_rel_call_back(hw, temp);
} while (temp);
return BC_STS_SUCCESS;
}
enum BC_STATUS crystalhd_hw_pause(struct crystalhd_hw *hw)
{
hw->stats.pause_cnt++;
hw->stop_pending = 1;
if ((hw->rx_list_sts[0] == sts_free) &&
(hw->rx_list_sts[1] == sts_free))
crystalhd_hw_finalize_pause(hw);
return BC_STS_SUCCESS;
}
enum BC_STATUS crystalhd_hw_unpause(struct crystalhd_hw *hw)
{
enum BC_STATUS sts;
uint32_t aspm;
hw->stop_pending = 0;
aspm = crystalhd_reg_rd(hw->adp, PCIE_DLL_DATA_LINK_CONTROL);
aspm &= ~ASPM_L1_ENABLE;
/* NAREN BCMLOG(BCMLOG_INFO, "aspm off\n"); */
crystalhd_reg_wr(hw->adp, PCIE_DLL_DATA_LINK_CONTROL, aspm);
sts = crystalhd_hw_start_capture(hw);
return sts;
}
enum BC_STATUS crystalhd_hw_suspend(struct crystalhd_hw *hw)
{
enum BC_STATUS sts;
if (!hw) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
sts = crystalhd_put_ddr2sleep(hw);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("Failed to Put DDR To Sleep!!\n");
return BC_STS_ERROR;
}
if (!crystalhd_stop_device(hw->adp)) {
BCMLOG_ERR("Failed to Stop Device!!\n");
return BC_STS_ERROR;
}
return BC_STS_SUCCESS;
}
void crystalhd_hw_stats(struct crystalhd_hw *hw,
struct crystalhd_hw_stats *stats)
{
if (!hw) {
BCMLOG_ERR("Invalid Arguments\n");
return;
}
/* if called w/NULL stats, its a req to zero out the stats */
if (!stats) {
memset(&hw->stats, 0, sizeof(hw->stats));
return;
}
hw->stats.freeq_count = crystalhd_dioq_count(hw->rx_freeq);
hw->stats.rdyq_count = crystalhd_dioq_count(hw->rx_rdyq);
memcpy(stats, &hw->stats, sizeof(*stats));
}
enum BC_STATUS crystalhd_hw_set_core_clock(struct crystalhd_hw *hw)
{
uint32_t reg, n, i;
uint32_t vco_mg, refresh_reg;
if (!hw) {
BCMLOG_ERR("Invalid Arguments\n");
return BC_STS_INV_ARG;
}
/* FIXME: jarod: wha? */
/*n = (hw->core_clock_mhz * 3) / 20 + 1; */
n = hw->core_clock_mhz/5;
if (n == hw->prev_n)
return BC_STS_CLK_NOCHG;
if (hw->pwr_lock > 0) {
/* BCMLOG(BCMLOG_INFO,"pwr_lock is %u\n", hw->pwr_lock) */
return BC_STS_CLK_NOCHG;
}
i = n * 27;
if (i < 560)
vco_mg = 0;
else if (i < 900)
vco_mg = 1;
else if (i < 1030)
vco_mg = 2;
else
vco_mg = 3;
reg = bc_dec_reg_rd(hw->adp, DecHt_PllACtl);
reg &= 0xFFFFCFC0;
reg |= n;
reg |= vco_mg << 12;
BCMLOG(BCMLOG_INFO, "clock is moving to %d with n %d with vco_mg %d\n",
hw->core_clock_mhz, n, vco_mg);
/* Change the DRAM refresh rate to accommodate the new frequency */
/* refresh reg = ((refresh_rate * clock_rate)/16) - 1; rounding up*/
refresh_reg = (7 * hw->core_clock_mhz / 16);
bc_dec_reg_wr(hw->adp, SDRAM_REF_PARAM, ((1 << 12) | refresh_reg));
bc_dec_reg_wr(hw->adp, DecHt_PllACtl, reg);
i = 0;
for (i = 0; i < 10; i++) {
reg = bc_dec_reg_rd(hw->adp, DecHt_PllACtl);
if (reg & 0x00020000) {
hw->prev_n = n;
/* FIXME: jarod: outputting
a random "C" is... confusing... */
BCMLOG(BCMLOG_INFO, "C");
return BC_STS_SUCCESS;
} else {
msleep_interruptible(10);
}
}
BCMLOG(BCMLOG_INFO, "clk change failed\n");
return BC_STS_CLK_NOCHG;
}
drivers/staging/crystalhd/crystalhd_hw.h deleted 100644 → 0
View file @ 895ae876
/***************************************************************************
* Copyright (c) 2005-2009, Broadcom Corporation.
*
* Name: crystalhd_hw . h
*
* Description:
* BCM70012 Linux driver hardware layer.
*
* HISTORY:
*
**********************************************************************
* This file is part of the crystalhd device driver.
*
* This driver 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, version 2 of the License.
*
* This driver is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this driver. If not, see <http://www.gnu.org/licenses/>.
**********************************************************************/
#ifndef _CRYSTALHD_HW_H_
#define _CRYSTALHD_HW_H_
#include "crystalhd.h"
/* HW constants..*/
#define DMA_ENGINE_CNT 2
#define MAX_PIB_Q_DEPTH 64
#define MIN_PIB_Q_DEPTH 2
#define WR_POINTER_OFF 4
#define ASPM_L1_ENABLE (BC_BIT(27))
/*************************************************
7412 Decoder Registers.
**************************************************/
#define FW_CMD_BUFF_SZ 64
#define TS_Host2CpuSnd 0x00000100
#define Hst2CpuMbx1 0x00100F00
#define Cpu2HstMbx1 0x00100F04
#define MbxStat1 0x00100F08
#define Stream2Host_Intr_Sts 0x00100F24
#define C011_RET_SUCCESS 0x0 /* Return status of firmware command. */
/* TS input status register */
#define TS_StreamAFIFOStatus 0x0010044C
#define TS_StreamBFIFOStatus 0x0010084C
/*UART Selection definitions*/
#define UartSelectA 0x00100300
#define UartSelectB 0x00100304
#define BSVS_UART_DEC_NONE 0x00
#define BSVS_UART_DEC_OUTER 0x01
#define BSVS_UART_DEC_INNER 0x02
#define BSVS_UART_STREAM 0x03
/* Code-In fifo */
#define REG_DecCA_RegCinCTL 0xa00
#define REG_DecCA_RegCinBase 0xa0c
#define REG_DecCA_RegCinEnd 0xa10
#define REG_DecCA_RegCinWrPtr 0xa04
#define REG_DecCA_RegCinRdPtr 0xa08
#define REG_Dec_TsUser0Base 0x100864
#define REG_Dec_TsUser0Rdptr 0x100868
#define REG_Dec_TsUser0Wrptr 0x10086C
#define REG_Dec_TsUser0End 0x100874
/* ASF Case ...*/
#define REG_Dec_TsAudCDB2Base 0x10036c
#define REG_Dec_TsAudCDB2Rdptr 0x100378
#define REG_Dec_TsAudCDB2Wrptr 0x100374
#define REG_Dec_TsAudCDB2End 0x100370
/* DRAM bringup Registers */
#define SDRAM_PARAM 0x00040804
#define SDRAM_PRECHARGE 0x000408B0
#define SDRAM_EXT_MODE 0x000408A4
#define SDRAM_MODE 0x000408A0
#define SDRAM_REFRESH 0x00040890
#define SDRAM_REF_PARAM 0x00040808
#define DecHt_PllACtl 0x34000C
#define DecHt_PllBCtl 0x340010
#define DecHt_PllCCtl 0x340014
#define DecHt_PllDCtl 0x340034
#define DecHt_PllECtl 0x340038
#define AUD_DSP_MISC_SOFT_RESET 0x00240104
#define AIO_MISC_PLL_RESET 0x0026000C
#define PCIE_CLK_REQ_REG 0xDC
#define PCI_CLK_REQ_ENABLE (BC_BIT(8))
/*************************************************
F/W Copy engine definitions..
**************************************************/
#define BC_FWIMG_ST_ADDR 0x00000000
/* FIXME: jarod: there's a kernel function that'll do this for us... */
#define rotr32_1(x, n) (((x) >> n) | ((x) << (32 - n)))
#define bswap_32_1(x) ((rotr32_1((x), 24) & 0x00ff00ff) | (rotr32_1((x), 8) & 0xff00ff00))
#define DecHt_HostSwReset 0x340000
#define BC_DRAM_FW_CFG_ADDR 0x001c2000
union addr_64 {
struct {
uint32_t low_part;
uint32_t high_part;
};
uint64_t full_addr;
};
union intr_mask_reg {
struct {
uint32_t mask_tx_done:1;
uint32_t mask_tx_err:1;
uint32_t mask_rx_done:1;
uint32_t mask_rx_err:1;
uint32_t mask_pcie_err:1;
uint32_t mask_pcie_rbusmast_err:1;
uint32_t mask_pcie_rgr_bridge:1;
uint32_t reserved:25;
};
uint32_t whole_reg;
};
union link_misc_perst_deco_ctrl {
struct {
uint32_t bcm7412_rst:1; /* 1 -> BCM7412 is held
in reset. Reset value 1.*/
uint32_t reserved0:3; /* Reserved.No Effect*/
uint32_t stop_bcm_7412_clk:1; /* 1 ->Stops branch of
27MHz clk used to clk BCM7412*/
uint32_t reserved1:27; /* Reserved. No Effect*/
};
uint32_t whole_reg;
};
union link_misc_perst_clk_ctrl {
struct {
uint32_t sel_alt_clk:1; /* When set, selects a
6.75MHz clock as the source of core_clk */
uint32_t stop_core_clk:1; /* When set, stops the branch
of core_clk that is not needed for low power operation */
uint32_t pll_pwr_dn:1; /* When set, powers down the
main PLL. The alternate clock bit should be set to
select an alternate clock before setting this bit.*/
uint32_t reserved0:5; /* Reserved */
uint32_t pll_mult:8; /* This setting controls
the multiplier for the PLL. */
uint32_t pll_div:4; /* This setting controls
the divider for the PLL. */
uint32_t reserved1:12; /* Reserved */
};
uint32_t whole_reg;
};
union link_misc_perst_decoder_ctrl {
struct {
uint32_t bcm_7412_rst:1; /* 1 -> BCM7412 is held
in reset. Reset value 1.*/
uint32_t res0:3; /* Reserved.No Effect*/
uint32_t stop_7412_clk:1; /* 1 ->Stops branch of 27MHz
clk used to clk BCM7412*/
uint32_t res1:27; /* Reserved. No Effect */
};
uint32_t whole_reg;
};
union desc_low_addr_reg {
struct {
uint32_t list_valid:1;
uint32_t reserved:4;
uint32_t low_addr:27;
};
uint32_t whole_reg;
};
struct dma_descriptor { /* 8 32-bit values */
/* 0th u32 */
uint32_t sdram_buff_addr:28; /* bits 0-27: SDRAM Address */
uint32_t res0:4; /* bits 28-31: Reserved */
/* 1st u32 */
uint32_t buff_addr_low; /* 1 buffer address low */
uint32_t buff_addr_high; /* 2 buffer address high */
/* 3rd u32 */
uint32_t res2:2; /* 0-1 - Reserved */
uint32_t xfer_size:23; /* 2-24 = Xfer size in words */
uint32_t res3:6; /* 25-30 reserved */
uint32_t intr_enable:1; /* 31 - Interrupt After this desc */
/* 4th u32 */
uint32_t endian_xlat_align:2; /* 0-1 Endian Translation */
uint32_t next_desc_cont:1; /* 2 - Next desc is in contig memory */
uint32_t res4:25; /* 3 - 27 Reserved bits */
uint32_t fill_bytes:2; /* 28-29 Bits Fill Bytes */
uint32_t dma_dir:1; /* 30 bit DMA Direction */
uint32_t last_rec_indicator:1; /* 31 bit Last Record Indicator */
/* 5th u32 */
uint32_t next_desc_addr_low; /* 32-bits Next Desc Addr lower */
/* 6th u32 */
uint32_t next_desc_addr_high; /* 32-bits Next Desc Addr Higher */
/* 7th u32 */
uint32_t res8; /* Last 32bits reserved */
};
/*
* We will allocate the memory in 4K pages
* the linked list will be a list of 32 byte descriptors.
