/************************************************************************** * * Copyright 2007-2008 Tungsten Graphics, Inc., Cedar Park, Texas. * All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sub license, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice (including the * next paragraph) shall be included in all copies or substantial portions * of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. * IN NO EVENT SHALL TUNGSTEN GRAPHICS AND/OR ITS SUPPLIERS BE LIABLE FOR * ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. * **************************************************************************/ #include "pipe/p_config.h" #if defined(PIPE_ARCH_X86) #include "util/u_debug.h" #include "pipe/p_shader_tokens.h" #include "util/u_math.h" #include "util/u_memory.h" #if defined(PIPE_ARCH_SSE) #include "util/u_sse.h" #endif #include "tgsi/tgsi_parse.h" #include "tgsi/tgsi_util.h" #include "tgsi_exec.h" #include "tgsi_sse2.h" #include "rtasm/rtasm_x86sse.h" /* for 1/sqrt() * * This costs about 100fps (close to 10%) in gears: */ #define HIGH_PRECISION 1 #define FAST_MATH 1 #define FOR_EACH_CHANNEL( CHAN )\ for (CHAN = 0; CHAN < NUM_CHANNELS; CHAN++) #define IS_DST0_CHANNEL_ENABLED( INST, CHAN )\ ((INST).FullDstRegisters[0].DstRegister.WriteMask & (1 << (CHAN))) #define IF_IS_DST0_CHANNEL_ENABLED( INST, CHAN )\ if (IS_DST0_CHANNEL_ENABLED( INST, CHAN )) #define FOR_EACH_DST0_ENABLED_CHANNEL( INST, CHAN )\ FOR_EACH_CHANNEL( CHAN )\ IF_IS_DST0_CHANNEL_ENABLED( INST, CHAN ) #define CHAN_X 0 #define CHAN_Y 1 #define CHAN_Z 2 #define CHAN_W 3 #define TEMP_ONE_I TGSI_EXEC_TEMP_ONE_I #define TEMP_ONE_C TGSI_EXEC_TEMP_ONE_C #define TEMP_R0 TGSI_EXEC_TEMP_R0 #define TEMP_ADDR TGSI_EXEC_TEMP_ADDR #define TEMP_EXEC_MASK_I TGSI_EXEC_MASK_I #define TEMP_EXEC_MASK_C TGSI_EXEC_MASK_C /** * X86 utility functions. */ static struct x86_reg make_xmm( unsigned xmm ) { return x86_make_reg( file_XMM, (enum x86_reg_name) xmm ); } /** * X86 register mapping helpers. */ static struct x86_reg get_const_base( void ) { return x86_make_reg( file_REG32, reg_CX ); } static struct x86_reg get_machine_base( void ) { return x86_make_reg( file_REG32, reg_AX ); } static struct x86_reg get_input_base( void ) { return x86_make_disp( get_machine_base(), Offset(struct tgsi_exec_machine, Inputs) ); } static struct x86_reg get_output_base( void ) { return x86_make_disp( get_machine_base(), Offset(struct tgsi_exec_machine, Outputs) ); } static struct x86_reg get_temp_base( void ) { return x86_make_disp( get_machine_base(), Offset(struct tgsi_exec_machine, Temps) ); } static struct x86_reg get_coef_base( void ) { return x86_make_reg( file_REG32, reg_BX ); } static struct x86_reg get_immediate_base( void ) { return x86_make_reg( file_REG32, reg_DX ); } /** * Data access helpers. */ static struct x86_reg get_immediate( unsigned vec, unsigned chan ) { return x86_make_disp( get_immediate_base(), (vec * 4 + chan) * 4 ); } static struct x86_reg get_const( unsigned vec, unsigned chan ) { return x86_make_disp( get_const_base(), (vec * 4 + chan) * 4 ); } static struct x86_reg get_input( unsigned vec, unsigned chan ) { return x86_make_disp( get_input_base(), (vec * 4 + chan) * 16 ); } static struct x86_reg get_output( unsigned vec, unsigned chan ) { return x86_make_disp( get_output_base(), (vec * 4 + chan) * 16 ); } static struct x86_reg get_temp( unsigned vec, unsigned chan ) { return x86_make_disp( get_temp_base(), (vec * 4 + chan) * 16 ); } static struct x86_reg get_coef( unsigned vec, unsigned chan, unsigned member ) { return x86_make_disp( get_coef_base(), ((vec * 3 + member) * 4 + chan) * 4 ); } static void emit_ret( struct x86_function *func ) { x86_ret( func ); } /** * Data fetch helpers. */ /** * Copy a shader constant to xmm register * \param xmm the destination xmm register * \param vec the src const buffer index * \param chan src channel to fetch (X, Y, Z or W) */ static void emit_const( struct x86_function *func, uint xmm, int vec, uint chan, uint indirect, uint indirectFile, int indirectIndex ) { if (indirect) { /* 'vec' is the offset from the address register's value. * We're loading CONST[ADDR+vec] into an xmm register. */ struct x86_reg r0 = get_input_base(); struct x86_reg r1 = get_output_base(); uint i; assert( indirectFile == TGSI_FILE_ADDRESS ); assert( indirectIndex == 0 ); x86_push( func, r0 ); x86_push( func, r1 ); /* * Loop over the four pixels or vertices in the quad. * Get the value of the address (offset) register for pixel/vertex[i], * add it to the src offset and index into the constant buffer. * Note that we're working on SOA data. * If any of the pixel/vertex execution channels are unused their * values will be garbage. It's very important that we don't use * those garbage values as indexes into the constant buffer since * that'll cause segfaults. * The solution is to bitwise-AND the offset with the execution mask * register whose values are either 0 or ~0. * The caller must setup the execution mask register to indicate * which channels are valid/alive before running the shader. * The execution mask will also figure into loops and conditionals * someday. */ for (i = 0; i < QUAD_SIZE; i++) { /* r1 = address register[i] */ x86_mov( func, r1, x86_make_disp( get_temp( TEMP_ADDR, CHAN_X ), i * 4 ) ); /* r0 = execution mask[i] */ x86_mov( func, r0, x86_make_disp( get_temp( TEMP_EXEC_MASK_I, TEMP_EXEC_MASK_C ), i * 4 ) ); /* r1 = r1 & r0 */ x86_and( func, r1, r0 ); /* r0 = 'vec', the offset */ x86_lea( func, r0, get_const( vec, chan ) ); /* Quick hack to multiply r1 by 16 -- need to add SHL to rtasm. */ x86_add( func, r1, r1 ); x86_add( func, r1, r1 ); x86_add( func, r1, r1 ); x86_add( func, r1, r1 ); x86_add( func, r0, r1 ); /* r0 = r0 + r1 */ x86_mov( func, r1, x86_deref( r0 ) ); x86_mov( func, x86_make_disp( get_temp( TEMP_R0, CHAN_X ), i * 4 ), r1 ); } x86_pop( func, r1 ); x86_pop( func, r0 ); sse_movaps( func, make_xmm( xmm ), get_temp( TEMP_R0, CHAN_X ) ); } else { /* 'vec' is the index into the src register file, such as TEMP[vec] */ assert( vec >= 0 ); sse_movss( func, make_xmm( xmm ), get_const( vec, chan ) ); sse_shufps( func, make_xmm( xmm ), make_xmm( xmm ), SHUF( 0, 0, 0, 0 ) ); } } static void emit_immediate( struct x86_function *func, unsigned xmm, unsigned vec, unsigned chan ) { sse_movss( func, make_xmm( xmm ), get_immediate( vec, chan ) ); sse_shufps( func, make_xmm( xmm ), make_xmm( xmm ), SHUF( 0, 0, 0, 0 ) ); } /** * Copy a shader input to xmm register * \param xmm the destination xmm register * \param vec the src input attrib * \param chan src channel to fetch (X, Y, Z or W) */ static void emit_inputf( struct x86_function *func, unsigned xmm, unsigned vec, unsigned chan ) { sse_movups( func, make_xmm( xmm ), get_input( vec, chan ) ); } /** * Store an xmm register to a shader output * \param xmm the source xmm register * \param vec the dest output attrib * \param chan src dest channel to store (X, Y, Z or W) */ static void emit_output( struct x86_function *func, unsigned