sound/oss/emu10k1/efxmgr.h - kernel/msm-4.9 - Gitiles

 /*
  **********************************************************************
  *     sblive_fx.h
  *     Copyright 1999, 2000 Creative Labs, Inc.
  *
  **********************************************************************
  *
  *     Date                 Author          Summary of changes
  *     ----                 ------          ------------------
  *     October 20, 1999     Bertrand Lee    base code release
  *
  **********************************************************************
  *
  *     This program is free software; you can redistribute it and/or
  *     modify it under the terms of the GNU General Public License as
  *     published by the Free Software Foundation; either version 2 of
  *     the License, or (at your option) any later version.
  *
  *     This program 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 program; if not, write to the Free
  *     Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139,
  *     USA.
  *
  **********************************************************************
  */

 #ifndef _EFXMGR_H
 #define _EFXMGR_H

 struct emu_efx_info_t{
 	int opcode_shift;
 	int high_operand_shift;
 	int instruction_start;
 	int gpr_base;
 	int output_base;
 };


 #define WRITE_EFX(a, b, c) sblive_writeptr((a), emu_efx_info[card->is_audigy].instruction_start + (b), 0, (c))

 #define OP(op, z, w, x, y) \
 	do { WRITE_EFX(card, (pc) * 2, ((x) << emu_efx_info[card->is_audigy].high_operand_shift) | (y)); \
 	WRITE_EFX(card, (pc) * 2 + 1, ((op) << emu_efx_info[card->is_audigy].opcode_shift ) | ((z) << emu_efx_info[card->is_audigy].high_operand_shift) | (w)); \
 	++pc; } while (0)

 #define NUM_INPUTS 0x20
 #define NUM_OUTPUTS 0x20
 #define NUM_GPRS 0x100

 #define A_NUM_INPUTS 0x60
 #define A_NUM_OUTPUTS 0x60  //fixme: this may or may not be true
 #define A_NUM_GPRS 0x200

 #define GPR_NAME_SIZE   32
 #define PATCH_NAME_SIZE 32

 struct dsp_rpatch {
 	char name[PATCH_NAME_SIZE];
 	u16 code_start;
 	u16 code_size;

 	unsigned long gpr_used[NUM_GPRS / (sizeof(unsigned long) * 8) + 1];
 	unsigned long gpr_input[NUM_GPRS / (sizeof(unsigned long) * 8) + 1];
 	unsigned long route[NUM_OUTPUTS];
 	unsigned long route_v[NUM_OUTPUTS];
 };

 struct dsp_patch {
 	char name[PATCH_NAME_SIZE];
 	u8 id;
 	unsigned long input;	/* bitmap of the lines used as inputs */
 	unsigned long output;	/* bitmap of the lines used as outputs */
 	u16 code_start;
 	u16 code_size;

 	unsigned long gpr_used[NUM_GPRS / (sizeof(unsigned long) * 8) + 1];	/* bitmap of used gprs */
 	unsigned long gpr_input[NUM_GPRS / (sizeof(unsigned long) * 8) + 1];
 	u8 traml_istart;	/* starting address of the internal tram lines used */
 	u8 traml_isize;		/* number of internal tram lines used */

 	u8 traml_estart;
 	u8 traml_esize;

 	u16 tramb_istart;        /* starting address of the internal tram memory used */
 	u16 tramb_isize;         /* amount of internal memory used */
 	u32 tramb_estart;
 	u32 tramb_esize;
 };

 struct dsp_gpr {
 	u8 type;			/* gpr type, STATIC, DYNAMIC, INPUT, OUTPUT, CONTROL */
 	char name[GPR_NAME_SIZE];	/* gpr value, only valid for control gprs */
 	s32 min, max;			/* value range for this gpr, only valid for control gprs */
 	u8 line;			/* which input/output line is the gpr attached, only valid for input/output gprs */
 	u8 usage;
 };

 enum {
 	GPR_TYPE_NULL = 0,
 	GPR_TYPE_IO,
 	GPR_TYPE_STATIC,
 	GPR_TYPE_DYNAMIC,
 	GPR_TYPE_CONTROL,
 	GPR_TYPE_CONSTANT
 };