* The virtual address will determine what should be freed.
*/
struct dma_desc_mem {
struct dma_descriptor *pdma_desc_start; /* 32-bytes for dma
descriptor. should be first element */
dma_addr_t phy_addr; /* physical address
of each DMA desc */
uint32_t sz;
struct _dma_desc_mem_ *Next; /* points to Next Descriptor in chain */
};
enum list_sts {
sts_free = 0,
/* RX-Y Bits 0:7 */
rx_waiting_y_intr = 0x00000001,
rx_y_error = 0x00000004,
/* RX-UV Bits 8:16 */
rx_waiting_uv_intr = 0x0000100,
rx_uv_error = 0x0000400,
rx_sts_waiting = (rx_waiting_y_intr|rx_waiting_uv_intr),
rx_sts_error = (rx_y_error|rx_uv_error),
rx_y_mask = 0x000000FF,
rx_uv_mask = 0x0000FF00,
};
struct tx_dma_pkt {
struct dma_desc_mem desc_mem;
hw_comp_callback call_back;
struct crystalhd_dio_req *dio_req;
wait_queue_head_t *cb_event;
uint32_t list_tag;
};
struct crystalhd_rx_dma_pkt {
struct dma_desc_mem desc_mem;
struct crystalhd_dio_req *dio_req;
uint32_t pkt_tag;
uint32_t flags;
struct BC_PIC_INFO_BLOCK pib;
dma_addr_t uv_phy_addr;
struct crystalhd_rx_dma_pkt *next;
};
struct crystalhd_hw_stats {
uint32_t rx_errors;
uint32_t tx_errors;
uint32_t freeq_count;
uint32_t rdyq_count;
uint32_t num_interrupts;
uint32_t dev_interrupts;
uint32_t cin_busy;
uint32_t pause_cnt;
};
struct crystalhd_hw {
struct tx_dma_pkt tx_pkt_pool[DMA_ENGINE_CNT];
spinlock_t lock;
uint32_t tx_ioq_tag_seed;
uint32_t tx_list_post_index;
struct crystalhd_rx_dma_pkt *rx_pkt_pool_head;
uint32_t rx_pkt_tag_seed;
bool dev_started;
void *adp;
wait_queue_head_t *pfw_cmd_event;
int fwcmd_evt_sts;
uint32_t pib_del_Q_addr;
uint32_t pib_rel_Q_addr;
struct crystalhd_dioq *tx_freeq;
struct crystalhd_dioq *tx_actq;
/* Rx DMA Engine Specific Locks */
spinlock_t rx_lock;
uint32_t rx_list_post_index;
enum list_sts rx_list_sts[DMA_ENGINE_CNT];
struct crystalhd_dioq *rx_rdyq;
struct crystalhd_dioq *rx_freeq;
struct crystalhd_dioq *rx_actq;
uint32_t stop_pending;
/* HW counters.. */
struct crystalhd_hw_stats stats;
/* Core clock in MHz */
uint32_t core_clock_mhz;
uint32_t prev_n;
uint32_t pwr_lock;
};
/* Clock defines for power control */
#define CLOCK_PRESET 175
/* DMA engine register BIT mask wrappers.. */
#define DMA_START_BIT MISC1_TX_SW_DESC_LIST_CTRL_STS_TX_DMA_RUN_STOP_MASK
#define GET_RX_INTR_MASK (INTR_INTR_STATUS_L1_UV_RX_DMA_ERR_INTR_MASK | \
INTR_INTR_STATUS_L1_UV_RX_DMA_DONE_INTR_MASK | \
INTR_INTR_STATUS_L1_Y_RX_DMA_ERR_INTR_MASK | \
INTR_INTR_STATUS_L1_Y_RX_DMA_DONE_INTR_MASK | \
INTR_INTR_STATUS_L0_UV_RX_DMA_ERR_INTR_MASK | \
INTR_INTR_STATUS_L0_UV_RX_DMA_DONE_INTR_MASK | \
INTR_INTR_STATUS_L0_Y_RX_DMA_ERR_INTR_MASK | \
INTR_INTR_STATUS_L0_Y_RX_DMA_DONE_INTR_MASK)
#define GET_Y0_ERR_MSK (MISC1_Y_RX_ERROR_STATUS_RX_L0_OVERRUN_ERROR_MASK | \
MISC1_Y_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_MASK | \
MISC1_Y_RX_ERROR_STATUS_RX_L0_DESC_TX_ABORT_ERRORS_MASK | \
MISC1_Y_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_MASK)
#define GET_UV0_ERR_MSK (MISC1_UV_RX_ERROR_STATUS_RX_L0_OVERRUN_ERROR_MASK | \
MISC1_UV_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_MASK | \
MISC1_UV_RX_ERROR_STATUS_RX_L0_DESC_TX_ABORT_ERRORS_MASK | \
MISC1_UV_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_MASK)
#define GET_Y1_ERR_MSK (MISC1_Y_RX_ERROR_STATUS_RX_L1_OVERRUN_ERROR_MASK | \
MISC1_Y_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_MASK | \
MISC1_Y_RX_ERROR_STATUS_RX_L1_DESC_TX_ABORT_ERRORS_MASK | \
MISC1_Y_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_MASK)
#define GET_UV1_ERR_MSK (MISC1_UV_RX_ERROR_STATUS_RX_L1_OVERRUN_ERROR_MASK | \
MISC1_UV_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_MASK | \
MISC1_UV_RX_ERROR_STATUS_RX_L1_DESC_TX_ABORT_ERRORS_MASK | \
MISC1_UV_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_MASK)
/**** API Exposed to the other layers ****/
enum BC_STATUS crystalhd_download_fw(struct crystalhd_adp *adp,
void *buffer, uint32_t sz);
enum BC_STATUS crystalhd_do_fw_cmd(struct crystalhd_hw *hw,
struct BC_FW_CMD *fw_cmd);
bool crystalhd_hw_interrupt(struct crystalhd_adp *adp,
struct crystalhd_hw *hw);
enum BC_STATUS crystalhd_hw_open(struct crystalhd_hw *,
struct crystalhd_adp *);
enum BC_STATUS crystalhd_hw_close(struct crystalhd_hw *);
enum BC_STATUS crystalhd_hw_setup_dma_rings(struct crystalhd_hw *);
enum BC_STATUS crystalhd_hw_free_dma_rings(struct crystalhd_hw *);
enum BC_STATUS crystalhd_hw_post_tx(struct crystalhd_hw *hw,
struct crystalhd_dio_req *ioreq,
hw_comp_callback call_back,
wait_queue_head_t *cb_event,
uint32_t *list_id, uint8_t data_flags);
enum BC_STATUS crystalhd_hw_pause(struct crystalhd_hw *hw);
enum BC_STATUS crystalhd_hw_unpause(struct crystalhd_hw *hw);
enum BC_STATUS crystalhd_hw_suspend(struct crystalhd_hw *hw);
enum BC_STATUS crystalhd_hw_cancel_tx(struct crystalhd_hw *hw,
uint32_t list_id);
enum BC_STATUS crystalhd_hw_add_cap_buffer(struct crystalhd_hw *hw,
struct crystalhd_dio_req *ioreq, bool en_post);
enum BC_STATUS crystalhd_hw_get_cap_buffer(struct crystalhd_hw *hw,
struct BC_PIC_INFO_BLOCK *pib,
struct crystalhd_dio_req **ioreq);
enum BC_STATUS crystalhd_hw_stop_capture(struct crystalhd_hw *hw);
enum BC_STATUS crystalhd_hw_start_capture(struct crystalhd_hw *hw);
void crystalhd_hw_stats(struct crystalhd_hw *hw,
struct crystalhd_hw_stats *stats);
/* API to program the core clock on the decoder */
enum BC_STATUS crystalhd_hw_set_core_clock(struct crystalhd_hw *);
#endif
drivers/staging/crystalhd/crystalhd_lnx.c deleted 100644 → 0
View file @ 895ae876
/***************************************************************************
BCM70010 Linux driver
Copyright (c) 2005-2009, Broadcom Corporation.
This driver 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, version 2 of the License.
This driver is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this driver. If not, see <http://www.gnu.org/licenses/>.
