/* * Copyright © 2018 Advanced Micro Devices, Inc. * * 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, sublicense, * 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 NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS 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. */ #ifndef FAST_IDIV_BY_CONST_H #define FAST_IDIV_BY_CONST_H /* Imported from: * https://raw.githubusercontent.com/ridiculousfish/libdivide/master/divide_by_constants_codegen_reference.c */ #include #include #include #ifdef __cplusplus extern "C" { #endif /* Computes "magic info" for performing signed division by a fixed integer D. * The type 'sint_t' is assumed to be defined as a signed integer type large * enough to hold both the dividend and the divisor. * Here >> is arithmetic (signed) shift, and >>> is logical shift. * * To emit code for n/d, rounding towards zero, use the following sequence: * * m = compute_signed_magic_info(D) * emit("result = (m.multiplier * n) >> SINT_BITS"); * if d > 0 and m.multiplier < 0: emit("result += n") * if d < 0 and m.multiplier > 0: emit("result -= n") * if m.post_shift > 0: emit("result >>= m.shift") * emit("result += (result < 0)") * * The shifts by SINT_BITS may be "free" if the high half of the full multiply * is put in a separate register. * * The final add can of course be implemented via the sign bit, e.g. * result += (result >>> (SINT_BITS - 1)) * or * result -= (result >> (SINT_BITS - 1)) * * This code is heavily indebted to Hacker's Delight by Henry Warren. * See http://www.hackersdelight.org/HDcode/magic.c.txt * Used with permission from http://www.hackersdelight.org/permissions.htm */ struct util_fast_sdiv_info { int64_t multiplier; /* the "magic number" multiplier */ unsigned shift; /* shift for the dividend after multiplying */ }; struct util_fast_sdiv_info util_compute_fast_sdiv_info(int64_t D, unsigned SINT_BITS); /* Computes "magic info" for performing unsigned division by a fixed positive * integer D. UINT_BITS is the bit size at which the final "magic" * calculation will be performed; it is assumed to be large enough to hold * both the dividand and the divisor. num_bits can be set appropriately if n * is known to be smaller than calc_bits; if this is not known then UINT_BITS * for num_bits. * * Assume we have a hardware register of width UINT_BITS, a known constant D * which is not zero and not a power of 2, and a variable n of width num_bits * (which may be up to UINT_BITS). To emit code for n/d, use one of the two * following sequences (here >>> refers to a logical bitshift): * * m = compute_unsigned_magic_info(D, num_bits) * if m.pre_shift > 0: emit("n >>>= m.pre_shift") * if m.increment: emit("n = saturated_increment(n)") * emit("result = (m.multiplier * n) >>> UINT_BITS") * if m.post_shift > 0: emit("result >>>= m.post_shift") * * or * * m = compute_unsigned_magic_info(D, num_bits) * if m.pre_shift > 0: emit("n >>>= m.pre_shift") * emit("result = m.multiplier * n") * if m.increment: emit("result = result + m.multiplier") * emit("result >>>= UINT_BITS") * if m.post_shift > 0: emit("result >>>= m.post_shift") * * This second version works even if D is 1. The shifts by UINT_BITS may be * "free" if the high half of the full multiply is put in a separate register. * * saturated_increment(n) means "increment n unless it would wrap to 0," i.e. * if n == (1 << UINT_BITS)-1: result = n * else: result = n+1 * A common way to implement this is with the carry bit. For example, on x86: * add 1 * sbb 0 * * Some invariants: * 1: At least one of pre_shift and increment is zero * 2: multiplier is never zero * * This code incorporates the "round down" optimization per ridiculous_fish. */ struct util_fast_udiv_info { uint64_t multiplier; /* the "magic number" multiplier */ unsigned pre_shift; /* shift for the dividend before multiplying */ unsigned post_shift; /* shift for the dividend after multiplying */ int increment; /* 0 or 1; if set then increment the numerator, using one of the two strategies */ }; struct util_fast_udiv_info util_compute_fast_udiv_info(uint64_t D, unsigned num_bits, unsigned UINT_BITS); /* Below are possible options for dividing by a uniform in a shader where * the divisor is constant but not known at compile time. */ /* Full version. */ static inline uint32_t util_fast_udiv32(uint32_t n, struct util_fast_udiv_info info) { n = n >> info.pre_shift; /* For non-power-of-two divisors, use a 32-bit ADD that clamps to UINT_MAX. */ n = (((uint64_t)n + info.increment) * info.multiplier) >> 32; n = n >> info.post_shift; return n; } /* A little more efficient version if n != UINT_MAX, i.e. no unsigned * wraparound in the computation. */ static inline uint32_t util_fast_udiv32_nuw(uint32_t n, struct util_fast_udiv_info info) { assert(n != UINT32_MAX); n = n >> info.pre_shift; n = n + info.increment; n = ((uint64_t)n * info.multiplier) >> 32; n = n >> info.post_shift; return n; } /* Even faster version but both operands must be 31-bit unsigned integers * and the divisor must be greater than 1. * * info must be computed with num_bits == 31. */ static inline uint32_t util_fast_udiv32_u31_d_not_one(uint32_t n, struct util_fast_udiv_info info) { assert(info.pre_shift == 0); assert(info.increment == 0); n = ((uint64_t)n * info.multiplier) >> 32; n = n >> info.post_shift; return n; } #ifdef __cplusplus } /* extern C */ #endif #endif /* FAST_IDIV_BY_CONST_H */