 #define GPR_BASE 0x100
 #define OUTPUT_BASE 0x20

 #define A_GPR_BASE 0x400
 #define A_OUTPUT_BASE 0x60

 #define MAX_PATCHES_PAGES 32

 struct patch_manager {
 	void *patch[MAX_PATCHES_PAGES];
 	int current_pages;
 	struct dsp_rpatch rpatch;
 	struct dsp_gpr gpr[NUM_GPRS];   /* gpr usage table */
 	spinlock_t lock;
 	s16 ctrl_gpr[SOUND_MIXER_NRDEVICES][2];
 };

 #define PATCHES_PER_PAGE (PAGE_SIZE / sizeof(struct dsp_patch))

 #define PATCH(mgr, i) ((struct dsp_patch *) (mgr)->patch[(i) / PATCHES_PER_PAGE] + (i) % PATCHES_PER_PAGE)

 /* PCM volume control */
 #define TMP_PCM_L     0x100 //temp PCM L (after the vol control)
 #define TMP_PCM_R     0x101
 #define VOL_PCM_L     0x102 //vol PCM
 #define VOL_PCM_R     0x103

 /* Routing patch */
 #define TMP_AC_L      0x104 //tmp ac97 out
 #define TMP_AC_R      0x105
 #define TMP_REAR_L    0x106 //output - Temp Rear
 #define TMP_REAR_R    0x107
 #define TMP_DIGI_L    0x108 //output - Temp digital
 #define TMP_DIGI_R    0x109
 #define DSP_VOL_L     0x10a // main dsp volume
 #define DSP_VOL_R     0x10b

 /* hw inputs */
 #define PCM_IN_L 	0x00
 #define PCM_IN_R 	0x01

 #define PCM1_IN_L        0x04
 #define PCM1_IN_R        0x05
 //mutilchannel playback stream appear here:

 #define MULTI_FRONT_L	0x08
 #define MULTI_FRONT_R	0x09
 #define MULTI_REAR_L	0x0a
 #define MULTI_REAR_R	0x0b
 #define MULTI_CENTER	0x0c
 #define MULTI_LFE	0x0d

 #define AC97_IN_L	0x10
 #define AC97_IN_R	0x11
 #define SPDIF_CD_L	0x12
 #define SPDIF_CD_R	0x13

 /* hw outputs */
 #define AC97_FRONT_L	0x20
 #define AC97_FRONT_R	0x21
 #define DIGITAL_OUT_L	0x22
 #define DIGITAL_OUT_R	0x23
 #define DIGITAL_CENTER	0x24
 #define DIGITAL_LFE	0x25

 #define ANALOG_REAR_L	0x28
 #define ANALOG_REAR_R	0x29
 #define ADC_REC_L	0x2a
 #define ADC_REC_R	0x2b

 #define ANALOG_CENTER	0x31
 #define ANALOG_LFE	0x32


 #define INPUT_PATCH_START(patch, nm, ln, i)		\
 do {							\
 	patch = PATCH(mgr, patch_n);			\
 	strcpy(patch->name, nm);			\
 	patch->code_start = pc * 2;			\
 	patch->input = (1<<(0x1f&ln));			\
 	patch->output= (1<<(0x1f&ln));			\
 	patch->id = i;					\
 } while(0)

 #define INPUT_PATCH_END(patch)				\
 do {							\
 	patch->code_size = pc * 2 - patch->code_start;	\
 	patch_n++;					\
 } while(0)


 #define ROUTING_PATCH_START(patch, nm)	\
 do {					\
 	patch = &mgr->rpatch;		\
 	strcpy(patch->name, nm);	\
 	patch->code_start = pc * 2;	\
 } while(0)

 #define ROUTING_PATCH_END(patch)			\
 do {                                                    \
 	patch->code_size = pc * 2 - patch->code_start;      \
 } while(0)

 #define CONNECT(input, output) set_bit(input, &rpatch->route[(output) - OUTPUT_BASE]);

 #define CONNECT_V(input, output) set_bit(input, &rpatch->route_v[(output) - OUTPUT_BASE]);

