/* SDL_mixer: An audio mixer library based on the SDL library Copyright (C) 1997-2017 Sam Lantinga This software is provided 'as-is', without any express or implied warranty. In no event will the authors be held liable for any damages arising from the use of this software. Permission is granted to anyone to use this software for any purpose, including commercial applications, and to alter it and redistribute it freely, subject to the following restrictions: 1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required. 2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software. 3. This notice may not be removed or altered from any source distribution. This file by Ryan C. Gordon (icculus@icculus.org) These are some internally supported special effects that use SDL_mixer's effect callback API. They are meant for speed over quality. :) */ /* $Id$ */ #include #include #include #include "SDL.h" #include "SDL_endian.h" #include "SDL_mixer.h" #include "mixer.h" #define __MIX_INTERNAL_EFFECT__ #include "effects_internal.h" /* profile code: #include #include struct timeval tv1; struct timeval tv2; gettimeofday(&tv1, NULL); ... do your thing here ... gettimeofday(&tv2, NULL); printf("%ld\n", tv2.tv_usec - tv1.tv_usec); */ /* * Positional effects...panning, distance attenuation, etc. */ typedef struct _Eff_positionargs { volatile float left_f; volatile float right_f; volatile Uint8 left_u8; volatile Uint8 right_u8; volatile float left_rear_f; volatile float right_rear_f; volatile float center_f; volatile float lfe_f; volatile Uint8 left_rear_u8; volatile Uint8 right_rear_u8; volatile Uint8 center_u8; volatile Uint8 lfe_u8; volatile float distance_f; volatile Uint8 distance_u8; volatile Sint16 room_angle; volatile int in_use; volatile int channels; } position_args; static position_args **pos_args_array = NULL; static position_args *pos_args_global = NULL; static int position_channels = 0; void _Eff_PositionDeinit(void) { int i; for (i = 0; i < position_channels; i++) { SDL_free(pos_args_array[i]); } position_channels = 0; SDL_free(pos_args_global); pos_args_global = NULL; SDL_free(pos_args_array); pos_args_array = NULL; } /* This just frees up the callback-specific data. */ static void _Eff_PositionDone(int channel, void *udata) { if (channel < 0) { if (pos_args_global != NULL) { SDL_free(pos_args_global); pos_args_global = NULL; } } else if (pos_args_array[channel] != NULL) { SDL_free(pos_args_array[channel]); pos_args_array[channel] = NULL; } } static void _Eff_position_u8(int chan, void *stream, int len, void *udata) { volatile position_args *args = (volatile position_args *) udata; Uint8 *ptr = (Uint8 *) stream; int i; /* * if there's only a mono channnel (the only way we wouldn't have * a len divisible by 2 here), then left_f and right_f are always * 1.0, and are therefore throwaways. */ if (len % sizeof (Uint16) != 0) { *ptr = (Uint8) (((float) *ptr) * args->distance_f); ptr++; len--; } if (args->room_angle == 180) for (i = 0; i < len; i += sizeof (Uint8) * 2) { /* must adjust the sample so that 0 is the center */ *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_f) * args->distance_f) + 128); ptr++; } else for (i = 0; i < len; i += sizeof (Uint8) * 2) { /* must adjust the sample so that 0 is the center */ *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_f) * args->distance_f) + 128); ptr++; } } static void _Eff_position_u8_c4(int chan, void *stream, int len, void *udata) { volatile position_args *args = (volatile position_args *) udata; Uint8 *ptr = (Uint8 *) stream; int i; /* * if there's only a mono channnel (the only way we wouldn't have * a len divisible by 2 here), then left_f and right_f are always * 1.0, and are therefore throwaways. */ if (len % sizeof (Uint16) != 0) { *ptr = (Uint8) (((float) *ptr) * args->distance_f); ptr++; len--; } if (args->room_angle == 0) for (i = 0; i < len; i += sizeof (Uint8) * 6) { /* must adjust the sample so that 0 is the center */ *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_rear_f) * args->distance_f) + 128); ptr++; } else if (args->room_angle == 90) for (i = 0; i < len; i += sizeof (Uint8) * 6) { /* must adjust the sample so that 0 is the center */ *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_rear_f) * args->distance_f) + 128); ptr++; } else if (args->room_angle == 180) for (i = 0; i < len; i += sizeof (Uint8) * 6) { /* must adjust the sample so that 0 is the center */ *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_f) * args->distance_f) + 128); ptr++; } else if (args->room_angle == 270) for (i = 0; i < len; i += sizeof (Uint8) * 6) { /* must adjust the sample so that 0 is the center */ *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_f) * args->distance_f) + 128); ptr++; } } static void _Eff_position_u8_c6(int chan, void *stream, int len, void *udata) { volatile position_args *args = (volatile position_args *) udata; Uint8 *ptr = (Uint8 *) stream; int i; /* * if there's only a mono channnel (the only way we wouldn't have * a len divisible by 2 here), then left_f and right_f are always * 1.0, and are therefore throwaways. */ if (len % sizeof (Uint16) != 0) { *ptr = (Uint8) (((float) *ptr) * args->distance_f); ptr++; len--; } if (args->room_angle == 0) for (i = 0; i < len; i += sizeof (Uint8) * 6) { /* must adjust the sample so that 0 is the center */ *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->center_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->lfe_f) * args->distance_f) + 128); ptr++; } else if (args->room_angle == 90) for (i = 0; i < len; i += sizeof (Uint8) * 6) { /* must