***************************************************************************/
#include "crystalhd.h"
#include <linux/mutex.h>
#include <linux/slab.h>
static DEFINE_MUTEX(chd_dec_mutex);
static struct class *crystalhd_class;
static struct crystalhd_adp *g_adp_info;
static irqreturn_t chd_dec_isr(int irq, void *arg)
{
struct crystalhd_adp *adp = arg;
int rc = 0;
if (adp)
rc = crystalhd_cmd_interrupt(&adp->cmds);
return IRQ_RETVAL(rc);
}
static int chd_dec_enable_int(struct crystalhd_adp *adp)
{
int rc = 0;
if (!adp || !adp->pdev) {
BCMLOG_ERR("Invalid arg!!\n");
return -EINVAL;
}
if (adp->pdev->msi_enabled)
adp->msi = 1;
else
adp->msi = pci_enable_msi(adp->pdev);
rc = request_irq(adp->pdev->irq, chd_dec_isr, IRQF_SHARED,
adp->name, (void *)adp);
if (rc) {
BCMLOG_ERR("Interrupt request failed..\n");
pci_disable_msi(adp->pdev);
}
return rc;
}
static int chd_dec_disable_int(struct crystalhd_adp *adp)
{
if (!adp || !adp->pdev) {
BCMLOG_ERR("Invalid arg!!\n");
return -EINVAL;
}
free_irq(adp->pdev->irq, adp);
if (adp->msi)
pci_disable_msi(adp->pdev);
return 0;
}
static struct
crystalhd_ioctl_data *chd_dec_alloc_iodata(struct crystalhd_adp *adp,
bool isr)
{
unsigned long flags = 0;
struct crystalhd_ioctl_data *temp;
if (!adp)
return NULL;
spin_lock_irqsave(&adp->lock, flags);
temp = adp->idata_free_head;
if (temp) {
adp->idata_free_head = adp->idata_free_head->next;
memset(temp, 0, sizeof(*temp));
}
spin_unlock_irqrestore(&adp->lock, flags);
return temp;
}
static void chd_dec_free_iodata(struct crystalhd_adp *adp,
struct crystalhd_ioctl_data *iodata, bool isr)
{
unsigned long flags = 0;
if (!adp || !iodata)
return;
spin_lock_irqsave(&adp->lock, flags);
iodata->next = adp->idata_free_head;
adp->idata_free_head = iodata;
spin_unlock_irqrestore(&adp->lock, flags);
}
static inline int crystalhd_user_data(void __user *ud, void *dr,
int size, int set)
{
int rc;
if (!ud || !dr) {
BCMLOG_ERR("Invalid arg\n");
return -EINVAL;
}
if (set)
rc = copy_to_user(ud, dr, size);
else
rc = copy_from_user(dr, ud, size);
if (rc) {
BCMLOG_ERR("Invalid args for command\n");
rc = -EFAULT;
}
return rc;
}
static int chd_dec_fetch_cdata(struct crystalhd_adp *adp,
struct crystalhd_ioctl_data *io, uint32_t m_sz,
unsigned long ua)
{
unsigned long ua_off;
int rc = 0;
if (!adp || !io || !ua || !m_sz) {
BCMLOG_ERR("Invalid Arg!!\n");
return -EINVAL;
}
io->add_cdata = vmalloc(m_sz);
if (!io->add_cdata) {
BCMLOG_ERR("kalloc fail for sz:%x\n", m_sz);
return -ENOMEM;
}
io->add_cdata_sz = m_sz;
ua_off = ua + sizeof(io->udata);
rc = crystalhd_user_data((void __user *)ua_off, io->add_cdata,
io->add_cdata_sz, 0);
if (rc) {
BCMLOG_ERR("failed to pull add_cdata sz:%x ua_off:%x\n",
io->add_cdata_sz, (unsigned int)ua_off);
vfree(io->add_cdata);
io->add_cdata = NULL;
return -ENODATA;
}
return rc;
}
static int chd_dec_release_cdata(struct crystalhd_adp *adp,
struct crystalhd_ioctl_data *io,
unsigned long ua)
{
unsigned long ua_off;
int rc;
if (!adp || !io || !ua) {
BCMLOG_ERR("Invalid Arg!!\n");
return -EINVAL;
}
if (io->cmd != BCM_IOC_FW_DOWNLOAD) {
ua_off = ua + sizeof(io->udata);
rc = crystalhd_user_data((void __user *)ua_off, io->add_cdata,
io->add_cdata_sz, 1);
if (rc) {
BCMLOG_ERR(
"failed to push add_cdata sz:%x ua_off:%x\n",
io->add_cdata_sz, (unsigned int)ua_off);
return -ENODATA;
}
}
if (io->add_cdata) {
vfree(io->add_cdata);
io->add_cdata = NULL;
}
return 0;
}
static int chd_dec_proc_user_data(struct crystalhd_adp *adp,
struct crystalhd_ioctl_data *io,
unsigned long ua, int set)
{
int rc;
uint32_t m_sz = 0;
if (!adp || !io || !ua) {
BCMLOG_ERR("Invalid Arg!!\n");
return -EINVAL;
}
rc = crystalhd_user_data((void __user *)ua, &io->udata,
sizeof(io->udata), set);
if (rc) {
BCMLOG_ERR("failed to %s iodata\n", (set ? "set" : "get"));
return rc;
}
switch (io->cmd) {
case BCM_IOC_MEM_RD:
case BCM_IOC_MEM_WR:
case BCM_IOC_FW_DOWNLOAD:
m_sz = io->udata.u.devMem.NumDwords * 4;
if (set)
rc = chd_dec_release_cdata(adp, io, ua);
else
rc = chd_dec_fetch_cdata(adp, io, m_sz, ua);
break;
default:
break;
}
return rc;
}
static int chd_dec_api_cmd(struct crystalhd_adp *adp, unsigned long ua,
uint32_t uid, uint32_t cmd, crystalhd_cmd_proc func)
{
int rc;
struct crystalhd_ioctl_data *temp;
enum BC_STATUS sts = BC_STS_SUCCESS;
temp = chd_dec_alloc_iodata(adp, 0);
if (!temp) {
BCMLOG_ERR("Failed to get iodata..\n");
return -EINVAL;
}
temp->u_id = uid;
temp->cmd = cmd;
rc = chd_dec_proc_user_data(adp, temp, ua, 0);
if (!rc) {
sts = func(&adp->cmds, temp);
if (sts == BC_STS_PENDING)
sts = BC_STS_NOT_IMPL;
temp->udata.RetSts = sts;
rc = chd_dec_proc_user_data(adp, temp, ua, 1);
}
chd_dec_free_iodata(adp, temp, 0);
return rc;
}
/* API interfaces */
static long chd_dec_ioctl(struct file *fd, unsigned int cmd, unsigned long ua)
{
struct crystalhd_adp *adp = chd_get_adp();
crystalhd_cmd_proc cproc;
struct crystalhd_user *uc;
int ret;
if (!adp || !fd) {
BCMLOG_ERR("Invalid adp\n");
return -EINVAL;
}
uc = fd->private_data;
if (!uc) {
BCMLOG_ERR("Failed to get uc\n");
return -ENODATA;
}
mutex_lock(&chd_dec_mutex);
cproc = crystalhd_get_cmd_proc(&adp->cmds, cmd, uc);
if (!cproc) {
BCMLOG_ERR("Unhandled command: %d\n", cmd);
mutex_unlock(&chd_dec_mutex);
return -EINVAL;
}
ret = chd_dec_api_cmd(adp, ua, uc->uid, cmd, cproc);
mutex_unlock(&chd_dec_mutex);
return ret;
}
static int chd_dec_open(struct inode *in, struct file *fd)
{
struct crystalhd_adp *adp = chd_get_adp();
int rc = 0;
enum BC_STATUS sts = BC_STS_SUCCESS;
struct crystalhd_user *uc = NULL;
if (!adp) {
BCMLOG_ERR("Invalid adp\n");
return -EINVAL;
}
if (adp->cfg_users >= BC_LINK_MAX_OPENS) {
BCMLOG(BCMLOG_INFO, "Already in use.%d\n", adp->cfg_users);
return -EBUSY;
}
sts = crystalhd_user_open(&adp->cmds, &uc);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("cmd_user_open - %d\n", sts);
rc = -EBUSY;
}
adp->cfg_users++;
fd->private_data = uc;
return rc;
}
static int chd_dec_close(struct inode *in, struct file *fd)
{
struct crystalhd_adp *adp = chd_get_adp();
struct crystalhd_user *uc;
if (!adp) {
BCMLOG_ERR("Invalid adp\n");
return -EINVAL;
}
uc = fd->private_data;
if (!uc) {
BCMLOG_ERR("Failed to get uc\n");
return -ENODATA;
}
crystalhd_user_close(&adp->cmds, uc);
adp->cfg_users--;
return 0;
}
static const struct file_operations chd_dec_fops = {
.owner = THIS_MODULE,
.unlocked_ioctl = chd_dec_ioctl,
.open = chd_dec_open,
.release = chd_dec_close,
.llseek = noop_llseek,
};
static int chd_dec_init_chdev(struct crystalhd_adp *adp)
{
struct crystalhd_ioctl_data *temp;
struct device *dev;
int rc = -ENODEV, i = 0;
if (!adp)
goto fail;
adp->chd_dec_major = register_chrdev(0, CRYSTALHD_API_NAME,
&chd_dec_fops);
if (adp->chd_dec_major < 0) {
BCMLOG_ERR("Failed to create config dev\n");
rc = adp->chd_dec_major;
goto fail;
}
/* register crystalhd class */
crystalhd_class = class_create(THIS_MODULE, "crystalhd");
if (IS_ERR(crystalhd_class)) {
rc = PTR_ERR(crystalhd_class);
BCMLOG_ERR("failed to create class\n");
goto class_create_fail;
}
dev = device_create(crystalhd_class, NULL,
MKDEV(adp->chd_dec_major, 0), NULL, "crystalhd");
if (IS_ERR(dev)) {
rc = PTR_ERR(dev);
BCMLOG_ERR("failed to create device\n");
goto device_create_fail;
}
rc = crystalhd_create_elem_pool(adp, BC_LINK_ELEM_POOL_SZ);
if (rc) {
BCMLOG_ERR("failed to create device\n");
goto elem_pool_fail;
}
/* Allocate general purpose ioctl pool. */
for (i = 0; i < CHD_IODATA_POOL_SZ; i++) {
temp = kzalloc(sizeof(*temp), GFP_KERNEL);
if (!temp) {
BCMLOG_ERR("ioctl data pool kzalloc failed\n");
rc = -ENOMEM;
goto kzalloc_fail;
}
/* Add to global pool.. */
chd_dec_free_iodata(adp, temp, 0);
}
return 0;
kzalloc_fail:
crystalhd_delete_elem_pool(adp);
elem_pool_fail:
device_destroy(crystalhd_class, MKDEV(adp->chd_dec_major, 0));
device_create_fail:
class_destroy(crystalhd_class);
class_create_fail:
unregister_chrdev(adp->chd_dec_major, CRYSTALHD_API_NAME);
fail:
return rc;
}
static void chd_dec_release_chdev(struct crystalhd_adp *adp)
{