 #define OUTPUT_PATCH_START(patch, nm, ln, i)		\
 do {							\
 	patch = PATCH(mgr, patch_n);			\
 	strcpy(patch->name, nm);			\
 	patch->code_start = pc * 2;			\
 	patch->input = (1<<(0x1f&ln));			\
 	patch->output= (1<<(0x1f&ln));			\
 	patch->id = i;					\
 } while(0)

 #define OUTPUT_PATCH_END(patch)				\
 do {							\
 	patch->code_size = pc * 2 - patch->code_start;	\
 	patch_n++;					\
 } while(0)

 #define GET_OUTPUT_GPR(patch, g, ln)			\
 do {							\
 	mgr->gpr[(g) - GPR_BASE].type = GPR_TYPE_IO;	\
 	mgr->gpr[(g) - GPR_BASE].usage++;		\
 	mgr->gpr[(g) - GPR_BASE].line = ln;		\
 	set_bit((g) - GPR_BASE, patch->gpr_used);	\
 } while(0)

 #define GET_INPUT_GPR(patch, g, ln)			\
 do {							\
 	mgr->gpr[(g) - GPR_BASE].type = GPR_TYPE_IO;	\
 	mgr->gpr[(g) - GPR_BASE].usage++;		\
 	mgr->gpr[(g) - GPR_BASE].line = ln;		\
 	set_bit((g) - GPR_BASE, patch->gpr_used);	\
 	set_bit((g) - GPR_BASE, patch->gpr_input);	\
 } while(0)

 #define GET_DYNAMIC_GPR(patch, g)				\
 do {								\
 	mgr->gpr[(g) - GPR_BASE].type = GPR_TYPE_DYNAMIC;	\
 	mgr->gpr[(g) - GPR_BASE].usage++;			\
 	set_bit((g) - GPR_BASE, patch->gpr_used);          	\
 } while(0)

 #define GET_CONTROL_GPR(patch, g, nm, a, b)			\
 do {								\
 	strcpy(mgr->gpr[(g) - GPR_BASE].name, nm);		\
 	mgr->gpr[(g) - GPR_BASE].type = GPR_TYPE_CONTROL;	\
 	mgr->gpr[(g) - GPR_BASE].usage++;			\
 	mgr->gpr[(g) - GPR_BASE].min = a;			\
 	mgr->gpr[(g) - GPR_BASE].max = b;			\
 	sblive_writeptr(card, g, 0, b);				\
 	set_bit((g) - GPR_BASE, patch->gpr_used);		\
 } while(0)

 #endif /* _EFXMGR_H */
	/*
	**********************************************************************
	* sblive_fx.h
	* Copyright 1999, 2000 Creative Labs, Inc.
	*
	**********************************************************************
	*
	* Date Author Summary of changes
	* ---- ------ ------------------
	* October 20, 1999 Bertrand Lee base code release
	*
	**********************************************************************
	*
	* This program is free software; you can redistribute it and/or
	* modify it under the terms of the GNU General Public License as
	* published by the Free Software Foundation; either version 2 of
	* the License, or (at your option) any later version.
	*
	* This program 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 program; if not, write to the Free
	* Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139,
	* USA.
	*
	**********************************************************************
	*/

	#ifndef _EFXMGR_H
	#define _EFXMGR_H

	struct emu_efx_info_t{
	int opcode_shift;
	int high_operand_shift;
	int instruction_start;
	int gpr_base;
	int output_base;
	};


	#define WRITE_EFX(a, b, c) sblive_writeptr((a), emu_efx_info[card->is_audigy].instruction_start + (b), 0, (c))

	#define OP(op, z, w, x, y) \
	do { WRITE_EFX(card, (pc) * 2, ((x) << emu_efx_info[card->is_audigy].high_operand_shift) \| (y)); \
	WRITE_EFX(card, (pc) * 2 + 1, ((op) << emu_efx_info[card->is_audigy].opcode_shift ) \| ((z) << emu_efx_info[card->is_audigy].high_operand_shift) \| (w)); \
	++pc; } while (0)

	#define NUM_INPUTS 0x20
	#define NUM_OUTPUTS 0x20
	#define NUM_GPRS 0x100

	#define A_NUM_INPUTS 0x60
	#define A_NUM_OUTPUTS 0x60 //fixme: this may or may not be true
	#define A_NUM_GPRS 0x200