adjust the sample so that 0 is the center */ *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_rear_f) * args->distance_f/2) + 128) + (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_f) * args->distance_f/2) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->lfe_f) * args->distance_f) + 128); ptr++; } else if (args->room_angle == 180) for (i = 0; i < len; i += sizeof (Uint8) * 6) { /* must adjust the sample so that 0 is the center */ *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_rear_f) * args->distance_f/2) + 128) + (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_rear_f) * args->distance_f/2) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->lfe_f) * args->distance_f) + 128); ptr++; } else if (args->room_angle == 270) for (i = 0; i < len; i += sizeof (Uint8) * 6) { /* must adjust the sample so that 0 is the center */ *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_rear_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->right_f) * args->distance_f) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_f) * args->distance_f/2) + 128) + (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->left_rear_f) * args->distance_f/2) + 128); ptr++; *ptr = (Uint8) ((Sint8) ((((float) (Sint8) (*ptr - 128)) * args->lfe_f) * args->distance_f) + 128); ptr++; } } /* * This one runs about 10.1 times faster than the non-table version, with * no loss in quality. It does, however, require 64k of memory for the * lookup table. Also, this will only update position information once per * call; the non-table version always checks the arguments for each sample, * in case the user has called Mix_SetPanning() or whatnot again while this * callback is running. */ static void _Eff_position_table_u8(int chan, void *stream, int len, void *udata) { volatile position_args *args = (volatile position_args *) udata; Uint8 *ptr = (Uint8 *) stream; Uint32 *p; int i; Uint8 *l = ((Uint8 *) _Eff_volume_table) + (256 * args->left_u8); Uint8 *r = ((Uint8 *) _Eff_volume_table) + (256 * args->right_u8); Uint8 *d = ((Uint8 *) _Eff_volume_table) + (256 * args->distance_u8); if (args->room_angle == 180) { Uint8 *temp = l; l = r; r = temp; } /* * if there's only a mono channnel, then l[] and r[] are always * volume 255, and are therefore throwaways. Still, we have to * be sure not to overrun the audio buffer... */ while (len % sizeof (Uint32) != 0) { *ptr = d[l[*ptr]]; ptr++; if (args->channels > 1) { *ptr = d[r[*ptr]]; ptr++; } len -= args->channels; } p = (Uint32 *) ptr; for (i = 0; i < len; i += sizeof (Uint32)) { #if (SDL_BYTEORDER == SDL_BIG_ENDIAN) *p = (d[l[(*p & 0xFF000000) >> 24]] << 24) | (d[r[(*p & 0x00FF0000) >> 16]] << 16) | (d[l[(*p & 0x0000FF00) >> 8]] << 8) | (d[r[(*p & 0x000000FF) ]] ) ; #else *p = (d[r[(*p & 0xFF000000) >> 24]] << 24) | (d[l[(*p & 0x00FF0000) >> 16]] << 16) | (d[r[(*p & 0x0000FF00) >> 8]] << 8) | (d[l[(*p & 0x000000FF) ]] ) ; #endif ++p; } } static void _Eff_position_s8(int chan, void *stream, int len, void *udata) { volatile position_args *args = (volatile position_args *) udata; Sint8 *ptr = (Sint8 *) stream; int i; /* * if there's only a mono channnel (the only way we wouldn't have * a len divisible by 2 here), then left_f and right_f are always * 1.0, and are therefore throwaways. */ if (len % sizeof (Sint16) != 0) { *ptr = (Sint8) (((float) *ptr) * args->distance_f); ptr++; len--; } if (args->room_angle == 180) for (i = 0; i < len; i += sizeof (Sint8) * 2) { *ptr = (Sint8)((((float) *ptr) * args->right_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_f) * args->distance_f); ptr++; } else for (i = 0; i < len; i += sizeof (Sint8) * 2) { *ptr = (Sint8)((((float) *ptr) * args->left_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_f) * args->distance_f); ptr++; } } static void _Eff_position_s8_c4(int chan, void *stream, int len, void *udata) { volatile position_args *args = (volatile position_args *) udata; Sint8 *ptr = (Sint8 *) stream; int i; /* * if there's only a mono channnel (the only way we wouldn't have * a len divisible by 2 here), then left_f and right_f are always * 1.0, and are therefore throwaways. */ if (len % sizeof (Sint16) != 0) { *ptr = (Sint8) (((float) *ptr) * args->distance_f); ptr++; len--; } for (i = 0; i < len; i += sizeof (Sint8) * 4) { switch (args->room_angle) { case 0: *ptr = (Sint8)((((float) *ptr) * args->left_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_rear_f) * args->distance_f); ptr++; break; case 90: *ptr = (Sint8)((((float) *ptr) * args->right_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_rear_f) * args->distance_f); ptr++; break; case 180: *ptr = (Sint8)((((float) *ptr) * args->right_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_f) * args->distance_f); ptr++; break; case 270: *ptr = (Sint8)((((float) *ptr) * args->left_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_f) * args->distance_f); ptr++; break; } } } static void _Eff_position_s8_c6(int chan, void *stream, int len, void *udata) { volatile position_args *args = (volatile position_args *) udata; Sint8 *ptr = (Sint8 *) stream; int i; /* * if there's only a mono channnel (the only way we wouldn't have * a len divisible by 2 here), then left_f and right_f are always * 1.0, and are therefore throwaways. */ if (len % sizeof (Sint16) != 0) { *ptr = (Sint8) (((float) *ptr) * args->distance_f); ptr++; len--; } for (i = 0; i < len; i += sizeof (Sint8) * 6) { switch (args->room_angle) { case 0: *ptr = (Sint8)((((float) *ptr) * args->left_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->center_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->lfe_f) * args->distance_f); ptr++; break; case 