struct crystalhd_ioctl_data *temp = NULL;
if (!adp)
return;
if (adp->chd_dec_major > 0) {
/* unregister crystalhd class */
device_destroy(crystalhd_class, MKDEV(adp->chd_dec_major, 0));
unregister_chrdev(adp->chd_dec_major, CRYSTALHD_API_NAME);
BCMLOG(BCMLOG_INFO, "released api device - %d\n",
adp->chd_dec_major);
class_destroy(crystalhd_class);
}
adp->chd_dec_major = 0;
/* Clear iodata pool.. */
do {
temp = chd_dec_alloc_iodata(adp, 0);
kfree(temp);
} while (temp);
crystalhd_delete_elem_pool(adp);
}
static int chd_pci_reserve_mem(struct crystalhd_adp *pinfo)
{
int rc;
unsigned long bar2 = pci_resource_start(pinfo->pdev, 2);
uint32_t mem_len = pci_resource_len(pinfo->pdev, 2);
unsigned long bar0 = pci_resource_start(pinfo->pdev, 0);
uint32_t i2o_len = pci_resource_len(pinfo->pdev, 0);
BCMLOG(BCMLOG_SSTEP, "bar2:0x%lx-0x%08x bar0:0x%lx-0x%08x\n",
bar2, mem_len, bar0, i2o_len);
rc = check_mem_region(bar2, mem_len);
if (rc) {
BCMLOG_ERR("No valid mem region...\n");
return -ENOMEM;
}
pinfo->addr = ioremap_nocache(bar2, mem_len);
if (!pinfo->addr) {
BCMLOG_ERR("Failed to remap mem region...\n");
return -ENOMEM;
}
pinfo->pci_mem_start = bar2;
pinfo->pci_mem_len = mem_len;
rc = check_mem_region(bar0, i2o_len);
if (rc) {
BCMLOG_ERR("No valid mem region...\n");
return -ENOMEM;
}
pinfo->i2o_addr = ioremap_nocache(bar0, i2o_len);
if (!pinfo->i2o_addr) {
BCMLOG_ERR("Failed to remap mem region...\n");
return -ENOMEM;
}
pinfo->pci_i2o_start = bar0;
pinfo->pci_i2o_len = i2o_len;
rc = pci_request_regions(pinfo->pdev, pinfo->name);
if (rc < 0) {
BCMLOG_ERR("Region request failed: %d\n", rc);
return rc;
}
BCMLOG(BCMLOG_SSTEP, "Mapped addr:0x%08lx i2o_addr:0x%08lx\n",
(unsigned long)pinfo->addr, (unsigned long)pinfo->i2o_addr);
return 0;
}
static void chd_pci_release_mem(struct crystalhd_adp *pinfo)
{
if (!pinfo)
return;
if (pinfo->addr)
iounmap(pinfo->addr);
if (pinfo->i2o_addr)
iounmap(pinfo->i2o_addr);
pci_release_regions(pinfo->pdev);
}
static void chd_dec_pci_remove(struct pci_dev *pdev)
{
struct crystalhd_adp *pinfo;
enum BC_STATUS sts = BC_STS_SUCCESS;
pinfo = pci_get_drvdata(pdev);
if (!pinfo) {
BCMLOG_ERR("could not get adp\n");
return;
}
sts = crystalhd_delete_cmd_context(&pinfo->cmds);
if (sts != BC_STS_SUCCESS)
BCMLOG_ERR("cmd delete :%d\n", sts);
chd_dec_release_chdev(pinfo);
chd_dec_disable_int(pinfo);
chd_pci_release_mem(pinfo);
pci_disable_device(pinfo->pdev);
kfree(pinfo);
g_adp_info = NULL;
}
static int chd_dec_pci_probe(struct pci_dev *pdev,
const struct pci_device_id *entry)
{
struct crystalhd_adp *pinfo;
int rc;
enum BC_STATUS sts = BC_STS_SUCCESS;
BCMLOG(BCMLOG_DBG,
"PCI_INFO: Vendor:0x%04x Device:0x%04x s_vendor:0x%04x s_device: 0x%04x\n",
pdev->vendor, pdev->device, pdev->subsystem_vendor,
pdev->subsystem_device);
pinfo = kzalloc(sizeof(*pinfo), GFP_KERNEL);
if (!pinfo) {
BCMLOG_ERR("Failed to allocate memory\n");
return -ENOMEM;
}
pinfo->pdev = pdev;
rc = pci_enable_device(pdev);
if (rc) {
BCMLOG_ERR("Failed to enable PCI device\n");
goto err;
}
snprintf(pinfo->name, sizeof(pinfo->name), "crystalhd_pci_e:%d:%d:%d",
pdev->bus->number, PCI_SLOT(pdev->devfn),
PCI_FUNC(pdev->devfn));
rc = chd_pci_reserve_mem(pinfo);
if (rc) {
BCMLOG_ERR("Failed to setup memory regions.\n");
pci_disable_device(pdev);
rc = -ENOMEM;
goto err;
}
pinfo->present = 1;
pinfo->drv_data = entry->driver_data;
/* Setup adapter level lock.. */
spin_lock_init(&pinfo->lock);
/* setup api stuff.. */
chd_dec_init_chdev(pinfo);
rc = chd_dec_enable_int(pinfo);
if (rc) {
BCMLOG_ERR("_enable_int err:%d\n", rc);
pci_disable_device(pdev);
rc = -ENODEV;
goto err;
}
/* Set dma mask... */
if (!pci_set_dma_mask(pdev, DMA_BIT_MASK(64))) {
pci_set_consistent_dma_mask(pdev, DMA_BIT_MASK(64));
pinfo->dmabits = 64;
} else if (!pci_set_dma_mask(pdev, DMA_BIT_MASK(32))) {
pci_set_consistent_dma_mask(pdev, DMA_BIT_MASK(32));
pinfo->dmabits = 32;
} else {
BCMLOG_ERR("Unabled to setup DMA %d\n", rc);
pci_disable_device(pdev);
rc = -ENODEV;
goto err;
}
sts = crystalhd_setup_cmd_context(&pinfo->cmds, pinfo);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("cmd setup :%d\n", sts);
pci_disable_device(pdev);
rc = -ENODEV;
goto err;
}
pci_set_master(pdev);
pci_set_drvdata(pdev, pinfo);
g_adp_info = pinfo;
return 0;
err:
kfree(pinfo);
return rc;
}
#ifdef CONFIG_PM
static int chd_dec_pci_suspend(struct pci_dev *pdev, pm_message_t state)
{
struct crystalhd_adp *adp;
struct crystalhd_ioctl_data *temp;
enum BC_STATUS sts = BC_STS_SUCCESS;
adp = pci_get_drvdata(pdev);
if (!adp) {
BCMLOG_ERR("could not get adp\n");
return -ENODEV;
}
temp = chd_dec_alloc_iodata(adp, false);
if (!temp) {
BCMLOG_ERR("could not get ioctl data\n");
return -ENODEV;
}
sts = crystalhd_suspend(&adp->cmds, temp);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("BCM70012 Suspend %d\n", sts);
return -ENODEV;
}
chd_dec_free_iodata(adp, temp, false);
chd_dec_disable_int(adp);
pci_save_state(pdev);
/* Disable IO/bus master/irq router */
pci_disable_device(pdev);
pci_set_power_state(pdev, pci_choose_state(pdev, state));
return 0;
}
static int chd_dec_pci_resume(struct pci_dev *pdev)
{
struct crystalhd_adp *adp;
enum BC_STATUS sts = BC_STS_SUCCESS;
int rc;
adp = pci_get_drvdata(pdev);
if (!adp) {
BCMLOG_ERR("could not get adp\n");
return -ENODEV;
}
pci_set_power_state(pdev, PCI_D0);
pci_restore_state(pdev);
/* device's irq possibly is changed, driver should take care */
if (pci_enable_device(pdev)) {
BCMLOG_ERR("Failed to enable PCI device\n");
return 1;
}
pci_set_master(pdev);
rc = chd_dec_enable_int(adp);
if (rc) {
BCMLOG_ERR("_enable_int err:%d\n", rc);
pci_disable_device(pdev);
return -ENODEV;
}
sts = crystalhd_resume(&adp->cmds);
if (sts != BC_STS_SUCCESS) {
BCMLOG_ERR("BCM70012 Resume %d\n", sts);
pci_disable_device(pdev);
return -ENODEV;
}
return 0;
}
#endif
static const struct pci_device_id chd_dec_pci_id_table[] = {
{ PCI_VDEVICE(BROADCOM, 0x1612), 8 },
{ 0, },
};
MODULE_DEVICE_TABLE(pci, chd_dec_pci_id_table);
static struct pci_driver bc_chd_70012_driver = {
.name = "Broadcom 70012 Decoder",
.probe = chd_dec_pci_probe,
.remove = chd_dec_pci_remove,
.id_table = chd_dec_pci_id_table,
#ifdef CONFIG_PM
.suspend = chd_dec_pci_suspend,
.resume = chd_dec_pci_resume
#endif
};
void chd_set_log_level(struct crystalhd_adp *adp, char *arg)
{
if ((!arg) || (strlen(arg) < 3))
g_linklog_level = BCMLOG_ERROR | BCMLOG_DATA;
else if (!strncmp(arg, "sstep", 5))
g_linklog_level = BCMLOG_INFO | BCMLOG_DATA | BCMLOG_DBG |
BCMLOG_SSTEP | BCMLOG_ERROR;
else if (!strncmp(arg, "info", 4))
g_linklog_level = BCMLOG_ERROR | BCMLOG_DATA | BCMLOG_INFO;
else if (!strncmp(arg, "debug", 5))
g_linklog_level = BCMLOG_ERROR | BCMLOG_DATA | BCMLOG_INFO |
BCMLOG_DBG;
else if (!strncmp(arg, "pball", 5))
g_linklog_level = 0xFFFFFFFF & ~(BCMLOG_SPINLOCK);
else if (!strncmp(arg, "silent", 6))
g_linklog_level = 0;
else
g_linklog_level = 0;
}
struct crystalhd_adp *chd_get_adp(void)
{
return g_adp_info;
}
static int __init chd_dec_module_init(void)
{
int rc;
chd_set_log_level(NULL, "debug");
BCMLOG(BCMLOG_DATA, "Loading crystalhd %d.%d.%d\n",
crystalhd_kmod_major, crystalhd_kmod_minor, crystalhd_kmod_rev);
rc = pci_register_driver(&bc_chd_70012_driver);
if (rc < 0)
BCMLOG_ERR("Could not find any devices. err:%d\n", rc);
return rc;
}
module_init(chd_dec_module_init);
static void __exit chd_dec_module_cleanup(void)
{
BCMLOG(BCMLOG_DATA, "unloading crystalhd %d.%d.%d\n",
crystalhd_kmod_major, crystalhd_kmod_minor, crystalhd_kmod_rev);
pci_unregister_driver(&bc_chd_70012_driver);
}
module_exit(chd_dec_module_cleanup);
MODULE_AUTHOR("Naren Sankar <nsankar@broadcom.com>");
MODULE_AUTHOR("Prasad Bolisetty <prasadb@broadcom.com>");
MODULE_DESCRIPTION(CRYSTAL_HD_NAME);
MODULE_LICENSE("GPL");
MODULE_ALIAS("bcm70012");
drivers/staging/crystalhd/crystalhd_lnx.h deleted 100644 → 0
View file @ 895ae876
/***************************************************************************
* Copyright (c) 2005-2009, Broadcom Corporation.