	#define GPR_NAME_SIZE 32
	#define PATCH_NAME_SIZE 32

	struct dsp_rpatch {
	char name[PATCH_NAME_SIZE];
	u16 code_start;
	u16 code_size;

	unsigned long gpr_used[NUM_GPRS / (sizeof(unsigned long) * 8) + 1];
	unsigned long gpr_input[NUM_GPRS / (sizeof(unsigned long) * 8) + 1];
	unsigned long route[NUM_OUTPUTS];
	unsigned long route_v[NUM_OUTPUTS];
	};

	struct dsp_patch {
	char name[PATCH_NAME_SIZE];
	u8 id;
	unsigned long input; /* bitmap of the lines used as inputs */
	unsigned long output; /* bitmap of the lines used as outputs */
	u16 code_start;
	u16 code_size;

	unsigned long gpr_used[NUM_GPRS / (sizeof(unsigned long) * 8) + 1]; /* bitmap of used gprs */
	unsigned long gpr_input[NUM_GPRS / (sizeof(unsigned long) * 8) + 1];
	u8 traml_istart; /* starting address of the internal tram lines used */
	u8 traml_isize; /* number of internal tram lines used */

	u8 traml_estart;
	u8 traml_esize;

	u16 tramb_istart; /* starting address of the internal tram memory used */
	u16 tramb_isize; /* amount of internal memory used */
	u32 tramb_estart;
	u32 tramb_esize;
	};

	struct dsp_gpr {
	u8 type; /* gpr type, STATIC, DYNAMIC, INPUT, OUTPUT, CONTROL */
	char name[GPR_NAME_SIZE]; /* gpr value, only valid for control gprs */
	s32 min, max; /* value range for this gpr, only valid for control gprs */
	u8 line; /* which input/output line is the gpr attached, only valid for input/output gprs */
	u8 usage;
	};

	enum {
	GPR_TYPE_NULL = 0,
	GPR_TYPE_IO,
	GPR_TYPE_STATIC,
	GPR_TYPE_DYNAMIC,
	GPR_TYPE_CONTROL,
	GPR_TYPE_CONSTANT
	};

	#define GPR_BASE 0x100
	#define OUTPUT_BASE 0x20

	#define A_GPR_BASE 0x400
	#define A_OUTPUT_BASE 0x60

	#define MAX_PATCHES_PAGES 32

	struct patch_manager {
	void *patch[MAX_PATCHES_PAGES];
	int current_pages;
	struct dsp_rpatch rpatch;
	struct dsp_gpr gpr[NUM_GPRS]; /* gpr usage table */
	spinlock_t lock;
	s16 ctrl_gpr[SOUND_MIXER_NRDEVICES][2];
	};

	#define PATCHES_PER_PAGE (PAGE_SIZE / sizeof(struct dsp_patch))

	#define PATCH(mgr, i) ((struct dsp_patch *) (mgr)->patch[(i) / PATCHES_PER_PAGE] + (i) % PATCHES_PER_PAGE)

	/* PCM volume control */
	#define TMP_PCM_L 0x100 //temp PCM L (after the vol control)
	#define TMP_PCM_R 0x101
	#define VOL_PCM_L 0x102 //vol PCM
	#define VOL_PCM_R 0x103

	/* Routing patch */
	#define TMP_AC_L 0x104 //tmp ac97 out
	#define TMP_AC_R 0x105
	#define TMP_REAR_L 0x106 //output - Temp Rear
	#define TMP_REAR_R 0x107
	#define TMP_DIGI_L 0x108 //output - Temp digital
	#define TMP_DIGI_R 0x109
	#define DSP_VOL_L 0x10a // main dsp volume
	#define DSP_VOL_R 0x10b

	/* hw inputs */
	#define PCM_IN_L 0x00
	#define PCM_IN_R 0x01

	#define PCM1_IN_L 0x04
	#define PCM1_IN_R 0x05
	//mutilchannel playback stream appear here:

	#define MULTI_FRONT_L 0x08
	#define MULTI_FRONT_R 0x09
	#define MULTI_REAR_L 0x0a
	#define MULTI_REAR_R 0x0b
	#define MULTI_CENTER 0x0c
	#define MULTI_LFE 0x0d