90: *ptr = (Sint8)((((float) *ptr) * args->right_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_rear_f) * args->distance_f / 2) + (Sint8)((((float) *ptr) * args->right_f) * args->distance_f / 2); ptr++; *ptr = (Sint8)((((float) *ptr) * args->lfe_f) * args->distance_f); ptr++; break; case 180: *ptr = (Sint8)((((float) *ptr) * args->right_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_rear_f) * args->distance_f / 2) + (Sint8)((((float) *ptr) * args->left_rear_f) * args->distance_f / 2); ptr++; *ptr = (Sint8)((((float) *ptr) * args->lfe_f) * args->distance_f); ptr++; break; case 270: *ptr = (Sint8)((((float) *ptr) * args->left_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_rear_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->right_f) * args->distance_f); ptr++; *ptr = (Sint8)((((float) *ptr) * args->left_f) * args->distance_f / 2) + (Sint8)((((float) *ptr) * args->left_rear_f) * args->distance_f / 2); ptr++; *ptr = (Sint8)((((float) *ptr) * args->lfe_f) * args->distance_f); ptr++; break; } } } /* * This one runs about 10.1 times faster than the non-table version, with * no loss in quality. It does, however, require 64k of memory for the * lookup table. Also, this will only update position information once per * call; the non-table version always checks the arguments for each sample, * in case the user has called Mix_SetPanning() or whatnot again while this * callback is running. */ static void _Eff_position_table_s8(int chan, void *stream, int len, void *udata) { volatile position_args *args = (volatile position_args *) udata; Sint8 *ptr = (Sint8 *) stream; Uint32 *p; int i; Sint8 *l = ((Sint8 *) _Eff_volume_table) + (256 * args->left_u8); Sint8 *r = ((Sint8 *) _Eff_volume_table) + (256 * args->right_u8); Sint8 *d = ((Sint8 *) _Eff_volume_table) + (256 * args->distance_u8); if (args->room_angle == 180) { Sint8 *temp = l; l = r; r = temp; } while (len % sizeof (Uint32) != 0) { *ptr = d[l[*ptr]]; ptr++; if (args->channels > 1) { *ptr = d[r[*ptr]]; ptr++; } len -= args->channels; } p = (Uint32 *) ptr; for (i = 0; i < len; i += sizeof (Uint32)) { #if (SDL_BYTEORDER == SDL_BIG_ENDIAN) *p = (d[l[((Sint16)(Sint8)((*p & 0xFF000000) >> 24))+128]] << 24) | (d[r[((Sint16)(Sint8)((*p & 0x00FF0000) >> 16))+128]] << 16) | (d[l[((Sint16)(Sint8)((*p & 0x0000FF00) >> 8))+128]] << 8) | (d[r[((Sint16)(Sint8)((*p & 0x000000FF) ))+128]] ) ; #else *p = (d[r[((Sint16)(Sint8)((*p & 0xFF000000) >> 24))+128]] << 24) | (d[l[((Sint16)(Sint8)((*p & 0x00FF0000) >> 16))+128]] << 16) | (d[r[((Sint16)(Sint8)((*p & 0x0000FF00) >> 8))+128]] << 8) | (d[l[((Sint16)(Sint8)((*p & 0x000000FF) ))+128]] ) ; #endif ++p; } } /* !!! FIXME : Optimize the code for 16-bit samples? */ static void _Eff_position_u16lsb(int chan, void *stream, int len, void *udata) { volatile position_args *args = (volatile position_args *) udata; Uint16 *ptr = (Uint16 *) stream; int i; for (i = 0; i < len; i += sizeof (Uint16) * 2) { Sint16 sampl = (Sint16) (SDL_SwapLE16(*(ptr+0)) - 32768); Sint16 sampr = (Sint16) (SDL_SwapLE16(*(ptr+1)) - 32768); Uint16 swapl = (Uint16) ((Sint16) (((float) sampl * args->left_f) * args->distance_f) + 32768); Uint16 swapr = (Uint16) ((Sint16) (((float) sampr * args->right_f) * args->distance_f) + 32768); if (args->room_angle == 180) { *(ptr++) = (Uint16) SDL_SwapLE16(swapr); *(ptr++) = (Uint16) SDL_SwapLE16(swapl); } else { *(ptr++) = (Uint16) SDL_SwapLE16(swapl); *(ptr++) = (Uint16) SDL_SwapLE16(swapr); } } } static void _Eff_position_u16lsb_c4(int chan, void *stream, int len, void *udata) { volatile position_args *args = (volatile position_args *) udata; Uint16 *ptr = (Uint16 *) stream; int i; for (i = 0; i < len; i += sizeof (Uint16) * 4) { Sint16 sampl = (Sint16) (SDL_SwapLE16(*(ptr+0)) - 32768); Sint16 sampr = (Sint16) (SDL_SwapLE16(*(ptr+1)) - 32768); Sint16 samplr = (Sint16) (SDL_SwapLE16(*(ptr+2)) - 32768); Sint16 samprr = (Sint16) (SDL_SwapLE16(*(ptr+3)) - 32768); Uint16 swapl = (Uint16) ((Sint16) (((float) sampl * args->left_f) * args->distance_f) + 32768); Uint16 swapr = (Uint16) ((Sint16) (((float) sampr * args->right_f) * args->distance_f) + 32768); Uint16 swaplr = (Uint16) ((Sint16) (((float) samplr * args->left_rear_f) * args->distance_f) + 32768); Uint16 swaprr = (Uint16) ((Sint16) (((float) samprr * args->right_rear_f) * args->distance_f) + 32768); switch (args->room_angle) { case 0: *(ptr++) = (Uint16) SDL_SwapLE16(swapl); *(ptr++) = (Uint16) SDL_SwapLE16(swapr); *(ptr++) = (Uint16) SDL_SwapLE16(swaplr); *(ptr++) = (Uint16) SDL_SwapLE16(swaprr); break; case 90: *(ptr++) = (Uint16) SDL_SwapLE16(swapr); *(ptr++) = (Uint16) SDL_SwapLE16(swaprr); *(ptr++) = (Uint16) SDL_SwapLE16(swapl); *(ptr++) = (Uint16) SDL_SwapLE16(swaplr); break; case 180: *(ptr++) = (Uint16) SDL_SwapLE16(swaprr); *(ptr++) = (Uint16) SDL_SwapLE16(swaplr); *(ptr++) = (Uint16) SDL_SwapLE16(swapr); *(ptr++) = (Uint16) SDL_SwapLE16(swapl); break; case 270: *(ptr++) = (Uint16) SDL_SwapLE16(swaplr); *(ptr++) = (Uint16) SDL_SwapLE16(swapl); *(ptr++) = (Uint16) SDL_SwapLE16(swaprr); *(ptr++) = (Uint16) SDL_SwapLE16(swapr); break; } } } static void _Eff_position_u16lsb_c6(int chan, void *stream, int len, void *udata) { volatile position_args *args = (volatile position_args *) udata; Uint16 *ptr = (Uint16 *) stream; int i; for (i = 0; i < len; i += sizeof (Uint16) * 6) { Sint16 sampl = (Sint16) (SDL_SwapLE16(*(ptr+0)) - 32768); Sint16 sampr = (Sint16) (SDL_SwapLE16(*(ptr+1)) - 32768); Sint16 samplr = (Sint16) (SDL_SwapLE16(*(ptr+2)) - 