xmm, unsigned vec, unsigned chan ) { sse_movups( func, get_output( vec, chan ), make_xmm( xmm ) ); } /** * Copy a shader temporary to xmm register * \param xmm the destination xmm register * \param vec the src temp register * \param chan src channel to fetch (X, Y, Z or W) */ static void emit_tempf( struct x86_function *func, unsigned xmm, unsigned vec, unsigned chan ) { sse_movaps( func, make_xmm( xmm ), get_temp( vec, chan ) ); } /** * Load an xmm register with an input attrib coefficient (a0, dadx or dady) * \param xmm the destination xmm register * \param vec the src input/attribute coefficient index * \param chan src channel to fetch (X, Y, Z or W) * \param member 0=a0, 1=dadx, 2=dady */ static void emit_coef( struct x86_function *func, unsigned xmm, unsigned vec, unsigned chan, unsigned member ) { sse_movss( func, make_xmm( xmm ), get_coef( vec, chan, member ) ); sse_shufps( func, make_xmm( xmm ), make_xmm( xmm ), SHUF( 0, 0, 0, 0 ) ); } /** * Data store helpers. */ static void emit_inputs( struct x86_function *func, unsigned xmm, unsigned vec, unsigned chan ) { sse_movups( func, get_input( vec, chan ), make_xmm( xmm ) ); } static void emit_temps( struct x86_function *func, unsigned xmm, unsigned vec, unsigned chan ) { sse_movaps( func, get_temp( vec, chan ), make_xmm( xmm ) ); } static void emit_addrs( struct x86_function *func, unsigned xmm, unsigned vec, unsigned chan ) { assert( vec == 0 ); emit_temps( func, xmm, vec + TGSI_EXEC_TEMP_ADDR, chan ); } /** * Coefficent fetch helpers. */ static void emit_coef_a0( struct x86_function *func, unsigned xmm, unsigned vec, unsigned chan ) { emit_coef( func, xmm, vec, chan, 0 ); } static void emit_coef_dadx( struct x86_function *func, unsigned xmm, unsigned vec, unsigned chan ) { emit_coef( func, xmm, vec, chan, 1 ); } static void emit_coef_dady( struct x86_function *func, unsigned xmm, unsigned vec, unsigned chan ) { emit_coef( func, xmm, vec, chan, 2 ); } /** * Function call helpers. */ /** * NOTE: In gcc, if the destination uses the SSE intrinsics, then it must be * defined with __attribute__((force_align_arg_pointer)), as we do not guarantee * that the stack pointer is 16 byte aligned, as expected. */ static void emit_func_call( struct x86_function *func, unsigned xmm_save, unsigned xmm_dst, void (PIPE_CDECL *code)() ) { struct x86_reg ecx = x86_make_reg( file_REG32, reg_CX ); unsigned i, n; unsigned xmm_mask; /* Bitmask of the xmm registers to save */ xmm_mask = (1 << xmm_save) - 1; xmm_mask &= ~(1 << xmm_dst); x86_push( func, x86_make_reg( file_REG32, reg_AX) ); x86_push( func, x86_make_reg( file_REG32, reg_CX) ); x86_push( func, x86_make_reg( file_REG32, reg_DX) ); /* Store XMM regs to the stack */ for(i = 0, n = 0; i < 8; ++i) if(xmm_mask & (1 << i)) ++n; x86_sub_imm( func, x86_make_reg( file_REG32, reg_SP ), n*16); for(i = 0, n = 0; i < 8; ++i) if(xmm_mask & (1 << i)) { sse_movups( func, x86_make_disp( x86_make_reg( file_REG32, reg_SP ), n*16 ), make_xmm( i ) ); ++n; } /* Load the address of the buffer we use for passing arguments and * receiving results: */ x86_lea( func, ecx, get_temp( TEMP_R0, 0 ) ); /* Push actual function arguments (currently just the pointer to * the buffer above), and call the function: */ x86_push( func, ecx ); x86_mov_reg_imm( func, ecx, (unsigned long) code ); x86_call( func, ecx ); x86_pop(func, ecx ); /* Pop the saved XMM regs: */ for(i = 0, n = 0; i < 8; ++i) if(xmm_mask & (1 << i)) { sse_movups( func, make_xmm( i ), x86_make_disp( x86_make_reg( file_REG32, reg_SP ), n*16 ) ); ++n; } x86_add_imm( func, x86_make_reg( file_REG32, reg_SP ), n*16); /* Restore GP registers in a reverse order. */ x86_pop( func, x86_make_reg( file_REG32, reg_DX) ); x86_pop( func, x86_make_reg( file_REG32, reg_CX) ); x86_pop( func, x86_make_reg( file_REG32, reg_AX) ); } static void emit_func_call_dst_src1( struct x86_function *func, unsigned xmm_save, unsigned xmm_dst, unsigned xmm_src0, void (PIPE_CDECL *code)() ) { /* Store our input parameters (in xmm regs) to the buffer we use * for passing arguments. We will pass a pointer to this buffer as * the actual function argument. */ sse_movaps( func, get_temp( TEMP_R0, 0 ), make_xmm( xmm_src0 ) ); emit_func_call( func, xmm_save, xmm_dst, code ); sse_movaps( func, make_xmm( xmm_dst ), get_temp( TEMP_R0, 0 ) ); } static void emit_func_call_dst_src2( struct x86_function *func, unsigned xmm_save, unsigned xmm_dst, unsigned xmm_src0, unsigned xmm_src1, void (PIPE_CDECL *code)() ) { /* Store two inputs to parameter buffer. */ sse_movaps( func, get_temp( TEMP_R0, 0 ), make_xmm( xmm_src0 ) ); sse_movaps( func, get_temp( TEMP_R0, 1 ), make_xmm( xmm_src1 ) ); /* Emit the call */ emit_func_call( func, xmm_save, xmm_dst, code ); /* Retrieve the results: */ sse_movaps( func, make_xmm( xmm_dst ), get_temp( TEMP_R0, 0 ) ); } #if defined(PIPE_ARCH_SSE) /* * Fast SSE2 implementation of special math functions. */ #define POLY0(x, c0) _mm_set1_ps(c0) #define POLY1(x, c0, c1) _mm_add_ps(_mm_mul_ps(POLY0(x, c1), x), _mm_set1_ps(c0)) #define POLY2(x, c0, c1, c2) _mm_add_ps(_mm_mul_ps(POLY1(x, c1, c2), x), _mm_set1_ps(c0)) #define POLY3(x, c0, c1, c2, c3) _mm_add_ps(_mm_mul_ps(POLY2(x, c1, c2, c3), x), _mm_set1_ps(c0)) #define POLY4(x, c0, c1, c2, c3, c4) _mm_add_ps(_mm_mul_ps(POLY3(x, c1, c2, c3, c4), x), _mm_set1_ps(c0)) #define POLY5(x, c0, c1, c2, c3, c4, c5) _mm_add_ps(_mm_mul_ps(POLY4(x, c1, c2, c3, c4, c5), x), _mm_set1_ps(c0)) #define EXP_POLY_DEGREE 3 #define LOG_POLY_DEGREE 5 /** * See http://www.devmaster.net/forums/showthread.php?p=43580 */ static INLINE __m128 exp2f4(__m128 x) { __m128i ipart; __m128 fpart, expipart, expfpart; x = _mm_min_ps(x, _mm_set1_ps( 129.00000f)); x = _mm_max_ps(x, _mm_set1_ps(-126.99999f)); /* ipart = int(x - 0.5) */ ipart = _mm_cvtps_epi32(_mm_sub_ps(x, _mm_set1_ps(0.5f))); /* fpart = x - ipart */ fpart = _mm_sub_ps(x, _mm_cvtepi32_ps(ipart)); /* expipart = (float) (1 << ipart) */ expipart = _mm_castsi128_ps(_mm_slli_epi32(_mm_add_epi32(ipart, _mm_set1_epi32(127)), 23)); /* minimax polynomial fit of 2**x, in range [-0.5, 0.5[ */ #if EXP_POLY_DEGREE == 5 expfpart = POLY5(fpart, 9.9999994e-1f, 6.9315308e-1f, 2.4015361e-1f, 5.5826318e-2f, 8.9893397e-3f, 1.8775767e-3f); #elif EXP_POLY_DEGREE == 4 expfpart = POLY4(fpart, 1.0000026f, 6.9300383e-1f, 2.4144275e-1f, 5.2011464e-2f, 1.3534167e-2f); #elif EXP_POLY_DEGREE == 3 expfpart = POLY3(fpart, 9.9992520e-1f, 6.9583356e-1f, 2.2606716e-1f, 7.8024521e-2f); #elif EXP_POLY_DEGREE == 2 expfpart = POLY2(fpart, 1.0017247f, 6.5763628e-1f, 3.3718944e-1f); #else #error #endif return _mm_mul_ps(expipart, expfpart); } /** * See http://www.devmaster.net/forums/showthread.php?p=43580 */ static INLINE __m128 log2f4(__m128 x) { __m128i expmask = _mm_set1_epi32(0x7f800000); __m128i mantmask = _mm_set1_epi32(0x007fffff); __m128 one = _mm_set1_ps(1.0f); __m128i i = _mm_castps_si128(x); /* exp = (float) exponent(x) */ __m128 exp = _mm_cvtepi32_ps(_mm_sub_epi32(_mm_srli_epi32(_mm_and_si128(i, expmask), 23), _mm_set1_epi32(127))); /* mant = (float) mantissa(x) */ __m128 mant = _mm_or_ps(_mm_castsi128_ps(_mm_and_si128(i, mantmask)), one); __m128 logmant; /* Minimax polynomial fit of log2(x)/(x - 1), for x in range [1, 2[ * These coefficients can be generate with * http://www.boost.org/doc/libs/1_36_0/libs/math/doc/sf_and_dist/html/math_toolkit/toolkit/internals2/minimax.html */ #if LOG_POLY_DEGREE == 6 logmant = POLY5(mant, 3.11578814719469302614f, -3.32419399085241980044f, 2.59883907202499966007f, -1.23152682416275988241f, 0.318212422185251071475f, -0.0344359067839062357313f); #elif LOG_POLY_DEGREE == 5 logmant = POLY4(mant, 2.8882704548164776201f, -2.52074962577807006663f, 1.48116647521213171641f, -0.465725644288844778798f, 0.0596515482674574969533f); #elif LOG_POLY_DEGREE == 4 logmant = POLY3(mant, 2.61761038894603480148f, -1.75647175389045657003f, 0.688243882994381274313f, -0.107254423828329604454f); #elif LOG_POLY_DEGREE == 3 logmant = POLY2(mant, 2.28330284476918490682f, -1.04913055217340124191f, 0.204446009836232697516f); #else #error #endif /* This effectively increases the polynomial degree by one, but ensures that log2(1) == 0*/ logmant = _mm_mul_ps(logmant, _mm_sub_ps(mant, one)); return _mm_add_ps(logmant, exp); } static INLINE __m128 powf4(__m128 x, __m128 y) { return exp2f4(_mm_mul_ps(log2f4(x), y)); } #endif /* PIPE_ARCH_SSE */ /** * Low-level instruction translators. */ static void emit_abs( struct x86_function *func, unsigned xmm ) { sse_andps( func, make_xmm( xmm ), get_temp( TGSI_EXEC_TEMP_7FFFFFFF_I, TGSI_EXEC_TEMP_7FFFFFFF_C ) ); } static void emit_add( struct x86_function *func, unsigned xmm_dst, unsigned xmm_src ) { sse_addps( func, make_xmm( xmm_dst ), make_xmm( xmm_src ) ); } static void PIPE_CDECL cos4f( float *store ) { store[0] = cosf( store[0] ); store[1] = cosf( store[1] ); store[2] = cosf( store[2] ); store[3] = cosf( store[3] ); } static void emit_cos( struct x86_function *func, unsigned xmm_save, unsigned xmm_dst ) { emit_func_call_dst_src1( func, xmm_save, xmm_dst, xmm_dst, cos4f ); } static void PIPE_CDECL #if defined(PIPE_CC_GCC) && defined(PIPE_ARCH_SSE) __attribute__((force_align_arg_pointer)) #endif ex24f( float *store ) { #if defined(PIPE_ARCH_SSE) _mm_store_ps(&store[0], exp2f4( _mm_load_ps(&store[0]) )); #else store[0] = util_fast_exp2( store[0] ); store[1] = util_fast_exp2( store[1] ); store[2] = util_fast_exp2( store[2] ); store[3] = util_fast_exp2( store[3] ); #endif } static void emit_ex2( struct x86_function *func, unsigned xmm_save, unsigned xmm_dst ) { emit_func_call_dst_src1( func, xmm_save, xmm_dst, xmm_dst, ex24f ); } static void emit_f2it( struct x86_function *func, unsigned xmm ) { sse2_cvttps2dq( func, make_xmm( xmm ), make_xmm( xmm ) ); } static void emit_i2f( struct x86_function *func, unsigned xmm ) { sse2_cvtdq2ps( func, make_xmm( xmm ), make_xmm( xmm ) ); } static void PIPE_CDECL flr4f( float *store ) { store[0] = floorf( store[0] ); store[1] = floorf( store[1] ); store[2] = floorf( store[2] ); store[3] = floorf( store[3] ); } static void emit_flr( struct x86_function *func, unsigned xmm_save, unsigned xmm_dst ) { emit_func_call_dst_src1( func, xmm_save, xmm_dst, xmm_dst, flr4f ); } static void PIPE_CDECL frc4f( float *store ) { store[0] -= floorf( store[0] ); store[1] -= floorf( store[1] ); store[2] -= floorf( store[2] ); store[3] -= floorf( store[3] ); } static void emit_frc( struct x86_function *func, unsigned xmm_save, unsigned xmm_dst ) { emit_func_call_dst_src1( func, xmm_save, xmm_dst, xmm_dst, frc4f ); } static void PIPE_CDECL #if defined(PIPE_CC_GCC) && defined(PIPE_ARCH_SSE) __attribute__((force_align_arg_pointer)) #endif lg24f( float *store ) { #if defined(PIPE_ARCH_SSE) _mm_store_ps(&store[0], log2f4( _mm_load_ps(&store[0]) )); #else store[0] = util_fast_log2( store[0] ); store[1] = util_fast_log2( store[1] ); store[2] = util_fast_log2( store[2] ); store[3] = util_fast_log2( store[3] ); #endif } static void emit_lg2( struct x86_function *func, unsigned xmm_save, unsigned xmm_dst ) { emit_func_call_dst_src1( func, xmm_save, xmm_dst, xmm_dst, lg24f ); } static void emit_MOV( struct x86_function *func, unsigned xmm_dst, unsigned xmm_src ) { sse_movups( func, make_xmm( xmm_dst ), make_xmm( xmm_src ) ); } static void emit_mul (struct x86_function *func, unsigned xmm_dst, unsigned xmm_src) { sse_mulps( func, make_xmm( xmm_dst ), make_xmm( xmm_src ) ); } static void emit_neg( struct x86_function *func, unsigned xmm ) { sse_xorps( func, make_xmm( xmm ), get_temp( TGSI_EXEC_TEMP_80000000_I, TGSI_EXEC_TEMP_80000000_C ) ); } static void PIPE_CDECL #if defined(PIPE_CC_GCC) && defined(PIPE_ARCH_SSE) __attribute__((force_align_arg_pointer)) #endif pow4f( float *store ) { #if defined(PIPE_ARCH_SSE) _mm_store_ps(&store[0], powf4( _mm_load_ps(&store[0]), _mm_load_ps(&store[4]) )); #else store[0] = util_fast_pow( store[0], store[4] ); store[1] = util_fast_pow( store[1], store[5] ); store[2] = util_fast_pow( store[2], store[6] ); store[3] = util_fast_pow( store[3], store[7] ); #endif } static void emit_pow( struct x86_function *func, unsigned xmm_save, unsigned xmm_dst, unsigned xmm_src0, unsigned xmm_src1 ) { emit_func_call_dst_src2( func, xmm_save, xmm_dst, xmm_src0, xmm_src1, pow4f ); } static void emit_rcp ( struct x86_function *func, unsigned xmm_dst, unsigned xmm_src ) { /* On Intel CPUs at least, this is only accurate to 12 bits -- not * good enough. Need to either emit a proper divide or use the * iterative technique described below in emit_rsqrt(). */ sse2_rcpps( func, make_xmm( xmm_dst ), make_xmm( xmm_src ) ); } static void PIPE_CDECL rnd4f( float *store ) { store[0] = floorf( store[0] + 0.5f ); store[1] = floorf( store[1] + 0.5f ); store[2] = floorf( store[2] + 0.5f ); store[3] = floorf( store[3] + 0.5f ); } static void emit_rnd( struct x86_function *func, unsigned xmm_save, unsigned xmm_dst ) { emit_func_call_dst_src1( func, xmm_save, xmm_dst, xmm_dst, rnd4f ); } static void emit_rsqrt( struct x86_function *func, unsigned xmm_dst, unsigned xmm_src ) { #if HIGH_PRECISION /* Although rsqrtps() and rcpps() are low precision on some/all SSE * implementations, it is possible to improve its precision at * fairly low cost, using a newton/raphson step, as below: * * x1 = 2 * rcpps(a) - a * rcpps(a) * rcpps(a) * x1 = 0.5 * rsqrtps(a) * [3.0 - (a * rsqrtps(a))* rsqrtps(a)] * * See: http://softwarecommunity.intel.com/articles/eng/1818.htm */ { struct x86_reg dst = make_xmm( xmm_dst ); struct x86_reg src = make_xmm( xmm_src ); struct x86_reg tmp0 = make_xmm( 2 ); struct x86_reg tmp1 = make_xmm( 3 ); assert( xmm_dst != xmm_src ); assert( xmm_dst != 2 && xmm_dst != 3 ); assert( xmm_src != 2 && xmm_src != 3 ); sse_movaps( func, dst, get_temp( TGSI_EXEC_TEMP_HALF_I, TGSI_EXEC_TEMP_HALF_C ) ); sse_movaps( func, tmp0, get_temp( TGSI_EXEC_TEMP_THREE_I, TGSI_EXEC_TEMP_THREE_C ) ); sse_rsqrtps( func, tmp1, src ); sse_mulps( func, src, tmp1 ); sse_mulps( func, dst, tmp1 ); sse_mulps( func, src, tmp1 ); sse_subps( func, tmp0, src ); sse_mulps( func, dst, tmp0 ); } #else /* On Intel CPUs at least, this is only accurate to 12 bits -- not * good enough. */ sse_rsqrtps( func, make_xmm( xmm_dst ), make_xmm( xmm_src ) ); #endif } static void emit_setsign( struct x86_function *func, unsigned xmm ) { sse_orps( func, make_xmm( xmm ), get_temp( TGSI_EXEC_TEMP_80000000_I, TGSI_EXEC_TEMP_80000000_C ) ); } static void PIPE_CDECL sgn4f( float *store ) { store[0] = store[0] < 0.0f ? -1.0f : store[0] > 0.0f ? 