	#define AC97_IN_L 0x10
	#define AC97_IN_R 0x11
	#define SPDIF_CD_L 0x12
	#define SPDIF_CD_R 0x13

	/* hw outputs */
	#define AC97_FRONT_L 0x20
	#define AC97_FRONT_R 0x21
	#define DIGITAL_OUT_L 0x22
	#define DIGITAL_OUT_R 0x23
	#define DIGITAL_CENTER 0x24
	#define DIGITAL_LFE 0x25

	#define ANALOG_REAR_L 0x28
	#define ANALOG_REAR_R 0x29
	#define ADC_REC_L 0x2a
	#define ADC_REC_R 0x2b

	#define ANALOG_CENTER 0x31
	#define ANALOG_LFE 0x32


	#define INPUT_PATCH_START(patch, nm, ln, i) \
	do { \
	patch = PATCH(mgr, patch_n); \
	strcpy(patch->name, nm); \
	patch->code_start = pc * 2; \
	patch->input = (1<<(0x1f&ln)); \
	patch->output= (1<<(0x1f&ln)); \
	patch->id = i; \
	} while(0)

	#define INPUT_PATCH_END(patch) \
	do { \
	patch->code_size = pc * 2 - patch->code_start; \
	patch_n++; \
	} while(0)


	#define ROUTING_PATCH_START(patch, nm) \
	do { \
	patch = &mgr->rpatch; \
	strcpy(patch->name, nm); \
	patch->code_start = pc * 2; \
	} while(0)

	#define ROUTING_PATCH_END(patch) \
	do { \
	patch->code_size = pc * 2 - patch->code_start; \
	} while(0)

	#define CONNECT(input, output) set_bit(input, &rpatch->route[(output) - OUTPUT_BASE]);

	#define CONNECT_V(input, output) set_bit(input, &rpatch->route_v[(output) - OUTPUT_BASE]);

	#define OUTPUT_PATCH_START(patch, nm, ln, i) \
	do { \
	patch = PATCH(mgr, patch_n); \
	strcpy(patch->name, nm); \
	patch->code_start = pc * 2; \
	patch->input = (1<<(0x1f&ln)); \
	patch->output= (1<<(0x1f&ln)); \
	patch->id = i; \
	} while(0)

	#define OUTPUT_PATCH_END(patch) \
	do { \
	patch->code_size = pc * 2 - patch->code_start; \
	patch_n++; \
	} while(0)

	#define GET_OUTPUT_GPR(patch, g, ln) \
	do { \
	mgr->gpr[(g) - GPR_BASE].type = GPR_TYPE_IO; \
	mgr->gpr[(g) - GPR_BASE].usage++; \
	mgr->gpr[(g) - GPR_BASE].line = ln; \
	set_bit((g) - GPR_BASE, patch->gpr_used); \
	} while(0)

	#define GET_INPUT_GPR(patch, g, ln) \
	do { \
	mgr->gpr[(g) - GPR_BASE].type = GPR_TYPE_IO; \
	mgr->gpr[(g) - GPR_BASE].usage++; \
	mgr->gpr[(g) - GPR_BASE].line = ln; \
	set_bit((g) - GPR_BASE, patch->gpr_used); \
	set_bit((g) - GPR_BASE, patch->gpr_input); \
	} while(0)

	#define GET_DYNAMIC_GPR(patch, g) \
	do { \
	mgr->gpr[(g) - GPR_BASE].type = GPR_TYPE_DYNAMIC; \
	mgr->gpr[(g) - GPR_BASE].usage++; \
	set_bit((g) - GPR_BASE, patch->gpr_used); \
	} while(0)

	#define GET_CONTROL_GPR(patch, g, nm, a, b) \
	do { \
	strcpy(mgr->gpr[(g) - GPR_BASE].name, nm); \
	mgr->gpr[(g) - GPR_BASE].type = GPR_TYPE_CONTROL; \
	mgr->gpr[(g) - GPR_BASE].usage++; \
	mgr->gpr[(g) - GPR_BASE].min = a; \
	mgr->gpr[(g) - GPR_BASE].max = b; \
	sblive_writeptr(card, g, 0, b); \
	set_bit((g) - GPR_BASE, patch->gpr_used); \
	} while(0)

	#endif /* _EFXMGR_H */