32768); Sint16 samprr = (Sint16) (SDL_SwapLE16(*(ptr+3)) - 32768); Sint16 sampce = (Sint16) (SDL_SwapLE16(*(ptr+4)) - 32768); Sint16 sampwf = (Sint16) (SDL_SwapLE16(*(ptr+5)) - 32768); Uint16 swapl = (Uint16) ((Sint16) (((float) sampl * args->left_f) * args->distance_f) + 32768); Uint16 swapr = (Uint16) ((Sint16) (((float) sampr * args->right_f) * args->distance_f) + 32768); Uint16 swaplr = (Uint16) ((Sint16) (((float) samplr * args->left_rear_f) * args->distance_f) + 32768); Uint16 swaprr = (Uint16) ((Sint16) (((float) samprr * args->right_rear_f) * args->distance_f) + 32768); Uint16 swapce = (Uint16) ((Sint16) (((float) sampce * args->center_f) * args->distance_f) + 32768); Uint16 swapwf = (Uint16) ((Sint16) (((float) sampwf * args->lfe_f) * args->distance_f) + 32768); switch (args->room_angle) { case 0: *(ptr++) = (Uint16) SDL_SwapLE16(swapl); *(ptr++) = (Uint16) SDL_SwapLE16(swapr); *(ptr++) = (Uint16) SDL_SwapLE16(swaplr); *(ptr++) = (Uint16) SDL_SwapLE16(swaprr); *(ptr++) = (Uint16) SDL_SwapLE16(swapce); *(ptr++) = (Uint16) SDL_SwapLE16(swapwf); break; case 90: *(ptr++) = (Uint16) SDL_SwapLE16(swapr); *(ptr++) = (Uint16) SDL_SwapLE16(swaprr); *(ptr++) = (Uint16) SDL_SwapLE16(swapl); *(ptr++) = (Uint16) SDL_SwapLE16(swaplr); *(ptr++) = (Uint16) SDL_SwapLE16(swapr)/2 + (Uint16) SDL_SwapLE16(swaprr)/2; *(ptr++) = (Uint16) SDL_SwapLE16(swapwf); break; case 180: *(ptr++) = (Uint16) SDL_SwapLE16(swaprr); *(ptr++) = (Uint16) SDL_SwapLE16(swaplr); *(ptr++) = (Uint16) SDL_SwapLE16(swapr); *(ptr++) = (Uint16) SDL_SwapLE16(swapl); *(ptr++) = (Uint16) SDL_SwapLE16(swaprr)/2 + (Uint16) SDL_SwapLE16(swaplr)/2; *(ptr++) = (Uint16) SDL_SwapLE16(swapwf); break; case 270: *(ptr++) = (Uint16) SDL_SwapLE16(swaplr); *(ptr++) = (Uint16) SDL_SwapLE16(swapl); *(ptr++) = (Uint16) SDL_SwapLE16(swaprr); *(ptr++) = (Uint16) SDL_SwapLE16(swapr); *(ptr++) = (Uint16) SDL_SwapLE16(swapl)/2 + (Uint16) SDL_SwapLE16(swaplr)/2; *(ptr++) = (Uint16) SDL_SwapLE16(swapwf); break; } } } static void _Eff_position_s16lsb(int chan, void *stream, int len, void *udata) { /* 16 signed bits (lsb) * 2 channels. */ volatile position_args *args = (volatile position_args *) udata; Sint16 *ptr = (Sint16 *) stream; int i; #if 0 if (len % (sizeof(Sint16) * 2)) { fprintf(stderr,"Not an even number of frames! len=%d\n", len); return; } #endif for (i = 0; i < len; i += sizeof (Sint16) * 2) { Sint16 swapl = (Sint16) ((((float) (Sint16) SDL_SwapLE16(*(ptr+0))) * args->left_f) * args->distance_f); Sint16 swapr = (Sint16) ((((float) (Sint16) SDL_SwapLE16(*(ptr+1))) * args->right_f) * args->distance_f); if (args->room_angle == 180) { *(ptr++) = (Sint16) SDL_SwapLE16(swapr); *(ptr++) = (Sint16) SDL_SwapLE16(swapl); } else { *(ptr++) = (Sint16) SDL_SwapLE16(swapl); *(ptr++) = (Sint16) SDL_SwapLE16(swapr); } } } static void _Eff_position_s16lsb_c4(int chan, void *stream, int len, void *udata) { /* 16 signed bits (lsb) * 4 channels. */ volatile position_args *args = (volatile position_args *) udata; Sint16 *ptr = (Sint16 *) stream; int i; for (i = 0; i < len; i += sizeof (Sint16) * 4) { Sint16 swapl = (Sint16) ((((float) (Sint16) SDL_SwapLE16(*(ptr+0))) * args->left_f) * args->distance_f); Sint16 swapr = (Sint16) ((((float) (Sint16) SDL_SwapLE16(*(ptr+1))) * args->right_f) * args->distance_f); Sint16 swaplr = (Sint16) ((((float) (Sint16) SDL_SwapLE16(*(ptr+1))) * args->left_rear_f) * args->distance_f); Sint16 swaprr = (Sint16) ((((float) (Sint16) SDL_SwapLE16(*(ptr+2))) * args->right_rear_f) * args->distance_f); switch (args->room_angle) { case 0: *(ptr++) = (Sint16) SDL_SwapLE16(swapl); *(ptr++) = (Sint16) SDL_SwapLE16(swapr); *(ptr++) = (Sint16) SDL_SwapLE16(swaplr); *(ptr++) = (Sint16) SDL_SwapLE16(swaprr); break; case 90: *(ptr++) = (Sint16) SDL_SwapLE16(swapr); *(ptr++) = (Sint16) SDL_SwapLE16(swaprr); *(ptr++) = (Sint16) SDL_SwapLE16(swapl); *(ptr++) = (Sint16) SDL_SwapLE16(swaplr); break; case 180: *(ptr++) = (Sint16) SDL_SwapLE16(swaprr); *(ptr++) = (Sint16) SDL_SwapLE16(swaplr); *(ptr++) = (Sint16) SDL_SwapLE16(swapr); *(ptr++) = (Sint16) SDL_SwapLE16(swapl); break; case 270: *(ptr++) = (Sint16) SDL_SwapLE16(swaplr); *(ptr++) = (Sint16) SDL_SwapLE16(swapl); *(ptr++) = (Sint16) SDL_SwapLE16(swaprr); *(ptr++) = (Sint16) SDL_SwapLE16(swapr); break; } } } static void _Eff_position_s16lsb_c6(int chan, void *stream, int len, void *udata) { /* 16 signed bits (lsb) * 6 channels. */ volatile position_args *args = (volatile position_args *) udata; Sint16 *ptr = (Sint16 *) stream; int i; for (i = 0; i < len; i += sizeof (Sint16) * 6) { Sint16 swapl = (Sint16) ((((float) (Sint16) SDL_SwapLE16(*(ptr+0))) * args->left_f) * args->distance_f); Sint16 swapr = (Sint16) ((((float) (Sint16) SDL_SwapLE16(*(ptr+1))) * args->right_f) * args->distance_f); Sint16 swaplr = (Sint16) ((((float) (Sint16) SDL_SwapLE16(*(ptr+2))) * args->left_rear_f) * args->distance_f); Sint16 swaprr = (Sint16) ((((float) (Sint16) SDL_SwapLE16(*(ptr+3))) * args->right_rear_f) * args->distance_f); Sint16 swapce = (Sint16) ((((float) (Sint16) SDL_SwapLE16(*(ptr+4))) * args->center_f) * args->distance_f); Sint16 swapwf = (Sint16) ((((float) (Sint16) SDL_SwapLE16(*(ptr+5))) * args->lfe_f) * args->distance_f); switch (args->room_angle) { case 0: *(ptr++) = (Sint16) SDL_SwapLE16(swapl); *(ptr++) = (Sint16) SDL_SwapLE16(swapr); *(ptr++) = (Sint16) SDL_SwapLE16(swaplr); *(ptr++) = (Sint16) SDL_SwapLE16(swaprr); *(ptr++) = (Sint16) SDL_SwapLE16(swapce); *(ptr++) = (Sint16) SDL_SwapLE16(swapwf); break; case 90: *(ptr++) = (Sint16) SDL_SwapLE16(swapr); *(ptr++) = (Sint16) SDL_SwapLE16(swaprr); *(ptr++) = (Sint16) SDL_SwapLE16(swapl); *(ptr++) = (Sint16) SDL_SwapLE16(swaplr); *(ptr++) = (Sint16) SDL_SwapLE16(swapr)/2 + (Sint16) SDL_SwapLE16(swaprr)/2; *(ptr++) = (Sint16) SDL_SwapLE16(swapwf); break; case 180: *(ptr++) = (Sint16) SDL_SwapLE16(swaprr); *(ptr++) = (Sint16) SDL_SwapLE16(swaplr); *(ptr++) = (Sint16) SDL_SwapLE16(swapr); *(ptr++) = (Sint16) SDL_SwapLE16(swapl); *(ptr++) = (Sint16) SDL_SwapLE16(swaprr)/2 + (Sint16) SDL_SwapLE16(swaplr)/2; *(ptr++) = (Sint16) SDL_SwapLE16(swapwf); break; case 270: *(ptr++) = (Sint16) SDL_SwapLE16(swaplr); *(ptr++) = (Sint16) SDL_SwapLE16(swapl); *(ptr++) = (Sint16) SDL_SwapLE16(swaprr); *(ptr++) = (Sint16) SDL_SwapLE16(swapr); *(ptr++) = (Sint16) SDL_SwapLE16(swapl)/2 + (Sint16) SDL_SwapLE16(swaplr)/2; *(ptr++) = (Sint16) SDL_SwapLE16(swapwf); break; } } } static void _Eff_position_u16msb(int chan, void *stream, int len, void *udata) { /* 16 signed bits (lsb) * 2 channels. */ volatile position_args *args = (volatile position_args *) udata; Uint16 *ptr = (Uint16 *) stream; int i; for (i = 0; i < len; i += sizeof (Sint16) * 2) { Sint16 sampl = (Sint16) (SDL_SwapBE16(*(ptr+0)) - 32768); Sint16 sampr = (Sint16) (SDL_SwapBE16(*(ptr+1)) - 32768); Uint16 swapl = (Uint16) ((Sint16) (((float) sampl * args->left_f) * args->distance_f) + 32768); Uint16 swapr = (Uint16) ((Sint16) (((float) sampr * args->right_f) * args->distance_f) + 32768); if (args->room_angle == 180) { *(ptr++) = (Uint16) SDL_SwapBE16(swapr); *(ptr++) = (Uint16) SDL_SwapBE16(swapl); } else { *(ptr++) = (Uint16) SDL_SwapBE16(swapl); *(ptr++) = (Uint16) SDL_SwapBE16(swapr); } } } static void _Eff_position_u16msb_c4(int chan, void *stream, int len, void *udata) { /* 16 signed bits (lsb) * 4 channels. */ volatile position_args *args = (volatile position_args *) udata; Uint16 *ptr = (Uint16 *) stream; int i; for (i = 0; i < len; i += sizeof (Sint16) * 4) { Sint16 sampl = (Sint16) (SDL_SwapBE16(*(ptr+0)) - 32768); Sint16 sampr = (Sint16) (SDL_SwapBE16(*(ptr+1)) - 32768); Sint16 samplr = (Sint16) (SDL_SwapBE16(*(ptr+2)) - 32768); Sint16 samprr = (Sint16) (SDL_SwapBE16(*(ptr+3)) - 32768); Uint16 swapl = (Uint16) ((Sint16) (((float) sampl * args->left_f) * args->distance_f) + 32768); Uint16 swapr = (Uint16) ((Sint16) (((float) sampr * args->right_f) * args->distance_f) + 32768); Uint16 swaplr = (Uint16) ((Sint16) (((float) samplr * args->left_rear_f) * args->distance_f) + 32768); Uint16 swaprr = (Uint16) ((Sint16) (((float) samprr * args->right_rear_f) * args->distance_f) + 32768); switch (args->room_angle) { case 0: *(ptr++) = (Uint16) SDL_SwapBE16(swapl); *(ptr++) = (Uint16) SDL_SwapBE16(swapr); *(ptr++) = (Uint16) SDL_SwapBE16(swaplr); *(ptr++) = (Uint16) SDL_SwapBE16(swaprr); break; case 90: *(ptr++) = (Uint16) SDL_SwapBE16(swapr); *(ptr++) = (Uint16) SDL_SwapBE16(swaprr); *(ptr++) = (Uint16) SDL_SwapBE16(swapl); *(ptr++) = (Uint16) SDL_SwapBE16(swaplr); break; case 180: *(ptr++) = (Uint16) SDL_SwapBE16(swaprr); *(ptr++) = (Uint16) SDL_SwapBE16(swaplr); *(ptr++) = (Uint16) SDL_SwapBE16(swapr); *(ptr++) = (Uint16) SDL_SwapBE16(swapl); break; case 270: *(ptr++) = (Uint16) SDL_SwapBE16(swaplr); *(ptr++) = (Uint16) SDL_SwapBE16(swapl); *(ptr++) = (Uint16) SDL_SwapBE16(swaprr); *(ptr++) = (Uint16) SDL_SwapBE16(swapr); break; } } } static void _Eff_position_u16msb_c6(int chan, void *stream, int len, void *udata) { /* 16 signed bits (lsb) * 6 channels. */ volatile position_args *args = (volatile position_args *) udata; Uint16 *ptr = (Uint16 *) stream; int i; for (i = 0; i < len; i += sizeof (Sint16) * 6) { Sint16 sampl = (Sint16) (SDL_SwapBE16(*(ptr+0)) - 32768); Sint16 sampr = (Sint16) (SDL_SwapBE16(*(ptr+1)) - 32768); Sint16 samplr = (Sint16) (SDL_SwapBE16(*(ptr+2)) - 32768); Sint16 samprr = (Sint16) (SDL_SwapBE16(*(ptr+3)) - 32768); Sint16 sampce = (Sint16) (SDL_SwapBE16(*(ptr+4)) - 32768); Sint16 sampwf = (Sint16) (SDL_SwapBE16(*(ptr+5)) - 32768); Uint16 swapl = (Uint16) ((Sint16) (((float) sampl * args->left_f) * args->distance_f) + 32768); Uint16 swapr = (Uint16) ((Sint16) (((float) sampr * args->right_f) * args->distance_f) + 32768); Uint16 swaplr = (Uint16) ((Sint16) (((float) samplr * args->left_rear_f) * args->distance_f) + 32768); Uint16 swaprr = (Uint16) ((Sint16) (((float) samprr * args->right_rear_f) * args->distance_f) + 32768); Uint16 swapce = (Uint16) ((Sint16) (((float) sampce * args->center_f) * args->distance_f) + 32768); Uint16 swapwf = (Uint16) ((Sint16) (((float) sampwf * args->lfe_f) * args->distance_f) + 32768); switch (args->room_angle) { case 0: *(ptr++) = (Uint16) SDL_SwapBE16(swapl); *(ptr++) = (Uint16) SDL_SwapBE16(swapr); *(ptr++) = (Uint16) SDL_SwapBE16(swaplr); *(ptr++) = (Uint16) SDL_SwapBE16(swaprr); *(ptr++) = (Uint16) SDL_SwapBE16(swapce); *(ptr++) = (Uint16) SDL_SwapBE16(swapwf); break; case 90: *(ptr++) = (Uint16) SDL_SwapBE16(swapr); *(ptr++) = (Uint16) SDL_SwapBE16(swaprr); *(ptr++) = (Uint16) SDL_SwapBE16(swapl); *(ptr++) = (Uint16) SDL_SwapBE16(swaplr); *(ptr++) = (Uint16) SDL_SwapBE16(swapr)/2 + (Uint16) SDL_SwapBE16(swaprr)/2; *(ptr++) = (Uint16) SDL_SwapBE16(swapwf); break; case 180: *(ptr++) = (Uint16) SDL_SwapBE16(swaprr); *(ptr++) = (Uint16) SDL_SwapBE16(swaplr); *(ptr++) = (Uint16) SDL_SwapBE16(swapr); *(ptr++) = (Uint16) SDL_SwapBE16(swapl); *(ptr++) = (Uint16) SDL_SwapBE16(swaprr)/2 + (Uint16) SDL_SwapBE16(swaplr)/2; *(ptr++) = (Uint16) SDL_SwapBE16(swapwf); break; case 270: *(ptr++) = (Uint16) SDL_SwapBE16(swaplr); *(ptr++) = (Uint16) SDL_SwapBE16(swapl); *(ptr++) = (Uint16) SDL_SwapBE16(swaprr); *(ptr++) = (Uint16) SDL_SwapBE16(swapr); *(ptr++) = (Uint16) SDL_SwapBE16(swapl)/2 + (Uint16) SDL_SwapBE16(swaplr)/2; *(ptr++) = (Uint16) SDL_SwapBE16(swapwf); break; } } } static void _Eff_position_s16msb(int chan, void *stream, int len, void *udata) { /* 16 signed bits (lsb) * 2 channels. */ volatile position_args *args = (volatile position_args *) udata; Sint16 *ptr = (Sint16 *) stream; int i; for (i = 0; i < len; i += sizeof (Sint16) * 2) { Sint16 swapl = (Sint16) ((((float) (Sint16) SDL_SwapBE16(*(ptr+0))) * args->left_f) * args->distance_f); Sint16 swapr = (Sint16) ((((float) (Sint16) SDL_SwapBE16(*(ptr+1))) * args->right_f) * args->distance_f); *(ptr++) = (Sint16) SDL_SwapBE16(swapl); *(ptr++) = (Sint16) SDL_SwapBE16(swapr); } } static void _Eff_position_s16msb_c4(int chan, void *stream, int len, void *udata) { /* 16 signed bits (lsb) * 4 channels. */ volatile position_args *args = (volatile position_args *) udata; Sint16 *ptr = (Sint16 *) stream; int i; for (i = 0; i < len; i += sizeof (Sint16) * 4) { Sint16 swapl = (Sint16) ((((float) (Sint16) SDL_SwapBE16(*(ptr+0))) * args->left_f) * args->distance_f); Sint16 swapr = (Sint16) ((((float) (Sint16) SDL_SwapBE16(*(ptr+1))) * args->right_f) * args->distance_f); Sint16 swaplr = (Sint16) ((((float) (Sint16) SDL_SwapBE16(*(ptr+2))) * args->left_rear_f) * args->distance_f); Sint16 swaprr = (Sint16) ((((float) (Sint16) SDL_SwapBE16(*(ptr+3))) * args->right_rear_f) * args->distance_f); switch (args->room_angle) { case 0: *(ptr++) = (Sint16) SDL_SwapBE16(swapl); *(ptr++) = (Sint16) SDL_SwapBE16(swapr); *(ptr++) = (Sint16) SDL_SwapBE16(swaplr); *(ptr++) = (Sint16) SDL_SwapBE16(swaprr); break; case 90: *(ptr++) = (Sint16) SDL_SwapBE16(swapr); *(ptr++) = (Sint16) SDL_SwapBE16(swaprr); *(ptr++) = (Sint16) SDL_SwapBE16(swapl); *(ptr++) = (Sint16) SDL_SwapBE16(swaplr); break; case 180: *(ptr++) = (Sint16) SDL_SwapBE16(swaprr); *(ptr++) = (Sint16) SDL_SwapBE16(swaplr); *(ptr++) = (Sint16) SDL_SwapBE16(swapr); *(ptr++) = (Sint16) SDL_SwapBE16(swapl); break; case 270: *(ptr++) = (Sint16) SDL_SwapBE16(swaplr); *(ptr++) = (Sint16) SDL_SwapBE16(swapl); *(ptr++) = (Sint16) SDL_SwapBE16(swaprr); *(ptr++) = (Sint16) SDL_SwapBE16(swapr); break; } } } static void _Eff_position_s16msb_c6(int chan, void *stream, int len, void *udata) { /* 16 signed bits (lsb) * 6 channels. */ volatile position_args *args = (volatile position_args *) udata; Sint16 *ptr = (Sint16 *) stream; int i; for (i = 0; i < len; i += sizeof (Sint16) * 6) { Sint16 swapl = (Sint16) ((((float) (Sint16) SDL_SwapBE16(*(ptr+0))) * args->left_f) * args->distance_f); Sint16 swapr = (Sint16) ((((float) (Sint16) SDL_SwapBE16(*(ptr+1))) * args->right_f) * args->distance_f); Sint16 swaplr = (Sint16) ((((float) (Sint16) SDL_SwapBE16(*(ptr+2))) * args->left_rear_f) * args->distance_f); Sint16 swaprr = (Sint16) ((((float) (Sint16) SDL_SwapBE16(*(ptr+3))) * args->right_rear_f) * args->distance_f); Sint16 swapce = (Sint16) ((((float) (Sint16) SDL_SwapBE16(*(ptr+4))) * args->center_f) * args->distance_f); Sint16 swapwf = (Sint16) ((((float) (Sint16) SDL_SwapBE16(*(ptr+5))) * args->lfe_f) * args->distance_f); switch (args->room_angle) { case 0: *(ptr++) = (Sint16) SDL_SwapBE16(swapl); *(ptr++) = (Sint16) SDL_SwapBE16(swapr); *(ptr++) = (Sint16) SDL_SwapBE16(swaplr); *(ptr++) = (Sint16) SDL_SwapBE16(swaprr); *(ptr++) = (Sint16) SDL_SwapBE16(swapce); *(ptr++) = (Sint16) SDL_SwapBE16(swapwf); break; case 90: *(ptr++) = (Sint16) SDL_SwapBE16(swapr); *(ptr++) = (Sint16) SDL_SwapBE16(swaprr); *(ptr++) = (Sint16) SDL_SwapBE16(swapl); *(ptr++) = (Sint16) SDL_SwapBE16(swaplr); *(ptr++) = (Sint16) SDL_SwapBE16(swapr)/2 + (Sint16) SDL_SwapBE16(swaprr)/2; *(ptr++) = (Sint16) SDL_SwapBE16(swapwf); break; case 180: *(ptr++) = (Sint16) SDL_SwapBE16(swaprr); *(ptr++) = (Sint16) SDL_SwapBE16(swaplr); *(ptr++) = (Sint16) SDL_SwapBE16(swapr); *(ptr++) = (Sint16) SDL_SwapBE16(swapl); *(ptr++) = (Sint16) SDL_SwapBE16(swaprr)/2 + (Sint16) SDL_SwapBE16(swaplr)/2; *(ptr++) = (Sint16) SDL_SwapBE16(swapwf); break; case 270: *(ptr++) = (Sint16) SDL_SwapBE16(swaplr); *(ptr++) = (Sint16) SDL_SwapBE16(swapl); *(ptr++) = (Sint16) SDL_SwapBE16(swaprr); *(ptr++) = (Sint16) SDL_SwapBE16(swapr); *(ptr++) = (Sint16) SDL_SwapBE16(swapl)/2 + (Sint16) SDL_SwapBE16(swaplr)/2; *(ptr++) = (Sint16) SDL_SwapBE16(swapwf); break; } } } static void init_position_args(position_args *args) { SDL_memset(args, '\0', sizeof (position_args)); args->in_use = 0; args->room_angle = 0; args->left_u8 = args->right_u8 = args->distance_u8 = 255; args->left_f = args->right_f = args->distance_f = 1.0f; args->left_rear_u8 = args->right_rear_u8 = args->center_u8 = args->lfe_u8 = 255; args->left_rear_f = args->right_rear_f = args->center_f = args->lfe_f = 1.0f; Mix_QuerySpec(NULL, NULL, (int *) &args->channels); } static position_args *get_position_arg(int channel) { void *rc; int i; if (channel < 0) { if (pos_args_global == NULL) { pos_args_global = SDL_malloc(sizeof (position_args)); if (pos_args_global == NULL) { Mix_SetError("Out of memory"); return(NULL); } init_position_args(pos_args_global); } return(pos_args_global); } if (channel >= position_channels) { rc = SDL_realloc(pos_args_array, (channel + 1) * sizeof (position_args *)); if (rc == NULL) { Mix_SetError("Out of memory"); return(NULL); } pos_args_array = (position_args **) rc; for (i = position_channels; i <= channel; i++) { pos_args_array[i] = NULL; } position_channels = channel + 1; } if (pos_args_array[channel] == NULL) { pos_args_array[channel] = (position_args *)SDL_malloc(sizeof(position_args)); if (pos_args_array[channel] == NULL) { Mix_SetError("Out of memory"); return(NULL); } init_position_args(pos_args_array[channel]); } return(pos_args_array[channel]); } static Mix_EffectFunc_t get_position_effect_func(Uint16 format, int channels) { Mix_EffectFunc_t f = NULL; switch (format) { case AUDIO_U8: switch (channels) { case 1: case 2: f = (_Eff_build_volume_table_u8()) ? _Eff_position_table_u8 : _Eff_position_u8; break; case 4: f = _Eff_position_u8_c4; break; case 6: f = _Eff_position_u8_c6; break; default: Mix_SetError("Unsupported audio channels"); break; } break; case AUDIO_S8: switch (channels) { case 1: case 2: f = (_Eff_build_volume_table_s8()) ? _Eff_position_table_s8 : _Eff_position_s8; break; case 4: f = _Eff_position_s8_c4; break; case 6: f = _Eff_position_s8_c6; break; default: Mix_SetError("Unsupported audio channels"); break; } break; case AUDIO_U16LSB: switch (channels) { case 1: case 2: f = _Eff_position_u16lsb; break; case 4: f = _Eff_position_u16lsb_c4; break; case 6: f = _Eff_position_u16lsb_c6; break; default: Mix_SetError("Unsupported audio channels"); break; } break; case AUDIO_S16LSB: switch (channels) { case 1: case 2: f = _Eff_position_s16lsb; break; case 4: f = _Eff_position_s16lsb_c4; break; case 6: f = _Eff_position_s16lsb_c6; break; default: Mix_SetError("Unsupported audio channels"); break; } break; case AUDIO_U16MSB: switch (channels) { case 1: case 2: f = _Eff_position_u16msb; break; case 4: f = _Eff_position_u16msb_c4; break; case 6: f = _Eff_position_u16msb_c6; break; default: Mix_SetError("Unsupported audio channels"); break; } break; case AUDIO_S16MSB: switch (channels) { case 1: case 2: f = _Eff_position_s16msb; break; case 4: f = _Eff_position_s16msb_c4; break; case 6: f = _Eff_position_s16msb_c6; break; default: Mix_SetError("Unsupported audio channels"); break; } break; default: Mix_SetError("Unsupported audio format"); break; } return(f); } static Uint8 speaker_amplitude[6]; static void set_amplitudes(int channels, int angle, int room_angle) { int left = 255, right = 255; int left_rear = 255, right_rear = 255, center = 255; angle = SDL_abs(angle) % 360; /* make angle between 0 and 359. */ if (channels == 2) { /* * We only attenuate by position if the angle falls on the far side * of center; That is, an angle that's due north would not attenuate * either channel. Due west attenuates the right channel to 0.0, and * due east attenuates the left channel to 0.0. Slightly east of * center attenuates the left channel a little, and the right channel * not at all. I think of this as occlusion by one's own head. :) * * ...so, we split our angle circle into four quadrants... */ if (angle < 90) { left = 255 - ((int) (255.0f * (((float) angle) / 89.0f))); } else if (angle < 180) { left = (int) (255.0f * (((float) (angle - 90)) / 89.0f)); } else if (angle < 270) { right = 255 - ((int) (255.0f * (((float) (angle - 180)) / 89.0f))); } else { right = (int) (255.0f * (((float) (angle - 270)) / 89.0f)); } } if (channels == 4 || channels == 6) { /* * An angle that's due north does not attenuate the center channel. * An angle in the first quadrant, 0-90, does not attenuate the RF. * * ...so, we split our angle circle into 8 ... * * CE * 0 * LF | RF * | * 270<-------|----------->90 * | * LR | RR * 180 * */ if (angle < 45) { left = ((int) (255.0f * (((float) (180 - angle)) / 179.0f))); left_rear = 255 - ((int) (255.0f * (((float) (angle + 45)) / 89.0f))); right_rear = 255 - ((int) (255.0f * (((float) (90 - angle)) / 179.0f))); } else if (angle < 90) { center = ((int) (255.0f * (((float) (225 - angle)) / 179.0f))); left = ((int) (255.0f * (((float) (180 - angle)) / 179.0f))); left_rear = 255 - ((int) (255.0f * (((float) (135 - angle)) / 89.0f))); right_rear = ((int) (255.0f * (((float) (90 + angle)) / 179.0f))); } else if (angle < 135) { center = ((int) (255.0f * (((float) (225 - angle)) / 179.0f))); left = 255 - ((int) (255.0f * (((float) (angle - 45)) / 89.0f))); right = ((int) (255.0f * (((float) (270 - angle)) / 179.0f))); left_rear = ((int) (255.0f * (((float) (angle)) / 179.0f))); } else if (angle < 180) { center = 255 - ((int) (255.0f * (((float) (angle - 90)) / 89.0f))); left = 255 - ((int) (255.0f * (((float) (225 - angle)) / 89.0f))); right = ((int) (255.0f * (((float) (270 - angle)) / 179.0f))); left_rear = ((int) (255.0f * (((float) (angle)) / 179.0f))); } else if (angle < 225) { center = 255 - ((int) (255.0f * (((float) (270 - angle)) / 89.0f))); left = ((int) (255.0f * (((float) (angle - 90)) / 179.0f))); right = 255 - ((int) (255.0f * (((float) (angle - 135)) / 89.0f))); right_rear = ((int) (255.0f * (((float) (360 - angle)) / 179.0f))); } else if (angle < 270) { center = ((int) (255.0f * (((float) (angle - 135)) / 179.0f))); left = ((int) (255.0f * (((float) (angle - 90)) / 179.0f))); right = 255 - ((int) (255.0f * (((float) (315 - angle)) / 89.0f))); right_rear = ((int) (255.0f * (((float) (360 - angle)) / 179.0f))); } else if (angle < 315) { center = ((int) (255.0f * (((float) (angle - 135)) / 179.0f))); right = ((int) (255.0f * (((float) (angle - 180)) / 179.0f))); left_rear = ((int) (255.0f * (((float) (450 - angle)) / 179.0f))); right_rear = 255 - ((int) (255.0f * (((float) (angle - 225)) / 89.0f))); } else { right = ((int) (255.0f * (((float) (angle - 180)) / 179.0f))); left_rear = ((int) (255.0f * (((float) (450 - angle)) / 179.0f))); right_rear = 255 - ((int) (255.0f * (((float) (405 - angle)) / 89.0f))); } } if (left < 0) left = 0; if (left > 255) left = 255; if (right < 0) right = 0; if (right > 255) right = 255; if (left_rear < 0) left_rear = 