1.0f : 0.0f; store[1] = store[1] < 0.0f ? -1.0f : store[1] > 0.0f ? 1.0f : 0.0f; store[2] = store[2] < 0.0f ? -1.0f : store[2] > 0.0f ? 1.0f : 0.0f; store[3] = store[3] < 0.0f ? -1.0f : store[3] > 0.0f ? 1.0f : 0.0f; } static void emit_sgn( struct x86_function *func, unsigned xmm_save, unsigned xmm_dst ) { emit_func_call_dst_src1( func, xmm_save, xmm_dst, xmm_dst, sgn4f ); } static void PIPE_CDECL sin4f( float *store ) { store[0] = sinf( store[0] ); store[1] = sinf( store[1] ); store[2] = sinf( store[2] ); store[3] = sinf( store[3] ); } static void emit_sin (struct x86_function *func, unsigned xmm_save, unsigned xmm_dst) { emit_func_call_dst_src1( func, xmm_save, xmm_dst, xmm_dst, sin4f ); } static void emit_sub( struct x86_function *func, unsigned xmm_dst, unsigned xmm_src ) { sse_subps( func, make_xmm( xmm_dst ), make_xmm( xmm_src ) ); } /** * Register fetch. */ static void emit_fetch( struct x86_function *func, unsigned xmm, const struct tgsi_full_src_register *reg, const unsigned chan_index ) { unsigned swizzle = tgsi_util_get_full_src_register_extswizzle( reg, chan_index ); switch (swizzle) { case TGSI_EXTSWIZZLE_X: case TGSI_EXTSWIZZLE_Y: case TGSI_EXTSWIZZLE_Z: case TGSI_EXTSWIZZLE_W: switch (reg->SrcRegister.File) { case TGSI_FILE_CONSTANT: emit_const( func, xmm, reg->SrcRegister.Index, swizzle, reg->SrcRegister.Indirect, reg->SrcRegisterInd.File, reg->SrcRegisterInd.Index ); break; case TGSI_FILE_IMMEDIATE: emit_immediate( func, xmm, reg->SrcRegister.Index, swizzle ); break; case TGSI_FILE_INPUT: emit_inputf( func, xmm, reg->SrcRegister.Index, swizzle ); break; case TGSI_FILE_TEMPORARY: emit_tempf( func, xmm, reg->SrcRegister.Index, swizzle ); break; default: assert( 0 ); } break; case TGSI_EXTSWIZZLE_ZERO: emit_tempf( func, xmm, TGSI_EXEC_TEMP_00000000_I, TGSI_EXEC_TEMP_00000000_C ); break; case TGSI_EXTSWIZZLE_ONE: emit_tempf( func, xmm, TEMP_ONE_I, TEMP_ONE_C ); break; default: assert( 0 ); } switch( tgsi_util_get_full_src_register_sign_mode( reg, chan_index ) ) { case TGSI_UTIL_SIGN_CLEAR: emit_abs( func, xmm ); break; case TGSI_UTIL_SIGN_SET: emit_setsign( func, xmm ); break; case TGSI_UTIL_SIGN_TOGGLE: emit_neg( func, xmm ); break; case TGSI_UTIL_SIGN_KEEP: break; } } #define FETCH( FUNC, INST, XMM, INDEX, CHAN )\ emit_fetch( FUNC, XMM, &(INST).FullSrcRegisters[INDEX], CHAN ) /** * Register store. */ static void emit_store( struct x86_function *func, unsigned xmm, const struct tgsi_full_dst_register *reg, const struct tgsi_full_instruction *inst, unsigned chan_index ) { switch( reg->DstRegister.File ) { case TGSI_FILE_OUTPUT: emit_output( func, xmm, reg->DstRegister.Index, chan_index ); break; case TGSI_FILE_TEMPORARY: emit_temps( func, xmm, reg->DstRegister.Index, chan_index ); break; case TGSI_FILE_ADDRESS: emit_addrs( func, xmm, reg->DstRegister.Index, chan_index ); break; default: assert( 0 ); } switch( inst->Instruction.Saturate ) { case TGSI_SAT_NONE: break; case TGSI_SAT_ZERO_ONE: /* assert( 0 ); */ break; case TGSI_SAT_MINUS_PLUS_ONE: assert( 0 ); break; } } #define STORE( FUNC, INST, XMM, INDEX, CHAN )\ emit_store( FUNC, XMM, &(INST).FullDstRegisters[INDEX], &(INST), CHAN ) /** * High-level instruction translators. */ static void emit_kil( struct x86_function *func, const struct tgsi_full_src_register *reg ) { unsigned uniquemask; unsigned registers[4]; unsigned nextregister = 0; unsigned firstchan = ~0; unsigned chan_index; /* This mask stores component bits that were already tested. Note that * we test if the value is less than zero, so 1.0 and 0.0 need not to be * tested. */ uniquemask = (1 << TGSI_EXTSWIZZLE_ZERO) | (1 << TGSI_EXTSWIZZLE_ONE); FOR_EACH_CHANNEL( chan_index ) { unsigned swizzle; /* unswizzle channel */ swizzle = tgsi_util_get_full_src_register_extswizzle( reg, chan_index ); /* check if the component has not been already tested */ if( !(uniquemask & (1 << swizzle)) ) { uniquemask |= 1 << swizzle; /* allocate register */ registers[chan_index] = nextregister; emit_fetch( func, nextregister, reg, chan_index ); nextregister++; /* mark the first channel used */ if( firstchan == ~0 ) { firstchan = chan_index; } } } x86_push( func, x86_make_reg( file_REG32, reg_AX ) ); x86_push( func, x86_make_reg( file_REG32, reg_DX ) ); FOR_EACH_CHANNEL( chan_index ) { if( uniquemask & (1 << chan_index) ) { sse_cmpps( func, make_xmm( registers[chan_index] ), get_temp( TGSI_EXEC_TEMP_00000000_I, TGSI_EXEC_TEMP_00000000_C ), cc_LessThan ); if( chan_index == firstchan ) { sse_pmovmskb( func, x86_make_reg( file_REG32, reg_AX ), make_xmm( registers[chan_index] ) ); } else { sse_pmovmskb( func, x86_make_reg( file_REG32, reg_DX ), make_xmm( registers[chan_index] ) ); x86_or( func, x86_make_reg( file_REG32, reg_AX ), x86_make_reg( file_REG32, reg_DX ) ); } } } x86_or( func, get_temp( TGSI_EXEC_TEMP_KILMASK_I, TGSI_EXEC_TEMP_KILMASK_C ), x86_make_reg( file_REG32, reg_AX ) ); x86_pop( func, x86_make_reg( file_REG32, reg_DX ) ); x86_pop( func, x86_make_reg( file_REG32, reg_AX ) ); } static void emit_kilp( struct x86_function *func ) { /* XXX todo / fix me */ } static void emit_setcc( struct x86_function *func, struct tgsi_full_instruction *inst, enum sse_cc cc ) { unsigned chan_index; FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); FETCH( func, *inst, 1, 1, chan_index ); sse_cmpps( func, make_xmm( 0 ), make_xmm( 1 ), cc ); sse_andps( func, make_xmm( 0 ), get_temp( TEMP_ONE_I, TEMP_ONE_C ) ); STORE( func, *inst, 0, 0, chan_index ); } } static void emit_cmp( struct x86_function *func, struct tgsi_full_instruction *inst ) { unsigned chan_index; FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); FETCH( func, *inst, 1, 1, chan_index ); FETCH( func, *inst, 2, 2, chan_index ); sse_cmpps( func, make_xmm( 0 ), get_temp( TGSI_EXEC_TEMP_00000000_I, TGSI_EXEC_TEMP_00000000_C ), cc_LessThan ); sse_andps( func, make_xmm( 1 ), make_xmm( 0 ) ); sse_andnps( func, make_xmm( 0 ), make_xmm( 2 ) ); sse_orps( func, make_xmm( 0 ), make_xmm( 1 ) ); STORE( func, *inst, 0, 0, chan_index ); } } /** * Check if inst src/dest regs use indirect addressing into temporary * register file. */ static boolean indirect_temp_reference(const struct tgsi_full_instruction *inst) { uint i; for (i = 0; i < inst->Instruction.NumSrcRegs; i++) { const struct tgsi_full_src_register *reg = &inst->FullSrcRegisters[i]; if (reg->SrcRegister.File == TGSI_FILE_TEMPORARY && reg->SrcRegister.Indirect) return TRUE; } for (i = 0; i < inst->Instruction.NumDstRegs; i++) { const struct tgsi_full_dst_register *reg = &inst->FullDstRegisters[i]; if (reg->DstRegister.File == TGSI_FILE_TEMPORARY && reg->DstRegister.Indirect) return TRUE; } return FALSE; } static int emit_instruction( struct x86_function *func, struct tgsi_full_instruction *inst ) { unsigned chan_index; /* we can't handle indirect addressing into temp register file yet */ if (indirect_temp_reference(inst)) return FALSE; switch (inst->Instruction.Opcode) { case TGSI_OPCODE_ARL: FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); emit_flr(func, 0, 0); emit_f2it( func, 0 ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_MOV: case TGSI_OPCODE_SWZ: FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_LIT: if( IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X ) || IS_DST0_CHANNEL_ENABLED( *inst, CHAN_W ) ) { emit_tempf( func, 0, TEMP_ONE_I, TEMP_ONE_C); if( IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X ) ) { STORE( func, *inst, 0, 0, CHAN_X ); } if( IS_DST0_CHANNEL_ENABLED( *inst, CHAN_W ) ) { STORE( func, *inst, 0, 0, CHAN_W ); } } if( IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y ) || IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Z ) ) { if( IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y ) ) { FETCH( func, *inst, 0, 0, CHAN_X ); sse_maxps( func, make_xmm( 0 ), get_temp( TGSI_EXEC_TEMP_00000000_I, TGSI_EXEC_TEMP_00000000_C ) ); STORE( func, *inst, 0, 0, CHAN_Y ); } if( IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Z ) ) { /* XMM[1] = SrcReg[0].yyyy */ FETCH( func, *inst, 1, 0, CHAN_Y ); /* XMM[1] = max(XMM[1], 0) */ sse_maxps( func, make_xmm( 1 ), get_temp( TGSI_EXEC_TEMP_00000000_I, TGSI_EXEC_TEMP_00000000_C ) ); /* XMM[2] = SrcReg[0].wwww */ FETCH( func, *inst, 2, 0, CHAN_W ); /* XMM[2] = min(XMM[2], 128.0) */ sse_minps( func, make_xmm( 2 ), get_temp( TGSI_EXEC_TEMP_128_I, TGSI_EXEC_TEMP_128_C ) ); /* XMM[2] = max(XMM[2], -128.0) */ sse_maxps( func, make_xmm( 2 ), get_temp( TGSI_EXEC_TEMP_MINUS_128_I, TGSI_EXEC_TEMP_MINUS_128_C ) ); emit_pow( func, 3, 1, 1, 2 ); FETCH( func, *inst, 0, 0, CHAN_X ); sse_xorps( func, make_xmm( 2 ), make_xmm( 2 ) ); sse_cmpps( func, make_xmm( 2 ), make_xmm( 0 ), cc_LessThan ); sse_andps( func, make_xmm( 2 ), make_xmm( 1 ) ); STORE( func, *inst, 2, 0, CHAN_Z ); } } break; case TGSI_OPCODE_RCP: /* TGSI_OPCODE_RECIP */ FETCH( func, *inst, 0, 0, CHAN_X ); emit_rcp( func, 0, 0 ); FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_RSQ: /* TGSI_OPCODE_RECIPSQRT */ FETCH( func, *inst, 0, 0, CHAN_X ); emit_abs( func, 0 ); emit_rsqrt( func, 1, 0 ); FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 1, 0, chan_index ); } break; case TGSI_OPCODE_EXP: if (IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X ) || IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y ) || IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Z )) { FETCH( func, *inst, 0, 0, CHAN_X ); if (IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X ) || IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y )) { emit_MOV( func, 1, 0 ); emit_flr( func, 2, 1 ); /* dst.x = ex2(floor(src.x)) */ if (IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X )) { emit_MOV( func, 2, 1 ); emit_ex2( func, 3, 2 ); STORE( func, *inst, 2, 0, CHAN_X ); } /* dst.y = src.x - floor(src.x) */ if (IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y )) { emit_MOV( func, 2, 0 ); emit_sub( func, 2, 1 ); STORE( func, *inst, 2, 0, CHAN_Y ); } } /* dst.z = ex2(src.x) */ if (IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Z )) { emit_ex2( func, 3, 0 ); STORE( func, *inst, 0, 0, CHAN_Z ); } } /* dst.w = 1.0 */ if (IS_DST0_CHANNEL_ENABLED( *inst, CHAN_W )) { emit_tempf( func, 0, TEMP_ONE_I, TEMP_ONE_C ); STORE( func, *inst, 0, 0, CHAN_W ); } break; case TGSI_OPCODE_LOG: if (IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X ) || IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y ) || IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Z )) { FETCH( func, *inst, 0, 0, CHAN_X ); emit_abs( func, 0 ); emit_MOV( func, 1, 0 ); emit_lg2( func, 2, 1 ); /* dst.z = lg2(abs(src.x)) */ if (IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Z )) { STORE( func, *inst, 1, 0, CHAN_Z ); } if (IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X ) || IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y )) { emit_flr( func, 2, 1 ); /* dst.x = floor(lg2(abs(src.x))) */ if (IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X )) { STORE( func, *inst, 1, 0, CHAN_X ); } /* dst.x = abs(src)/ex2(floor(lg2(abs(src.x)))) */ if (IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y )) { emit_ex2( func, 2, 1 ); emit_rcp( func, 1, 1 ); emit_mul( func, 0, 1 ); STORE( func, *inst, 0, 0, CHAN_Y ); } } } /* dst.w = 1.0 */ if (IS_DST0_CHANNEL_ENABLED( *inst, CHAN_W )) { emit_tempf( func, 0, TEMP_ONE_I, TEMP_ONE_C ); STORE( func, *inst, 0, 0, CHAN_W ); } break; case TGSI_OPCODE_MUL: FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); FETCH( func, *inst, 1, 1, chan_index ); emit_mul( func, 0, 1 ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_ADD: FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); FETCH( func, *inst, 1, 1, chan_index ); emit_add( func, 0, 1 ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_DP3: /* TGSI_OPCODE_DOT3 */ FETCH( func, *inst, 0, 0, CHAN_X ); FETCH( func, *inst, 1, 1, CHAN_X ); emit_mul( func, 0, 1 ); FETCH( func, *inst, 1, 0, CHAN_Y ); FETCH( func, *inst, 2, 1, CHAN_Y ); emit_mul( func, 1, 2 ); emit_add( func, 0, 1 ); FETCH( func, *inst, 1, 0, CHAN_Z ); FETCH( func, *inst, 2, 1, CHAN_Z ); emit_mul( func, 1, 2 ); emit_add( func, 0, 1 ); FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_DP4: /* TGSI_OPCODE_DOT4 */ FETCH( func, *inst, 0, 0, CHAN_X ); FETCH( func, *inst, 1, 1, CHAN_X ); emit_mul( func, 0, 1 ); FETCH( func, *inst, 1, 0, CHAN_Y ); FETCH( func, *inst, 2, 1, CHAN_Y ); emit_mul( func, 1, 2 ); emit_add( func, 0, 1 ); FETCH( func, *inst, 1, 0, CHAN_Z ); FETCH( func, *inst, 2, 1, CHAN_Z ); emit_mul(func, 1, 2 ); emit_add(func, 0, 1 ); FETCH( func, *inst, 1, 0, CHAN_W ); FETCH( func, *inst, 2, 1, CHAN_W ); emit_mul( func, 1, 2 ); emit_add( func, 0, 1 ); FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_DST: IF_IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X ) { emit_tempf( func, 0, TEMP_ONE_I, TEMP_ONE_C ); STORE( func, *inst, 0, 0, CHAN_X ); } IF_IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y ) { FETCH( func, *inst, 0, 0, CHAN_Y ); FETCH( func, *inst, 1, 1, CHAN_Y ); emit_mul( func, 0, 1 ); STORE( func, *inst, 0, 0, CHAN_Y ); } IF_IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Z ) { FETCH( func, *inst, 0, 0, CHAN_Z ); STORE( func, *inst, 0, 0, CHAN_Z ); } IF_IS_DST0_CHANNEL_ENABLED( *inst, CHAN_W ) { FETCH( func, *inst, 0, 1, CHAN_W ); STORE( func, *inst, 0, 0, CHAN_W ); } break; case TGSI_OPCODE_MIN: FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); FETCH( func, *inst, 1, 1, chan_index ); sse_minps( func, make_xmm( 0 ), make_xmm( 1 ) ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_MAX: FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); FETCH( func, *inst, 