*
* Name: crystalhd_lnx . h
*
* Description:
* BCM70012 Linux driver
*
* HISTORY:
*
**********************************************************************
* This file is part of the crystalhd device driver.
*
* This driver 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, version 2 of the License.
*
* This driver is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this driver. If not, see <http://www.gnu.org/licenses/>.
**********************************************************************/
#ifndef _CRYSTALHD_LNX_H_
#define _CRYSTALHD_LNX_H_
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/errno.h>
#include <linux/string.h>
#include <linux/mm.h>
#include <linux/tty.h>
#include <linux/slab.h>
#include <linux/delay.h>
#include <linux/fb.h>
#include <linux/pci.h>
#include <linux/interrupt.h>
#include <linux/pagemap.h>
#include <linux/vmalloc.h>
#include <linux/io.h>
#include <asm/irq.h>
#include <asm/pgtable.h>
#include <linux/uaccess.h>
#include "crystalhd.h"
#define CRYSTAL_HD_NAME "Broadcom Crystal HD Decoder (BCM70012) Driver"
/* OS specific PCI information structure and adapter information. */
struct crystalhd_adp {
/* Hardware board/PCI specifics */
char name[32];
struct pci_dev *pdev;
unsigned long pci_mem_start;
uint32_t pci_mem_len;
void __iomem *addr;
unsigned long pci_i2o_start;
uint32_t pci_i2o_len;
void __iomem *i2o_addr;
unsigned int drv_data;
unsigned int dmabits; /* 32 | 64 */
unsigned int registered;
unsigned int present;
unsigned int msi;
spinlock_t lock;
/* API Related */
int chd_dec_major;
unsigned int cfg_users;
struct crystalhd_ioctl_data *idata_free_head; /* ioctl data pool */
struct crystalhd_elem *elem_pool_head; /* Queue element pool */
struct crystalhd_cmd cmds;
struct crystalhd_dio_req *ua_map_free_head;
struct pci_pool *fill_byte_pool;
};
struct crystalhd_adp *chd_get_adp(void);
void chd_set_log_level(struct crystalhd_adp *adp, char *arg);
#endif
drivers/staging/crystalhd/crystalhd_misc.c deleted 100644 → 0
View file @ 895ae876
/***************************************************************************
* Copyright (c) 2005-2009, Broadcom Corporation.
*
* Name: crystalhd_misc . c
*
* Description:
* BCM70012 Linux driver misc routines.
*
* HISTORY:
*
**********************************************************************
* This file is part of the crystalhd device driver.
*
* This driver 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, version 2 of the License.
*
* This driver is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this driver. If not, see <http://www.gnu.org/licenses/>.
**********************************************************************/
#include "crystalhd.h"
#include <linux/slab.h>
uint32_t g_linklog_level;
static inline uint32_t crystalhd_dram_rd(struct crystalhd_adp *adp,
uint32_t mem_off)
{
crystalhd_reg_wr(adp, DCI_DRAM_BASE_ADDR, (mem_off >> 19));
return bc_dec_reg_rd(adp, (0x00380000 | (mem_off & 0x0007FFFF)));
}
static inline void crystalhd_dram_wr(struct crystalhd_adp *adp,
uint32_t mem_off, uint32_t val)
{
crystalhd_reg_wr(adp, DCI_DRAM_BASE_ADDR, (mem_off >> 19));
bc_dec_reg_wr(adp, (0x00380000 | (mem_off & 0x0007FFFF)), val);
}
static inline enum BC_STATUS bc_chk_dram_range(struct crystalhd_adp *adp,
uint32_t start_off, uint32_t cnt)
{
return BC_STS_SUCCESS;
}
static struct crystalhd_dio_req *crystalhd_alloc_dio(struct crystalhd_adp *adp)
{
unsigned long flags = 0;
struct crystalhd_dio_req *temp = NULL;
if (!adp) {
BCMLOG_ERR("Invalid Arg!!\n");
return temp;
}
spin_lock_irqsave(&adp->lock, flags);
temp = adp->ua_map_free_head;
if (temp)
adp->ua_map_free_head = adp->ua_map_free_head->next;
spin_unlock_irqrestore(&adp->lock, flags);
return temp;
}
static void crystalhd_free_dio(struct crystalhd_adp *adp,
struct crystalhd_dio_req *dio)
{
unsigned long flags = 0;
if (!adp || !dio)
return;
spin_lock_irqsave(&adp->lock, flags);
dio->sig = crystalhd_dio_inv;
dio->page_cnt = 0;
dio->fb_size = 0;
memset(&dio->uinfo, 0, sizeof(dio->uinfo));
dio->next = adp->ua_map_free_head;
adp->ua_map_free_head = dio;
spin_unlock_irqrestore(&adp->lock, flags);
}
static struct crystalhd_elem *crystalhd_alloc_elem(struct crystalhd_adp *adp)
{
unsigned long flags = 0;
struct crystalhd_elem *temp = NULL;
if (!adp)
return temp;
spin_lock_irqsave(&adp->lock, flags);
temp = adp->elem_pool_head;
if (temp) {
adp->elem_pool_head = adp->elem_pool_head->flink;
memset(temp, 0, sizeof(*temp));
}
spin_unlock_irqrestore(&adp->lock, flags);
return temp;
}
static void crystalhd_free_elem(struct crystalhd_adp *adp,
struct crystalhd_elem *elem)
{
unsigned long flags = 0;
if (!adp || !elem)
return;
spin_lock_irqsave(&adp->lock, flags);
elem->flink = adp->elem_pool_head;
adp->elem_pool_head = elem;
spin_unlock_irqrestore(&adp->lock, flags);
}
static inline void crystalhd_set_sg(struct scatterlist *sg, struct page *page,
unsigned int len, unsigned int offset)
{
sg_set_page(sg, page, len, offset);
#ifdef CONFIG_X86_64
sg->dma_length = len;
#endif
}
static inline void crystalhd_init_sg(struct scatterlist *sg,
unsigned int entries)
{
/* http://lkml.org/lkml/2007/11/27/68 */
sg_init_table(sg, entries);
}
/*========================== Extern ========================================*/
/**
* bc_dec_reg_rd - Read 7412's device register.
* @adp: Adapter instance
* @reg_off: Register offset.
*
* Return:
* 32bit value read
*
* 7412's device register read routine. This interface use
* 7412's device access range mapped from BAR-2 (4M) of PCIe
* configuration space.
*/
uint32_t bc_dec_reg_rd(struct crystalhd_adp *adp, uint32_t reg_off)
{
if (!adp || (reg_off > adp->pci_mem_len)) {
BCMLOG_ERR("dec_rd_reg_off outof range: 0x%08x\n", reg_off);
return 0;
}
return readl(adp->addr + reg_off);
}
/**
* bc_dec_reg_wr - Write 7412's device register
* @adp: Adapter instance
* @reg_off: Register offset.
* @val: Dword value to be written.
*
* Return:
* none.
*
* 7412's device register write routine. This interface use
* 7412's device access range mapped from BAR-2 (4M) of PCIe
* configuration space.
*/
void bc_dec_reg_wr(struct crystalhd_adp *adp, uint32_t reg_off, uint32_t val)
{
if (!adp || (reg_off > adp->pci_mem_len)) {
BCMLOG_ERR("dec_wr_reg_off outof range: 0x%08x\n", reg_off);
return;
}
writel(val, adp->addr + reg_off);
udelay(8);
}
/**
* crystalhd_reg_rd - Read Link's device register.
* @adp: Adapter instance
* @reg_off: Register offset.
*
* Return:
* 32bit value read
*
* Link device register read routine. This interface use
* Link's device access range mapped from BAR-1 (64K) of PCIe
* configuration space.
*
*/
uint32_t crystalhd_reg_rd(struct crystalhd_adp *adp, uint32_t reg_off)
{
if (!adp || (reg_off > adp->pci_i2o_len)) {
BCMLOG_ERR("link_rd_reg_off outof range: 0x%08x\n", reg_off);
return 0;
}
return readl(adp->i2o_addr + reg_off);
}
/**
* crystalhd_reg_wr - Write Link's device register
* @adp: Adapter instance
* @reg_off: Register offset.
* @val: Dword value to be written.
*
* Return:
* none.
*
* Link device register write routine. This interface use
* Link's device access range mapped from BAR-1 (64K) of PCIe
* configuration space.
*
*/
void crystalhd_reg_wr(struct crystalhd_adp *adp, uint32_t reg_off,
uint32_t val)
{
if (!adp || (reg_off > adp->pci_i2o_len)) {
BCMLOG_ERR("link_wr_reg_off outof range: 0x%08x\n", reg_off);
return;
}
writel(val, adp->i2o_addr + reg_off);
}
/**
* crystalhd_mem_rd - Read data from 7412's DRAM area.
* @adp: Adapter instance
* @start_off: Start offset.
* @dw_cnt: Count in dwords.
* @rd_buff: Buffer to copy the data from dram.
*
* Return:
* Status.
*
* 7412's Dram read routine.
*/
enum BC_STATUS crystalhd_mem_rd(struct crystalhd_adp *adp, uint32_t start_off,
uint32_t dw_cnt, uint32_t *rd_buff)
{
uint32_t ix = 0;
if (!adp || !rd_buff ||
(bc_chk_dram_range(adp, start_off, dw_cnt) != BC_STS_SUCCESS)) {
BCMLOG_ERR("Invalid arg\n");
return BC_STS_INV_ARG;
}
for (ix = 0; ix < dw_cnt; ix++)
rd_buff[ix] = crystalhd_dram_rd(adp, (start_off + (ix * 4)));
return BC_STS_SUCCESS;
}
/**
* crystalhd_mem_wr - Write data to 7412's DRAM area.
* @adp: Adapter instance
* @start_off: Start offset.
* @dw_cnt: Count in dwords.
* @wr_buff: Data Buffer to be written.
*
* Return:
* Status.
*
* 7412's Dram write routine.