0; if (left_rear > 255) left_rear = 255; if (right_rear < 0) right_rear = 0; if (right_rear > 255) right_rear = 255; if (center < 0) center = 0; if (center > 255) center = 255; if (room_angle == 90) { speaker_amplitude[0] = (Uint8)left_rear; speaker_amplitude[1] = (Uint8)left; speaker_amplitude[2] = (Uint8)right_rear; speaker_amplitude[3] = (Uint8)right; } else if (room_angle == 180) { if (channels == 2) { speaker_amplitude[0] = (Uint8)right; speaker_amplitude[1] = (Uint8)left; } else { speaker_amplitude[0] = (Uint8)right_rear; speaker_amplitude[1] = (Uint8)left_rear; speaker_amplitude[2] = (Uint8)right; speaker_amplitude[3] = (Uint8)left; } } else if (room_angle == 270) { speaker_amplitude[0] = (Uint8)right; speaker_amplitude[1] = (Uint8)right_rear; speaker_amplitude[2] = (Uint8)left; speaker_amplitude[3] = (Uint8)left_rear; } else { speaker_amplitude[0] = (Uint8)left; speaker_amplitude[1] = (Uint8)right; speaker_amplitude[2] = (Uint8)left_rear; speaker_amplitude[3] = (Uint8)right_rear; } speaker_amplitude[4] = (Uint8)center; speaker_amplitude[5] = 255; } int Mix_SetPosition(int channel, Sint16 angle, Uint8 distance); int Mix_SetPanning(int channel, Uint8 left, Uint8 right) { Mix_EffectFunc_t f = NULL; int channels; Uint16 format; position_args *args = NULL; int retval = 1; Mix_QuerySpec(NULL, &format, &channels); if (channels != 2 && channels != 4 && channels != 6) /* it's a no-op; we call that successful. */ return(1); if (channels > 2) { /* left = right = 255 => angle = 0, to unregister effect as when channels = 2 */ /* left = 255 => angle = -90; left = 0 => angle = +89 */ int angle = 0; if ((left != 255) || (right != 255)) { angle = (int)left; angle = 127 - angle; angle = -angle; angle = angle * 90 / 128; /* Make it larger for more effect? */ } return( Mix_SetPosition(channel, angle, 0) ); } f = get_position_effect_func(format, channels); if (f == NULL) return(0); Mix_LockAudio(); args = get_position_arg(channel); if (!args) { Mix_UnlockAudio(); return(0); } /* it's a no-op; unregister the effect, if it's registered. */ if ((args->distance_u8 == 255) && (left == 255) && (right == 255)) { if (args->in_use) { retval = _Mix_UnregisterEffect_locked(channel, f); Mix_UnlockAudio(); return(retval); } else { Mix_UnlockAudio(); return(1); } } args->left_u8 = left; args->left_f = ((float) left) / 255.0f; args->right_u8 = right; args->right_f = ((float) right) / 255.0f; args->room_angle = 0; if (!args->in_use) { args->in_use = 1; retval=_Mix_RegisterEffect_locked(channel, f, _Eff_PositionDone, (void*)args); } Mix_UnlockAudio(); return(retval); } int Mix_SetDistance(int channel, Uint8 distance) { Mix_EffectFunc_t f = NULL; Uint16 format; position_args *args = NULL; int channels; int retval = 1; Mix_QuerySpec(NULL, &format, &channels); f = get_position_effect_func(format, channels); if (f == NULL) return(0); Mix_LockAudio(); args = get_position_arg(channel); if (!args) { Mix_UnlockAudio(); return(0); } distance = 255 - distance; /* flip it to our scale. */ /* it's a no-op; unregister the effect, if it's registered. */ if ((distance == 255) && (args->left_u8 == 255) && (args->right_u8 == 255)) { if (args->in_use) { retval = _Mix_UnregisterEffect_locked(channel, f); Mix_UnlockAudio(); return(retval); } else { Mix_UnlockAudio(); return(1); } } args->distance_u8 = distance; args->distance_f = ((float) distance) / 255.0f; if (!args->in_use) { args->in_use = 1; retval = _Mix_RegisterEffect_locked(channel, f, _Eff_PositionDone, (void *) args); } Mix_UnlockAudio(); return(retval); } int Mix_SetPosition(int channel, Sint16 angle, Uint8 distance) { Mix_EffectFunc_t f = NULL; Uint16 format; int channels; position_args *args = NULL; Sint16 room_angle = 0; int retval = 1; Mix_QuerySpec(NULL, &format, &channels); f = get_position_effect_func(format, channels); if (f == NULL) return(0); angle = SDL_abs(angle) % 360; /* make angle between 0 and 359. */ Mix_LockAudio(); args = get_position_arg(channel); if (!args) { Mix_UnlockAudio(); return(0); } /* it's a no-op; unregister the effect, if it's registered. */ if ((!distance) && (!angle)) { if (args->in_use) { retval = _Mix_UnregisterEffect_locked(channel, f); Mix_UnlockAudio(); return(retval); } else { Mix_UnlockAudio(); return(1); } } if (channels == 2) { if (angle > 180) room_angle = 180; /* exchange left and right channels */ else room_angle = 0; } if (channels == 4 || channels == 6) { if (angle > 315) room_angle = 0; else if (angle > 225) room_angle = 270; else if (angle > 135) room_angle = 180; else if (angle > 45) room_angle = 90; else room_angle = 0; } distance = 255 - distance; /* flip it to scale Mix_SetDistance() uses. */ set_amplitudes(channels, angle, room_angle); args->left_u8 = speaker_amplitude[0]; args->left_f = ((float) speaker_amplitude[0]) / 255.0f; args->right_u8 = speaker_amplitude[1]; args->right_f = ((float) speaker_amplitude[1]) / 255.0f; args->left_rear_u8 = speaker_amplitude[2]; args->left_rear_f = ((float) speaker_amplitude[2]) / 255.0f; args->right_rear_u8 = speaker_amplitude[3]; args->right_rear_f = ((float) speaker_amplitude[3]) / 255.0f; args->center_u8 = speaker_amplitude[4]; args->center_f = ((float) speaker_amplitude[4]) / 255.0f; args->lfe_u8 = speaker_amplitude[5]; args->lfe_f = ((float) speaker_amplitude[5]) / 255.0f; args->distance_u8 = distance; args->distance_f = ((float) distance) / 255.0f; args->room_angle = room_angle; if (!args->in_use) { args->in_use = 1; retval = _Mix_RegisterEffect_locked(channel, f, _Eff_PositionDone, (void *) args); } Mix_UnlockAudio(); return(retval); } /* end of effects_position.c ... */