1, 1, chan_index ); sse_maxps( func, make_xmm( 0 ), make_xmm( 1 ) ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_SLT: /* TGSI_OPCODE_SETLT */ emit_setcc( func, inst, cc_LessThan ); break; case TGSI_OPCODE_SGE: /* TGSI_OPCODE_SETGE */ emit_setcc( func, inst, cc_NotLessThan ); break; case TGSI_OPCODE_MAD: /* TGSI_OPCODE_MADD */ FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); FETCH( func, *inst, 1, 1, chan_index ); FETCH( func, *inst, 2, 2, chan_index ); emit_mul( func, 0, 1 ); emit_add( func, 0, 2 ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_SUB: FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); FETCH( func, *inst, 1, 1, chan_index ); emit_sub( func, 0, 1 ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_LERP: /* TGSI_OPCODE_LRP */ FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); FETCH( func, *inst, 1, 1, chan_index ); FETCH( func, *inst, 2, 2, chan_index ); emit_sub( func, 1, 2 ); emit_mul( func, 0, 1 ); emit_add( func, 0, 2 ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_CND: return 0; break; case TGSI_OPCODE_CND0: return 0; break; case TGSI_OPCODE_DOT2ADD: /* TGSI_OPCODE_DP2A */ FETCH( func, *inst, 0, 0, CHAN_X ); /* xmm0 = src[0].x */ FETCH( func, *inst, 1, 1, CHAN_X ); /* xmm1 = src[1].x */ emit_mul( func, 0, 1 ); /* xmm0 = xmm0 * xmm1 */ FETCH( func, *inst, 1, 0, CHAN_Y ); /* xmm1 = src[0].y */ FETCH( func, *inst, 2, 1, CHAN_Y ); /* xmm2 = src[1].y */ emit_mul( func, 1, 2 ); /* xmm1 = xmm1 * xmm2 */ emit_add( func, 0, 1 ); /* xmm0 = xmm0 + xmm1 */ FETCH( func, *inst, 1, 2, CHAN_X ); /* xmm1 = src[2].x */ emit_add( func, 0, 1 ); /* xmm0 = xmm0 + xmm1 */ FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 0, 0, chan_index ); /* dest[ch] = xmm0 */ } break; case TGSI_OPCODE_INDEX: return 0; break; case TGSI_OPCODE_NEGATE: return 0; break; case TGSI_OPCODE_FRAC: /* TGSI_OPCODE_FRC */ FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); emit_frc( func, 0, 0 ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_CLAMP: return 0; break; case TGSI_OPCODE_FLOOR: /* TGSI_OPCODE_FLR */ FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); emit_flr( func, 0, 0 ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_ROUND: FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); emit_rnd( func, 0, 0 ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_EXPBASE2: /* TGSI_OPCODE_EX2 */ FETCH( func, *inst, 0, 0, CHAN_X ); emit_ex2( func, 0, 0 ); FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_LOGBASE2: /* TGSI_OPCODE_LG2 */ FETCH( func, *inst, 0, 0, CHAN_X ); emit_lg2( func, 0, 0 ); FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_POWER: /* TGSI_OPCODE_POW */ FETCH( func, *inst, 0, 0, CHAN_X ); FETCH( func, *inst, 1, 1, CHAN_X ); emit_pow( func, 0, 0, 0, 1 ); FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_CROSSPRODUCT: /* TGSI_OPCODE_XPD */ if( IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X ) || IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y ) ) { FETCH( func, *inst, 1, 1, CHAN_Z ); FETCH( func, *inst, 3, 0, CHAN_Z ); } if( IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X ) || IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Z ) ) { FETCH( func, *inst, 0, 0, CHAN_Y ); FETCH( func, *inst, 4, 1, CHAN_Y ); } IF_IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X ) { emit_MOV( func, 2, 0 ); emit_mul( func, 2, 1 ); emit_MOV( func, 5, 3 ); emit_mul( func, 5, 4 ); emit_sub( func, 2, 5 ); STORE( func, *inst, 2, 0, CHAN_X ); } if( IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y ) || IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Z ) ) { FETCH( func, *inst, 2, 1, CHAN_X ); FETCH( func, *inst, 5, 0, CHAN_X ); } IF_IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y ) { emit_mul( func, 3, 2 ); emit_mul( func, 1, 5 ); emit_sub( func, 3, 1 ); STORE( func, *inst, 3, 0, CHAN_Y ); } IF_IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Z ) { emit_mul( func, 5, 4 ); emit_mul( func, 0, 2 ); emit_sub( func, 5, 0 ); STORE( func, *inst, 5, 0, CHAN_Z ); } IF_IS_DST0_CHANNEL_ENABLED( *inst, CHAN_W ) { emit_tempf( func, 0, TEMP_ONE_I, TEMP_ONE_C ); STORE( func, *inst, 0, 0, CHAN_W ); } break; case TGSI_OPCODE_MULTIPLYMATRIX: return 0; break; case TGSI_OPCODE_ABS: FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); emit_abs( func, 0) ; STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_RCC: return 0; break; case TGSI_OPCODE_DPH: FETCH( func, *inst, 0, 0, CHAN_X ); FETCH( func, *inst, 1, 1, CHAN_X ); emit_mul( func, 0, 1 ); FETCH( func, *inst, 1, 0, CHAN_Y ); FETCH( func, *inst, 2, 1, CHAN_Y ); emit_mul( func, 1, 2 ); emit_add( func, 0, 1 ); FETCH( func, *inst, 1, 0, CHAN_Z ); FETCH( func, *inst, 2, 1, CHAN_Z ); emit_mul( func, 1, 2 ); emit_add( func, 0, 1 ); FETCH( func, *inst, 1, 1, CHAN_W ); emit_add( func, 0, 1 ); FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_COS: FETCH( func, *inst, 0, 0, CHAN_X ); emit_cos( func, 0, 0 ); FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_DDX: return 0; break; case TGSI_OPCODE_DDY: return 0; break; case TGSI_OPCODE_KILP: /* predicated kill */ emit_kilp( func ); return 0; /* XXX fix me */ break; case TGSI_OPCODE_KIL: /* conditional kill */ emit_kil( func, &inst->FullSrcRegisters[0] ); break; case TGSI_OPCODE_PK2H: return 0; break; case TGSI_OPCODE_PK2US: return 0; break; case TGSI_OPCODE_PK4B: return 0; break; case TGSI_OPCODE_PK4UB: return 0; break; case TGSI_OPCODE_RFL: return 0; break; case TGSI_OPCODE_SEQ: return 0; break; case TGSI_OPCODE_SFL: return 0; break; case TGSI_OPCODE_SGT: return 0; break; case TGSI_OPCODE_SIN: FETCH( func, *inst, 0, 0, CHAN_X ); emit_sin( func, 0, 0 ); FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_SLE: return 0; break; case TGSI_OPCODE_SNE: return 0; break; case TGSI_OPCODE_STR: return 0; break; case TGSI_OPCODE_TEX: if (0) { /* Disable dummy texture code: */ emit_tempf( func, 0, TEMP_ONE_I, TEMP_ONE_C ); FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 0, 0, chan_index ); } } else { return 0; } break; case TGSI_OPCODE_TXD: return 0; break; case TGSI_OPCODE_UP2H: return 0; break; case TGSI_OPCODE_UP2US: return 0; break; case TGSI_OPCODE_UP4B: return 0; break; case TGSI_OPCODE_UP4UB: return 0; break; case TGSI_OPCODE_X2D: return 0; break; case TGSI_OPCODE_ARA: return 0; break; case TGSI_OPCODE_ARR: FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); emit_rnd( func, 0, 0 ); emit_f2it( func, 0 ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_BRA: return 0; break; case TGSI_OPCODE_CAL: return 0; break; case TGSI_OPCODE_RET: emit_ret( func ); break; case TGSI_OPCODE_END: break; case TGSI_OPCODE_SSG: /* TGSI_OPCODE_SGN */ FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); emit_sgn( func, 0, 0 ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_CMP: emit_cmp (func, inst); break; case TGSI_OPCODE_SCS: IF_IS_DST0_CHANNEL_ENABLED( *inst, CHAN_X ) { FETCH( func, *inst, 0, 0, CHAN_X ); emit_cos( func, 0, 0 ); STORE( func, *inst, 0, 0, CHAN_X ); } IF_IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Y ) { FETCH( func, *inst, 0, 0, CHAN_X ); emit_sin( func, 0, 0 ); STORE( func, *inst, 0, 0, CHAN_Y ); } IF_IS_DST0_CHANNEL_ENABLED( *inst, CHAN_Z ) { emit_tempf( func, 0, TGSI_EXEC_TEMP_00000000_I, TGSI_EXEC_TEMP_00000000_C ); STORE( func, *inst, 0, 0, CHAN_Z ); } IF_IS_DST0_CHANNEL_ENABLED( *inst, CHAN_W ) { emit_tempf( func, 0, TEMP_ONE_I, TEMP_ONE_C ); STORE( func, *inst, 0, 0, CHAN_W ); } break; case TGSI_OPCODE_TXB: return 0; break; case TGSI_OPCODE_NRM: /* fall-through */ case TGSI_OPCODE_NRM4: /* 3 or 4-component normalization */ { uint dims = (inst->Instruction.Opcode == TGSI_OPCODE_NRM) ? 