*/
enum BC_STATUS crystalhd_mem_wr(struct crystalhd_adp *adp, uint32_t start_off,
uint32_t dw_cnt, uint32_t *wr_buff)
{
uint32_t ix = 0;
if (!adp || !wr_buff ||
(bc_chk_dram_range(adp, start_off, dw_cnt) != BC_STS_SUCCESS)) {
BCMLOG_ERR("Invalid arg\n");
return BC_STS_INV_ARG;
}
for (ix = 0; ix < dw_cnt; ix++)
crystalhd_dram_wr(adp, (start_off + (ix * 4)), wr_buff[ix]);
return BC_STS_SUCCESS;
}
/**
* crystalhd_pci_cfg_rd - PCIe config read
* @adp: Adapter instance
* @off: PCI config space offset.
* @len: Size -- Byte, Word & dword.
* @val: Value read
*
* Return:
* Status.
*
* Get value from Link's PCIe config space.
*/
enum BC_STATUS crystalhd_pci_cfg_rd(struct crystalhd_adp *adp, uint32_t off,
uint32_t len, uint32_t *val)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
int rc = 0;
if (!adp || !val) {
BCMLOG_ERR("Invalid arg\n");
return BC_STS_INV_ARG;
}
switch (len) {
case 1:
rc = pci_read_config_byte(adp->pdev, off, (u8 *)val);
break;
case 2:
rc = pci_read_config_word(adp->pdev, off, (u16 *)val);
break;
case 4:
rc = pci_read_config_dword(adp->pdev, off, (u32 *)val);
break;
default:
rc = -EINVAL;
sts = BC_STS_INV_ARG;
BCMLOG_ERR("Invalid len:%d\n", len);
}
if (rc && (sts == BC_STS_SUCCESS))
sts = BC_STS_ERROR;
return sts;
}
/**
* crystalhd_pci_cfg_wr - PCIe config write
* @adp: Adapter instance
* @off: PCI config space offset.
* @len: Size -- Byte, Word & dword.
* @val: Value to be written
*
* Return:
* Status.
*
* Set value to Link's PCIe config space.
*/
enum BC_STATUS crystalhd_pci_cfg_wr(struct crystalhd_adp *adp, uint32_t off,
uint32_t len, uint32_t val)
{
enum BC_STATUS sts = BC_STS_SUCCESS;
int rc = 0;
if (!adp || !val) {
BCMLOG_ERR("Invalid arg\n");
return BC_STS_INV_ARG;
}
switch (len) {
case 1:
rc = pci_write_config_byte(adp->pdev, off, (u8)val);
break;
case 2:
rc = pci_write_config_word(adp->pdev, off, (u16)val);
break;
case 4:
rc = pci_write_config_dword(adp->pdev, off, val);
break;
default:
rc = -EINVAL;
sts = BC_STS_INV_ARG;
BCMLOG_ERR("Invalid len:%d\n", len);
}
if (rc && (sts == BC_STS_SUCCESS))
sts = BC_STS_ERROR;
return sts;
}
/**
* bc_kern_dma_alloc - Allocate memory for Dma rings
* @adp: Adapter instance
* @sz: Size of the memory to allocate.
* @phy_addr: Physical address of the memory allocated.
* Typedef to system's dma_addr_t (u64)
*
* Return:
* Pointer to allocated memory..
*
* Wrapper to Linux kernel interface.
*
*/
void *bc_kern_dma_alloc(struct crystalhd_adp *adp, uint32_t sz,
dma_addr_t *phy_addr)
{
void *temp = NULL;
if (!adp || !sz || !phy_addr) {
BCMLOG_ERR("Invalid Arg..\n");
return temp;
}
temp = pci_alloc_consistent(adp->pdev, sz, phy_addr);
if (temp)
memset(temp, 0, sz);
return temp;
}
/**
* bc_kern_dma_free - Release Dma ring memory.
* @adp: Adapter instance
* @sz: Size of the memory to allocate.
* @ka: Kernel virtual address returned during _dio_alloc()
* @phy_addr: Physical address of the memory allocated.
* Typedef to system's dma_addr_t (u64)
*
* Return:
* none.
*/
void bc_kern_dma_free(struct crystalhd_adp *adp, uint32_t sz, void *ka,
dma_addr_t phy_addr)
{
if (!adp || !ka || !sz || !phy_addr) {
BCMLOG_ERR("Invalid Arg..\n");
return;
}
pci_free_consistent(adp->pdev, sz, ka, phy_addr);
}
/**
* crystalhd_create_dioq - Create Generic DIO queue
* @adp: Adapter instance
* @dioq_hnd: Handle to the dio queue created
* @cb : Optional - Call back To free the element.
* @cbctx: Context to pass to callback.
*
* Return:
* status
*
* Initialize Generic DIO queue to hold any data. Callback
* will be used to free elements while deleting the queue.
*/
enum BC_STATUS crystalhd_create_dioq(struct crystalhd_adp *adp,
struct crystalhd_dioq **dioq_hnd,
crystalhd_data_free_cb cb, void *cbctx)
{
struct crystalhd_dioq *dioq = NULL;
if (!adp || !dioq_hnd) {
BCMLOG_ERR("Invalid arg!!\n");
return BC_STS_INV_ARG;
}
dioq = kzalloc(sizeof(*dioq), GFP_KERNEL);
if (!dioq)
return BC_STS_INSUFF_RES;
spin_lock_init(&dioq->lock);
dioq->sig = BC_LINK_DIOQ_SIG;
dioq->head = (struct crystalhd_elem *)&dioq->head;
dioq->tail = (struct crystalhd_elem *)&dioq->head;
crystalhd_create_event(&dioq->event);
dioq->adp = adp;
dioq->data_rel_cb = cb;
dioq->cb_context = cbctx;
*dioq_hnd = dioq;
return BC_STS_SUCCESS;
}
/**
* crystalhd_delete_dioq - Delete Generic DIO queue
* @adp: Adapter instance
* @dioq: DIOQ instance..
*
* Return:
* None.
*
* Release Generic DIO queue. This function will remove
* all the entries from the Queue and will release data
* by calling the call back provided during creation.
*
*/
void crystalhd_delete_dioq(struct crystalhd_adp *adp,
struct crystalhd_dioq *dioq)
{
void *temp;
if (!dioq || (dioq->sig != BC_LINK_DIOQ_SIG))
return;
do {
temp = crystalhd_dioq_fetch(dioq);
if (temp && dioq->data_rel_cb)
dioq->data_rel_cb(dioq->cb_context, temp);
} while (temp);
dioq->sig = 0;
kfree(dioq);
}
/**
* crystalhd_dioq_add - Add new DIO request element.
* @ioq: DIO queue instance
* @t: DIO request to be added.
* @wake: True - Wake up suspended process.
* @tag: Special tag to assign - For search and get.
*
* Return:
* Status.
*
* Insert new element to Q tail.
*/
enum BC_STATUS crystalhd_dioq_add(struct crystalhd_dioq *ioq, void *data,
bool wake, uint32_t tag)
{
unsigned long flags = 0;
struct crystalhd_elem *tmp;
if (!ioq || (ioq->sig != BC_LINK_DIOQ_SIG) || !data) {
BCMLOG_ERR("Invalid arg!!\n");
return BC_STS_INV_ARG;
}
tmp = crystalhd_alloc_elem(ioq->adp);
if (!tmp) {
BCMLOG_ERR("No free elements.\n");
return BC_STS_INSUFF_RES;
}
tmp->data = data;
tmp->tag = tag;
spin_lock_irqsave(&ioq->lock, flags);
tmp->flink = (struct crystalhd_elem *)&ioq->head;
tmp->blink = ioq->tail;
tmp->flink->blink = tmp;
tmp->blink->flink = tmp;
ioq->count++;
spin_unlock_irqrestore(&ioq->lock, flags);
if (wake)
crystalhd_set_event(&ioq->event);
return BC_STS_SUCCESS;
}
/**
* crystalhd_dioq_fetch - Fetch element from head.
* @ioq: DIO queue instance
*
* Return:
* data element from the head..
*
* Remove an element from Queue.
*/
void *crystalhd_dioq_fetch(struct crystalhd_dioq *ioq)
{
unsigned long flags = 0;
struct crystalhd_elem *tmp;
struct crystalhd_elem *ret = NULL;
void *data = NULL;
if (!ioq || (ioq->sig != BC_LINK_DIOQ_SIG)) {
BCMLOG_ERR("Invalid arg!!\n");
return data;
}
spin_lock_irqsave(&ioq->lock, flags);
tmp = ioq->head;
if (tmp != (struct crystalhd_elem *)&ioq->head) {
ret = tmp;
tmp->flink->blink = tmp->blink;
tmp->blink->flink = tmp->flink;
ioq->count--;
}
spin_unlock_irqrestore(&ioq->lock, flags);
if (ret) {
data = ret->data;
crystalhd_free_elem(ioq->adp, ret);
}
return data;
}
/**
* crystalhd_dioq_find_and_fetch - Search the tag and Fetch element
* @ioq: DIO queue instance
* @tag: Tag to search for.
*
* Return:
* element from the head..
*
* Search TAG and remove the element.
*/
void *crystalhd_dioq_find_and_fetch(struct crystalhd_dioq *ioq, uint32_t tag)
{
unsigned long flags = 0;
struct crystalhd_elem *tmp;
struct crystalhd_elem *ret = NULL;
void *data = NULL;
if (!ioq || (ioq->sig != BC_LINK_DIOQ_SIG)) {
BCMLOG_ERR("Invalid arg!!\n");
return data;
}
spin_lock_irqsave(&ioq->lock, flags);
tmp = ioq->head;
while (tmp != (struct crystalhd_elem *)&ioq->head) {
if (tmp->tag == tag) {
ret = tmp;
tmp->flink->blink = tmp->blink;
tmp->blink->flink = tmp->flink;
ioq->count--;
break;
}
tmp = tmp->flink;
}
spin_unlock_irqrestore(&ioq->lock, flags);
if (ret) {
data = ret->data;
crystalhd_free_elem(ioq->adp, ret);
}
return data;
}
/**
* crystalhd_dioq_fetch_wait - Fetch element from Head.
* @ioq: DIO queue instance
* @to_secs: Wait timeout in seconds..
*
* Return:
* element from the head..
*
* Return element from head if Q is not empty. Wait for new element
* if Q is empty for Timeout seconds.