3 : 4; if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_X) || IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Y) || IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Z) || (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_W) && dims == 4)) { /* NOTE: Cannot use xmm regs 2/3 here (see emit_rsqrt() above). */ /* xmm4 = src.x */ /* xmm0 = src.x * src.x */ FETCH(func, *inst, 0, 0, CHAN_X); if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_X)) { emit_MOV(func, 4, 0); } emit_mul(func, 0, 0); /* xmm5 = src.y */ /* xmm0 = xmm0 + src.y * src.y */ FETCH(func, *inst, 1, 0, CHAN_Y); if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Y)) { emit_MOV(func, 5, 1); } emit_mul(func, 1, 1); emit_add(func, 0, 1); /* xmm6 = src.z */ /* xmm0 = xmm0 + src.z * src.z */ FETCH(func, *inst, 1, 0, CHAN_Z); if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Z)) { emit_MOV(func, 6, 1); } emit_mul(func, 1, 1); emit_add(func, 0, 1); if (dims == 4) { /* xmm7 = src.w */ /* xmm0 = xmm0 + src.w * src.w */ FETCH(func, *inst, 1, 0, CHAN_W); if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_W)) { emit_MOV(func, 7, 1); } emit_mul(func, 1, 1); emit_add(func, 0, 1); } /* xmm1 = 1 / sqrt(xmm0) */ emit_rsqrt(func, 1, 0); /* dst.x = xmm1 * src.x */ if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_X)) { emit_mul(func, 4, 1); STORE(func, *inst, 4, 0, CHAN_X); } /* dst.y = xmm1 * src.y */ if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Y)) { emit_mul(func, 5, 1); STORE(func, *inst, 5, 0, CHAN_Y); } /* dst.z = xmm1 * src.z */ if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_Z)) { emit_mul(func, 6, 1); STORE(func, *inst, 6, 0, CHAN_Z); } /* dst.w = xmm1 * src.w */ if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_X) && dims == 4) { emit_mul(func, 7, 1); STORE(func, *inst, 7, 0, CHAN_W); } } /* dst0.w = 1.0 */ if (IS_DST0_CHANNEL_ENABLED(*inst, CHAN_W) && dims == 3) { emit_tempf(func, 0, TEMP_ONE_I, TEMP_ONE_C); STORE(func, *inst, 0, 0, CHAN_W); } } break; case TGSI_OPCODE_DIV: return 0; break; case TGSI_OPCODE_DP2: FETCH( func, *inst, 0, 0, CHAN_X ); /* xmm0 = src[0].x */ FETCH( func, *inst, 1, 1, CHAN_X ); /* xmm1 = src[1].x */ emit_mul( func, 0, 1 ); /* xmm0 = xmm0 * xmm1 */ FETCH( func, *inst, 1, 0, CHAN_Y ); /* xmm1 = src[0].y */ FETCH( func, *inst, 2, 1, CHAN_Y ); /* xmm2 = src[1].y */ emit_mul( func, 1, 2 ); /* xmm1 = xmm1 * xmm2 */ emit_add( func, 0, 1 ); /* xmm0 = xmm0 + xmm1 */ FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { STORE( func, *inst, 0, 0, chan_index ); /* dest[ch] = xmm0 */ } break; case TGSI_OPCODE_TXL: return 0; break; case TGSI_OPCODE_BRK: return 0; break; case TGSI_OPCODE_IF: return 0; break; case TGSI_OPCODE_LOOP: return 0; break; case TGSI_OPCODE_REP: return 0; break; case TGSI_OPCODE_ELSE: return 0; break; case TGSI_OPCODE_ENDIF: return 0; break; case TGSI_OPCODE_ENDLOOP: return 0; break; case TGSI_OPCODE_ENDREP: return 0; break; case TGSI_OPCODE_PUSHA: return 0; break; case TGSI_OPCODE_POPA: return 0; break; case TGSI_OPCODE_CEIL: return 0; break; case TGSI_OPCODE_I2F: return 0; break; case TGSI_OPCODE_NOT: return 0; break; case TGSI_OPCODE_TRUNC: FOR_EACH_DST0_ENABLED_CHANNEL( *inst, chan_index ) { FETCH( func, *inst, 0, 0, chan_index ); emit_f2it( func, 0 ); emit_i2f( func, 0 ); STORE( func, *inst, 0, 0, chan_index ); } break; case TGSI_OPCODE_SHL: return 0; break; case TGSI_OPCODE_SHR: return 0; break; case TGSI_OPCODE_AND: return 0; break; case TGSI_OPCODE_OR: return 0; break; case TGSI_OPCODE_MOD: return 0; break; case TGSI_OPCODE_XOR: return 0; break; case TGSI_OPCODE_SAD: return 0; break; case TGSI_OPCODE_TXF: return 0; break; case TGSI_OPCODE_TXQ: return 0; break; case TGSI_OPCODE_CONT: return 0; break; case TGSI_OPCODE_EMIT: return 0; break; case TGSI_OPCODE_ENDPRIM: return 0; break; default: return 0; } return 1; } static void emit_declaration( struct x86_function *func, struct tgsi_full_declaration *decl ) { if( decl->Declaration.File == TGSI_FILE_INPUT ) { unsigned first, last, mask; unsigned i, j; first = decl->DeclarationRange.First; last = decl->DeclarationRange.Last; mask = decl->Declaration.UsageMask; for( i = first; i <= last; i++ ) { for( j = 0; j < NUM_CHANNELS; j++ ) { if( mask & (1 << j) ) { switch( decl->Declaration.Interpolate ) { case TGSI_INTERPOLATE_CONSTANT: emit_coef_a0( func, 0, i, j ); emit_inputs( func, 0, i, j ); break; case TGSI_INTERPOLATE_LINEAR: emit_tempf( func, 0, 0, TGSI_SWIZZLE_X ); emit_coef_dadx( func, 1, i, j ); emit_tempf( func, 2, 0, TGSI_SWIZZLE_Y ); emit_coef_dady( func, 3, i, j ); emit_mul( func, 0, 1 ); /* x * dadx */ emit_coef_a0( func, 4, i, j ); emit_mul( func, 2, 3 ); /* y * dady */ emit_add( func, 0, 4 ); /* x * dadx + a0 */ emit_add( func, 0, 2 ); /* x * dadx + y * dady + a0 */ emit_inputs( func, 0, i, j ); break; case TGSI_INTERPOLATE_PERSPECTIVE: emit_tempf( func, 0, 0, TGSI_SWIZZLE_X ); emit_coef_dadx( func, 1, i, j ); emit_tempf( func, 2, 0, TGSI_SWIZZLE_Y ); emit_coef_dady( func, 3, i, j ); emit_mul( func, 0, 1 ); /* x * dadx */ emit_tempf( func, 4, 0, TGSI_SWIZZLE_W ); emit_coef_a0( func, 5, i, j ); emit_rcp( func, 4, 4 ); /* 1.0 / w */ emit_mul( func, 2, 3 ); /* y * dady */ emit_add( func, 0, 5 ); /* x * dadx + a0 */ emit_add( func, 0, 2 ); /* x * dadx + y * dady + a0 */ emit_mul( func, 0, 4 ); /* (x * dadx + y * dady + a0) / w */ emit_inputs( func, 0, i, j ); break; default: assert( 0 ); break; } } } } } } static void aos_to_soa( struct x86_function *func, uint arg_aos, uint arg_machine, uint arg_num, uint arg_stride ) { struct x86_reg soa_input = x86_make_reg( file_REG32, reg_AX ); struct x86_reg aos_input = x86_make_reg( file_REG32, reg_BX ); struct x86_reg num_inputs = x86_make_reg( file_REG32, reg_CX ); struct x86_reg stride = x86_make_reg( file_REG32, reg_DX ); int inner_loop; /* Save EBX */ x86_push( func, x86_make_reg( file_REG32, reg_BX ) ); x86_mov( func, aos_input, x86_fn_arg( func, arg_aos ) ); x86_mov( func, soa_input, x86_fn_arg( func, arg_machine ) ); x86_lea( func, soa_input, x86_make_disp( soa_input, Offset(struct tgsi_exec_machine, Inputs) ) ); x86_mov( func, num_inputs, x86_fn_arg( func, arg_num ) ); x86_mov( func, stride, x86_fn_arg( func, arg_stride ) ); /* do */ inner_loop = x86_get_label( func ); { x86_push( func, aos_input ); sse_movlps( func, make_xmm( 0 ), x86_make_disp( aos_input, 0 ) ); sse_movlps( func, make_xmm( 3 ), x86_make_disp( aos_input, 8 ) ); x86_add( func, aos_input, stride ); sse_movhps( func, make_xmm( 0 ), x86_make_disp( aos_input, 0 ) ); sse_movhps( func, make_xmm( 3 ), x86_make_disp( aos_input, 8 ) ); x86_add( func, aos_input, stride ); sse_movlps( func, make_xmm( 1 ), x86_make_disp( aos_input, 0 ) ); sse_movlps( func, make_xmm( 4 ), x86_make_disp( aos_input, 8 ) ); x86_add( func, aos_input, stride ); sse_movhps( func, make_xmm( 1 ), x86_make_disp( aos_input, 0 ) ); sse_movhps( func, make_xmm( 4 ), x86_make_disp( aos_input, 8 ) ); x86_pop( func, aos_input ); sse_movaps( func, make_xmm( 2 ), make_xmm( 0 ) ); sse_movaps( func, make_xmm( 5 ), make_xmm( 3 ) ); sse_shufps( func, make_xmm( 0 ), make_xmm( 1 ), 0x88 ); sse_shufps( func, make_xmm( 2 ), make_xmm( 1 ), 0xdd ); sse_shufps( func, make_xmm( 3 ), make_xmm( 4 ), 0x88 ); sse_shufps( func, make_xmm( 5 ), make_xmm( 4 ), 0xdd ); sse_movups( func, x86_make_disp( soa_input, 0 ), make_xmm( 0 ) ); sse_movups( func, x86_make_disp( soa_input, 16 ), make_xmm( 2 ) ); sse_movups( func, x86_make_disp( soa_input, 32 ), make_xmm( 3 ) ); sse_movups( func, x86_make_disp( soa_input, 48 ), make_xmm( 5 ) ); /* Advance to next input */ x86_lea( func, aos_input, x86_make_disp(aos_input, 16) ); x86_lea( func, soa_input, x86_make_disp(soa_input, 64) ); } /* while --num_inputs */ x86_dec( func, num_inputs ); x86_jcc( func, cc_NE, inner_loop ); /* Restore EBX */ x86_pop( func, x86_make_reg( file_REG32, reg_BX ) ); } static void soa_to_aos( struct x86_function *func, uint arg_aos, uint arg_machine, uint arg_num, uint arg_stride ) { struct x86_reg soa_output = x86_make_reg( file_REG32, reg_AX ); struct x86_reg aos_output = x86_make_reg( file_REG32, reg_BX ); struct x86_reg num_outputs = x86_make_reg( file_REG32, reg_CX ); struct x86_reg temp = x86_make_reg( file_REG32, reg_DX ); int inner_loop; /* Save EBX */ x86_push( func, x86_make_reg( file_REG32, reg_BX ) ); x86_mov( func, aos_output, x86_fn_arg( func, arg_aos ) ); x86_mov( func, soa_output, x86_fn_arg( func, arg_machine ) ); x86_lea( func, soa_output, x86_make_disp( soa_output, Offset(struct tgsi_exec_machine, Outputs) ) ); x86_mov( func, num_outputs, x86_fn_arg( func, arg_num ) ); /* do */ inner_loop = x86_get_label( func ); { sse_movups( func, make_xmm( 0 ), x86_make_disp( soa_output, 0 ) ); sse_movups( func, make_xmm( 1 ), x86_make_disp( soa_output, 16 ) ); sse_movups( func, make_xmm( 3 ), x86_make_disp( soa_output, 32 ) ); sse_movups( func, make_xmm( 4 ), x86_make_disp( soa_output, 48 ) ); sse_movaps( func, make_xmm( 2 ), make_xmm( 0 ) ); sse_movaps( func, make_xmm( 5 ), make_xmm( 3 ) ); sse_unpcklps( func, make_xmm( 0 ), make_xmm( 1 ) ); sse_unpckhps( func, make_xmm( 2 ), make_xmm( 1 ) ); sse_unpcklps( func, make_xmm( 3 ), make_xmm( 4 ) ); sse_unpckhps( func, make_xmm( 5 ), make_xmm( 4 ) ); x86_mov( func, temp, x86_fn_arg( func, arg_stride ) ); x86_push( func, aos_output ); sse_movlps( func, x86_make_disp( aos_output, 0 ), make_xmm( 0 ) ); sse_movlps( func, x86_make_disp( aos_output, 8 ), make_xmm( 3 ) ); x86_add( func, aos_output, temp ); sse_movhps( func, x86_make_disp( aos_output, 0 ), make_xmm( 0 ) ); sse_movhps( func, x86_make_disp( aos_output, 8 ), make_xmm( 3 ) ); x86_add( func, aos_output, temp ); sse_movlps( func, x86_make_disp( aos_output, 0 ), make_xmm( 2 ) ); sse_movlps( func, x86_make_disp( aos_output, 8 ), make_xmm( 5 ) ); x86_add( func, aos_output, temp ); sse_movhps( func, x86_make_disp( aos_output, 0 ), make_xmm( 2 ) ); sse_movhps( func, x86_make_disp( aos_output, 8 ), make_xmm( 5 ) ); x86_pop( func, aos_output ); /* Advance to next output */ x86_lea( func, aos_output, x86_make_disp(aos_output, 16) ); x86_lea( func, soa_output, x86_make_disp(soa_output, 64) ); } /* while --num_outputs */ x86_dec( func, num_outputs ); x86_jcc( func, cc_NE, inner_loop ); /* Restore EBX */ x86_pop( func, x86_make_reg( file_REG32, reg_BX ) ); } /** * Translate a TGSI vertex/fragment shader to SSE2 code. * Slightly different things are done for vertex vs. fragment shaders. * * \param tokens the TGSI input shader * \param func the output SSE code/function * \param immediates buffer to place immediates, later passed to SSE func * \param return 1 for success, 0 if translation failed */ unsigned tgsi_emit_sse2( const struct tgsi_token *tokens, struct x86_function *func, float (*immediates)[4], boolean do_swizzles ) { struct tgsi_parse_context parse; unsigned ok = 1; uint num_immediates = 0; util_init_math(); func->csr = func->store; tgsi_parse_init( &parse, tokens ); /* Can't just use EDI, EBX without save/restoring them: */ x86_push( func, x86_make_reg( file_REG32, reg_BX ) ); x86_push( func, x86_make_reg( file_REG32, reg_DI ) ); /* * Different function args for vertex/fragment shaders: */ if (parse.FullHeader.Processor.Processor == TGSI_PROCESSOR_VERTEX) { if (do_swizzles) aos_to_soa( func, 4, /* aos_input */ 1, /* machine */ 5, /* num_inputs */ 6 ); /* input_stride */ } x86_mov( func, get_machine_base(), x86_fn_arg( func, 1 ) ); x86_mov( func, get_const_base(), x86_fn_arg( func, 2 ) ); x86_mov( func, get_immediate_base(), x86_fn_arg( func, 3 ) ); if (parse.FullHeader.Processor.Processor == TGSI_PROCESSOR_FRAGMENT) { x86_mov( func, get_coef_base(), x86_fn_arg( func, 4 ) ); } while( !tgsi_parse_end_of_tokens( &parse ) && ok ) { tgsi_parse_token( &parse ); switch( parse.FullToken.Token.Type ) { case TGSI_TOKEN_TYPE_DECLARATION: if (parse.FullHeader.Processor.Processor == TGSI_PROCESSOR_FRAGMENT) { emit_declaration( func, &parse.FullToken.FullDeclaration ); } break; case TGSI_TOKEN_TYPE_INSTRUCTION: ok = emit_instruction( func, &parse.FullToken.FullInstruction ); if (!ok) { debug_printf("failed to translate tgsi opcode %d to SSE (%s)\n", parse.FullToken.FullInstruction.Instruction.Opcode, parse.FullHeader.Processor.Processor == TGSI_PROCESSOR_VERTEX ? "vertex shader" : "fragment shader"); } break; case TGSI_TOKEN_TYPE_IMMEDIATE: /* simply copy the immediate values into the next immediates[] slot */ { const uint size = parse.FullToken.FullImmediate.Immediate.NrTokens - 1; uint i; assert(size <= 4); assert(num_immediates < TGSI_EXEC_NUM_IMMEDIATES); for( i = 0; i < size; i++ ) { immediates[num_immediates][i] = parse.FullToken.FullImmediate.u.ImmediateFloat32[i].Float; } #if 0 debug_printf("SSE FS immediate[%d] = %f %f %f %f\n", num_immediates, immediates[num_immediates][0], immediates[num_immediates][1], immediates[num_immediates][2], immediates[num_immediates][3]); #endif num_immediates++; } break; default: ok = 0; assert( 0 ); } } if (parse.FullHeader.Processor.Processor == TGSI_PROCESSOR_VERTEX) { if (do_swizzles) soa_to_aos( func, 7, /* aos_output */ 1, /* machine */ 8, /* num_outputs */ 9 ); /* output_stride */ } /* Can't just use EBX, EDI without save/restoring them: */ x86_pop( func, x86_make_reg( file_REG32, reg_DI ) ); x86_pop( func, x86_make_reg( file_REG32, reg_BX ) ); emit_ret( func ); tgsi_parse_free( &parse ); return ok; } #endif /* PIPE_ARCH_X86 */