*/
void *crystalhd_dioq_fetch_wait(struct crystalhd_dioq *ioq, uint32_t to_secs,
uint32_t *sig_pend)
{
unsigned long flags = 0;
int rc = 0, count;
void *tmp = NULL;
if (!ioq || (ioq->sig != BC_LINK_DIOQ_SIG) || !to_secs || !sig_pend) {
BCMLOG_ERR("Invalid arg!!\n");
return tmp;
}
count = to_secs;
spin_lock_irqsave(&ioq->lock, flags);
while ((ioq->count == 0) && count) {
spin_unlock_irqrestore(&ioq->lock, flags);
crystalhd_wait_on_event(&ioq->event,
(ioq->count > 0), 1000, rc, 0);
if (rc == 0) {
goto out;
} else if (rc == -EINTR) {
BCMLOG(BCMLOG_INFO, "Cancelling fetch wait\n");
*sig_pend = 1;
return tmp;
}
spin_lock_irqsave(&ioq->lock, flags);
count--;
}
spin_unlock_irqrestore(&ioq->lock, flags);
out:
return crystalhd_dioq_fetch(ioq);
}
/**
* crystalhd_map_dio - Map user address for DMA
* @adp: Adapter instance
* @ubuff: User buffer to map.
* @ubuff_sz: User buffer size.
* @uv_offset: UV buffer offset.
* @en_422mode: TRUE:422 FALSE:420 Capture mode.
* @dir_tx: TRUE for Tx (To device from host)
* @dio_hnd: Handle to mapped DIO request.
*
* Return:
* Status.
*
* This routine maps user address and lock pages for DMA.
*
*/
enum BC_STATUS crystalhd_map_dio(struct crystalhd_adp *adp, void *ubuff,
uint32_t ubuff_sz, uint32_t uv_offset,
bool en_422mode, bool dir_tx,
struct crystalhd_dio_req **dio_hnd)
{
struct crystalhd_dio_req *dio;
/* FIXME: jarod: should some of these
unsigned longs be uint32_t or uintptr_t? */
unsigned long start = 0, end = 0, uaddr = 0, count = 0;
unsigned long spsz = 0, uv_start = 0;
int i = 0, rw = 0, res = 0, nr_pages = 0, skip_fb_sg = 0;
if (!adp || !ubuff || !ubuff_sz || !dio_hnd) {
BCMLOG_ERR("Invalid arg\n");
return BC_STS_INV_ARG;
}
/* Compute pages */
uaddr = (unsigned long)ubuff;
count = (unsigned long)ubuff_sz;
end = (uaddr + count + PAGE_SIZE - 1) >> PAGE_SHIFT;
start = uaddr >> PAGE_SHIFT;
nr_pages = end - start;
if (!count || ((uaddr + count) < uaddr)) {
BCMLOG_ERR("User addr overflow!!\n");
return BC_STS_INV_ARG;
}
dio = crystalhd_alloc_dio(adp);
if (!dio) {
BCMLOG_ERR("dio pool empty..\n");
return BC_STS_INSUFF_RES;
}
if (dir_tx) {
rw = WRITE;
dio->direction = DMA_TO_DEVICE;
} else {
rw = READ;
dio->direction = DMA_FROM_DEVICE;
}
if (nr_pages > dio->max_pages) {
BCMLOG_ERR("max_pages(%d) exceeded(%d)!!\n",
dio->max_pages, nr_pages);
crystalhd_unmap_dio(adp, dio);
return BC_STS_INSUFF_RES;
}
if (uv_offset) {
uv_start = (uaddr + (unsigned long)uv_offset) >> PAGE_SHIFT;
dio->uinfo.uv_sg_ix = uv_start - start;
dio->uinfo.uv_sg_off = ((uaddr + (unsigned long)uv_offset) &
~PAGE_MASK);
}
dio->fb_size = ubuff_sz & 0x03;
if (dio->fb_size) {
res = copy_from_user(dio->fb_va,
(void __user *)(uaddr + count - dio->fb_size),
dio->fb_size);
if (res) {
BCMLOG_ERR("failed %d to copy %u fill bytes from %p\n",
res, dio->fb_size,
(void *)(uaddr + count-dio->fb_size));
crystalhd_unmap_dio(adp, dio);
return BC_STS_INSUFF_RES;
}
}
down_read(&current->mm->mmap_sem);
res = get_user_pages(current, current->mm, uaddr, nr_pages, rw == READ,
0, dio->pages, NULL);
up_read(&current->mm->mmap_sem);
/* Save for release..*/
dio->sig = crystalhd_dio_locked;
if (res < nr_pages) {
BCMLOG_ERR("get pages failed: %d-%d\n", nr_pages, res);
dio->page_cnt = res;
crystalhd_unmap_dio(adp, dio);
return BC_STS_ERROR;
}
dio->page_cnt = nr_pages;
/* Get scatter/gather */
crystalhd_init_sg(dio->sg, dio->page_cnt);
crystalhd_set_sg(&dio->sg[0], dio->pages[0], 0, uaddr & ~PAGE_MASK);
if (nr_pages > 1) {
dio->sg[0].length = PAGE_SIZE - dio->sg[0].offset;
#ifdef CONFIG_X86_64
dio->sg[0].dma_length = dio->sg[0].length;
#endif
count -= dio->sg[0].length;
for (i = 1; i < nr_pages; i++) {
if (count < 4) {
spsz = count;
skip_fb_sg = 1;
} else {
spsz = (count < PAGE_SIZE) ?
(count & ~0x03) : PAGE_SIZE;
}
crystalhd_set_sg(&dio->sg[i], dio->pages[i], spsz, 0);
count -= spsz;
}
} else {
if (count < 4) {
dio->sg[0].length = count;
skip_fb_sg = 1;
} else {
dio->sg[0].length = count - dio->fb_size;
}
#ifdef CONFIG_X86_64
dio->sg[0].dma_length = dio->sg[0].length;
#endif
}
dio->sg_cnt = pci_map_sg(adp->pdev, dio->sg,
dio->page_cnt, dio->direction);
if (dio->sg_cnt <= 0) {
BCMLOG_ERR("sg map %d-%d\n", dio->sg_cnt, dio->page_cnt);
crystalhd_unmap_dio(adp, dio);
return BC_STS_ERROR;
}
if (dio->sg_cnt && skip_fb_sg)
dio->sg_cnt -= 1;
dio->sig = crystalhd_dio_sg_mapped;
/* Fill in User info.. */
dio->uinfo.xfr_len = ubuff_sz;
dio->uinfo.xfr_buff = ubuff;
dio->uinfo.uv_offset = uv_offset;
dio->uinfo.b422mode = en_422mode;
dio->uinfo.dir_tx = dir_tx;
*dio_hnd = dio;
return BC_STS_SUCCESS;
}
/**
* crystalhd_unmap_sgl - Release mapped resources
* @adp: Adapter instance
* @dio: DIO request instance
*
* Return:
* Status.
*
* This routine is to unmap the user buffer pages.
*/
enum BC_STATUS crystalhd_unmap_dio(struct crystalhd_adp *adp,
struct crystalhd_dio_req *dio)
{
struct page *page = NULL;
int j = 0;
if (!adp || !dio) {
BCMLOG_ERR("Invalid arg\n");
return BC_STS_INV_ARG;
}
if ((dio->page_cnt > 0) && (dio->sig != crystalhd_dio_inv)) {
for (j = 0; j < dio->page_cnt; j++) {
page = dio->pages[j];
if (page) {
if (!PageReserved(page) &&
(dio->direction == DMA_FROM_DEVICE))
SetPageDirty(page);
page_cache_release(page);
}
}
}
if (dio->sig == crystalhd_dio_sg_mapped)
pci_unmap_sg(adp->pdev, dio->sg, dio->page_cnt,
dio->direction);
crystalhd_free_dio(adp, dio);
return BC_STS_SUCCESS;
}
/**
* crystalhd_create_dio_pool - Allocate mem pool for DIO management.
* @adp: Adapter instance
* @max_pages: Max pages for size calculation.
*
* Return:
* system error.
*
* This routine creates a memory pool to hold dio context for
* for HW Direct IO operation.
*/
int crystalhd_create_dio_pool(struct crystalhd_adp *adp, uint32_t max_pages)
{
uint32_t asz = 0, i = 0;
uint8_t *temp;
struct crystalhd_dio_req *dio;
if (!adp || !max_pages) {
BCMLOG_ERR("Invalid Arg!!\n");
return -EINVAL;
}
/* Get dma memory for fill byte handling..*/
adp->fill_byte_pool = pci_pool_create("crystalhd_fbyte",
adp->pdev, 8, 8, 0);
if (!adp->fill_byte_pool) {
BCMLOG_ERR("failed to create fill byte pool\n");
return -ENOMEM;
}
/* Get the max size from user based on 420/422 modes */
asz = (sizeof(*dio->pages) * max_pages) +
(sizeof(*dio->sg) * max_pages) + sizeof(*dio);
BCMLOG(BCMLOG_DBG, "Initializing Dio pool %d %d %x %p\n",
BC_LINK_SG_POOL_SZ, max_pages, asz, adp->fill_byte_pool);
for (i = 0; i < BC_LINK_SG_POOL_SZ; i++) {
temp = kzalloc(asz, GFP_KERNEL);
if ((temp) == NULL) {
BCMLOG_ERR("Failed to alloc %d mem\n", asz);
return -ENOMEM;
}
dio = (struct crystalhd_dio_req *)temp;
temp += sizeof(*dio);
dio->pages = (struct page **)temp;
temp += (sizeof(*dio->pages) * max_pages);
dio->sg = (struct scatterlist *)temp;
dio->max_pages = max_pages;
dio->fb_va = pci_pool_alloc(adp->fill_byte_pool, GFP_KERNEL,
&dio->fb_pa);
if (!dio->fb_va) {
BCMLOG_ERR("fill byte alloc failed.\n");
return -ENOMEM;
}
crystalhd_free_dio(adp, dio);
}
return 0;
}
/**
* crystalhd_destroy_dio_pool - Release DIO mem pool.
* @adp: Adapter instance
*
* Return:
* none.
*
* This routine releases dio memory pool during close.
*/
void crystalhd_destroy_dio_pool(struct crystalhd_adp *adp)
{
struct crystalhd_dio_req *dio;
int count = 0;
if (!adp) {
BCMLOG_ERR("Invalid Arg!!\n");
return;
}
do {
dio = crystalhd_alloc_dio(adp);
if (dio) {
if (dio->fb_va)
pci_pool_free(adp->fill_byte_pool,
dio->fb_va, dio->fb_pa);
count++;
kfree(dio);
}
} while (dio);
if (adp->fill_byte_pool) {
pci_pool_destroy(adp->fill_byte_pool);
adp->fill_byte_pool = NULL;
}
BCMLOG(BCMLOG_DBG, "Released dio pool %d\n", count);
}
/**
* crystalhd_create_elem_pool - List element pool creation.
* @adp: Adapter instance
* @pool_size: Number of elements in the pool.
*
* Return:
* 0 - success, <0 error
*
* Create general purpose list element pool to hold pending,
* and active requests.
*/
int crystalhd_create_elem_pool(struct crystalhd_adp *adp,
uint32_t pool_size)
{
uint32_t i;
struct crystalhd_elem *temp;
if (!adp || !pool_size)
return -EINVAL;
for (i = 0; i < pool_size; i++) {
temp = kzalloc(sizeof(*temp), GFP_KERNEL);
if (!temp) {
BCMLOG_ERR("kalloc failed\n");
return -ENOMEM;
}
crystalhd_free_elem(adp, temp);
}
BCMLOG(BCMLOG_DBG, "allocated %d elem\n", pool_size);
return 0;
}
/**
* crystalhd_delete_elem_pool - List element pool deletion.
* @adp: Adapter instance
*
* Return:
* none
*
* Delete general purpose list element pool.
*/
void crystalhd_delete_elem_pool(struct crystalhd_adp *adp)
{
struct crystalhd_elem *temp;
int dbg_cnt = 0;
if (!adp)
return;
do {
temp = crystalhd_alloc_elem(adp);
if (temp) {
kfree(temp);
dbg_cnt++;
}
} while (temp);
BCMLOG(BCMLOG_DBG, "released %d elem\n", dbg_cnt);
}
/*================ Debug support routines.. ================================*/
void crystalhd_show_buffer(uint32_t off, uint8_t *buff, uint32_t dwcount)
{
uint32_t i, k = 1;
for (i = 0; i < dwcount; i++) {
if (k == 1)
BCMLOG(BCMLOG_DATA, "0x%08X : ", off);
BCMLOG(BCMLOG_DATA, " 0x%08X ", *((uint32_t *)buff));
buff += sizeof(uint32_t);
off += sizeof(uint32_t);
k++;
if ((i == dwcount - 1) || (k > 4)) {
BCMLOG(BCMLOG_DATA, "\n");
k = 1;
}
}
}
drivers/staging/crystalhd/crystalhd_misc.h deleted 100644 → 0
View file @ 895ae876
/***************************************************************************
* Copyright (c) 2005-2009, Broadcom Corporation.
*
* Name: crystalhd_misc . h
*
* Description:
* BCM70012 Linux driver general purpose routines.
* Includes reg/mem read and write routines.
*
* HISTORY:
*
**********************************************************************
* This file is part of the crystalhd device driver.
*
* This driver 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, version 2 of the License.
*
* This driver is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this driver. If not, see <http://www.gnu.org/licenses/>.
**********************************************************************/
#ifndef _CRYSTALHD_MISC_H_
#define _CRYSTALHD_MISC_H_
#include "crystalhd.h"
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/errno.h>
#include <linux/string.h>
#include <linux/ioctl.h>
#include <linux/dma-mapping.h>
#include <linux/sched.h>
#include "bc_dts_glob_lnx.h"
/* Global log level variable defined in crystal_misc.c file */
extern uint32_t g_linklog_level;
/* Global element pool for all Queue management.
* TX: Active = BC_TX_LIST_CNT, Free = BC_TX_LIST_CNT.
* RX: Free = BC_RX_LIST_CNT, Active = 2
* FW-CMD: 4
*/
#define BC_LINK_ELEM_POOL_SZ ((BC_TX_LIST_CNT * 2) + BC_RX_LIST_CNT + 2 + 4)
/* Driver's IODATA pool count */
#define CHD_IODATA_POOL_SZ (BC_IOCTL_DATA_POOL_SIZE * BC_LINK_MAX_OPENS)
/* Scatter Gather memory pool size for Tx and Rx */
#define BC_LINK_SG_POOL_SZ (BC_TX_LIST_CNT + BC_RX_LIST_CNT)
enum crystalhd_dio_sig {
crystalhd_dio_inv = 0,
crystalhd_dio_locked,
crystalhd_dio_sg_mapped,
};
struct crystalhd_dio_user_info {
void *xfr_buff;
uint32_t xfr_len;
uint32_t uv_offset;
bool dir_tx;
uint32_t uv_sg_ix;
uint32_t uv_sg_off;
int comp_sts;
int ev_sts;
uint32_t y_done_sz;
uint32_t uv_done_sz;
uint32_t comp_flags;
bool b422mode;
};
struct crystalhd_dio_req {
uint32_t sig;
uint32_t max_pages;
struct page **pages;
struct scatterlist *sg;
int sg_cnt;
int page_cnt;
int direction;
struct crystalhd_dio_user_info uinfo;
void *fb_va;
uint32_t fb_size;
dma_addr_t fb_pa;
struct crystalhd_dio_req *next;
};
#define BC_LINK_DIOQ_SIG (0x09223280)
struct crystalhd_elem {
struct crystalhd_elem *flink;
struct crystalhd_elem *blink;
void *data;
uint32_t tag;
};
typedef void (*crystalhd_data_free_cb)(void *context, void *data);
struct crystalhd_dioq {
uint32_t sig;
struct crystalhd_adp *adp;
struct crystalhd_elem *head;
struct crystalhd_elem *tail;
uint32_t count;
spinlock_t lock;
wait_queue_head_t event;
crystalhd_data_free_cb data_rel_cb;
void *cb_context;
};
typedef void (*hw_comp_callback)(struct crystalhd_dio_req *,
wait_queue_head_t *event, enum BC_STATUS sts);
/*========= Decoder (7412) register access routines.================= */
uint32_t bc_dec_reg_rd(struct crystalhd_adp *, uint32_t);
void bc_dec_reg_wr(struct crystalhd_adp *, uint32_t, uint32_t);
/*========= Link (70012) register access routines.. =================*/
uint32_t crystalhd_reg_rd(struct crystalhd_adp *, uint32_t);
void crystalhd_reg_wr(struct crystalhd_adp *, uint32_t, uint32_t);
/*========= Decoder (7412) memory access routines..=================*/
enum BC_STATUS crystalhd_mem_rd(struct crystalhd_adp *,
uint32_t, uint32_t, uint32_t *);
enum BC_STATUS crystalhd_mem_wr(struct crystalhd_adp *,
uint32_t, uint32_t, uint32_t *);
/*==========Link (70012) PCIe Config access routines.================*/
enum BC_STATUS crystalhd_pci_cfg_rd(struct crystalhd_adp *,
uint32_t, uint32_t, uint32_t *);
enum BC_STATUS crystalhd_pci_cfg_wr(struct crystalhd_adp *,
uint32_t, uint32_t, uint32_t);
/*========= Linux Kernel Interface routines. ======================= */
void *bc_kern_dma_alloc(struct crystalhd_adp *, uint32_t, dma_addr_t *);
void bc_kern_dma_free(struct crystalhd_adp *, uint32_t,
void *, dma_addr_t);
#define crystalhd_create_event(_ev) init_waitqueue_head(_ev)
#define crystalhd_set_event(_ev) wake_up_interruptible(_ev)
#define crystalhd_wait_on_event(ev, condition, timeout, ret, nosig) \
do { \
DECLARE_WAITQUEUE(entry, current); \
unsigned long end = jiffies + ((timeout * HZ) / 1000); \
ret = 0; \
add_wait_queue(ev, &entry); \
for (;;) { \
__set_current_state(TASK_INTERRUPTIBLE); \
if (condition) { \
break; \
} \
if (time_after_eq(jiffies, end)) { \
ret = -EBUSY; \
break; \
} \
schedule_timeout((HZ / 100 > 1) ? HZ / 100 : 1); \
if (!nosig && signal_pending(current)) { \
ret = -EINTR; \
break; \
} \
} \
__set_current_state(TASK_RUNNING); \
remove_wait_queue(ev, &entry); \
} while (0)
/*================ Direct IO mapping routines ==================*/
extern int crystalhd_create_dio_pool(struct crystalhd_adp *, uint32_t);
extern void crystalhd_destroy_dio_pool(struct crystalhd_adp *);
extern enum BC_STATUS crystalhd_map_dio(struct crystalhd_adp *, void *,
uint32_t, uint32_t, bool, bool, struct crystalhd_dio_req**);
extern enum BC_STATUS crystalhd_unmap_dio(struct crystalhd_adp *,
struct crystalhd_dio_req*);
#define crystalhd_get_sgle_paddr(_dio, _ix) (sg_dma_address(&_dio->sg[_ix]))
#define crystalhd_get_sgle_len(_dio, _ix) (sg_dma_len(&_dio->sg[_ix]))
/*================ General Purpose Queues ==================*/
extern enum BC_STATUS crystalhd_create_dioq(struct crystalhd_adp *,
struct crystalhd_dioq **, crystalhd_data_free_cb , void *);
extern void crystalhd_delete_dioq(struct crystalhd_adp *,
struct crystalhd_dioq *);
extern enum BC_STATUS crystalhd_dioq_add(struct crystalhd_dioq *ioq,
void *data, bool wake, uint32_t tag);
extern void *crystalhd_dioq_fetch(struct crystalhd_dioq *ioq);
extern void *crystalhd_dioq_find_and_fetch(struct crystalhd_dioq *ioq,
uint32_t tag);
extern void *crystalhd_dioq_fetch_wait(struct crystalhd_dioq *ioq,
uint32_t to_secs, uint32_t *sig_pend);
#define crystalhd_dioq_count(_ioq) ((_ioq) ? _ioq->count : 0)
extern int crystalhd_create_elem_pool(struct crystalhd_adp *, uint32_t);
extern void crystalhd_delete_elem_pool(struct crystalhd_adp *);
/*================ Debug routines/macros .. ================================*/
extern void crystalhd_show_buffer(uint32_t off, uint8_t *buff,
uint32_t dwcount);
enum _chd_log_levels {
BCMLOG_ERROR = 0x80000000, /* Don't disable this option */
BCMLOG_DATA = 0x40000000, /* Data, enable by default */
BCMLOG_SPINLOCK = 0x20000000, /* Special case for Spin locks*/
/* Following are allowed only in debug mode */
BCMLOG_INFO = 0x00000001, /* Generic informational */
BCMLOG_DBG = 0x00000002, /* First level Debug info */
BCMLOG_SSTEP = 0x00000004, /* Stepping information */
};
#define BCMLOG(trace, fmt, args...) \
do { \
if (g_linklog_level & trace) \
printk(fmt, ##args); \
} while (0)
#define BCMLOG_ERR(fmt, args...) \
do { \
if (g_linklog_level & BCMLOG_ERROR) \
pr_err("*ERR*:%s:%d: "fmt, \
__FILE__, __LINE__, ##args); \
} while (0)
#endif
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