//===-- arm floating point env manipulation functions -----------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #ifndef LLVM_LIBC_SRC___SUPPORT_FPUTIL_ARM_FENVIMPL_H #define LLVM_LIBC_SRC___SUPPORT_FPUTIL_ARM_FENVIMPL_H #include "hdr/fenv_macros.h" #include "hdr/types/fenv_t.h" #include "src/__support/FPUtil/FPBits.h" #include "src/__support/macros/attributes.h" // For LIBC_INLINE #include "src/__support/macros/config.h" #include namespace LIBC_NAMESPACE_DECL { namespace fputil { struct FEnv { // Arm floating point state is all stored in a single 32-bit register named // fpscr. uint32_t fpscr; static constexpr uint32_t RoundingControlBitPosition = 22; static constexpr uint32_t ExceptionControlBitPosition = 8; static constexpr uint32_t TONEAREST = 0x0; static constexpr uint32_t UPWARD = 0x1; static constexpr uint32_t DOWNWARD = 0x2; static constexpr uint32_t TOWARDZERO = 0x3; static constexpr uint32_t INVALID_ENABLE = 0x1; static constexpr uint32_t DIVBYZERO_ENABLE = 0x2; static constexpr uint32_t OVERFLOW_ENABLE = 0x4; static constexpr uint32_t UNDERFLOW_ENABLE = 0x8; static constexpr uint32_t INEXACT_ENABLE = 0x10; static constexpr uint32_t DENORMAL_ENABLE = 0x20; static constexpr uint32_t INVALID_STATUS = 0x1; static constexpr uint32_t DIVBYZERO_STATUS = 0x2; static constexpr uint32_t OVERFLOW_STATUS = 0x4; static constexpr uint32_t UNDERFLOW_STATUS = 0x8; static constexpr uint32_t INEXACT_STATUS = 0x10; static constexpr uint32_t DENORMAL_STATUS = 0x80; LIBC_INLINE static uint32_t get_fpscr() { return __builtin_arm_get_fpscr(); } LIBC_INLINE static void set_fpscr(uint32_t val) { __builtin_arm_set_fpscr(val); } LIBC_INLINE static int exception_enable_bits_to_macro(uint32_t status) { return ((status & INVALID_ENABLE) ? FE_INVALID : 0) | ((status & DIVBYZERO_ENABLE) ? FE_DIVBYZERO : 0) | ((status & OVERFLOW_ENABLE) ? FE_OVERFLOW : 0) | ((status & UNDERFLOW_ENABLE) ? FE_UNDERFLOW : 0) | ((status & INEXACT_ENABLE) ? FE_INEXACT : 0); } LIBC_INLINE static uint32_t exception_macro_to_enable_bits(int except) { return ((except & FE_INVALID) ? INVALID_ENABLE : 0) | ((except & FE_DIVBYZERO) ? DIVBYZERO_ENABLE : 0) | ((except & FE_OVERFLOW) ? OVERFLOW_ENABLE : 0) | ((except & FE_UNDERFLOW) ? UNDERFLOW_ENABLE : 0) | ((except & FE_INEXACT) ? INEXACT_ENABLE : 0); } LIBC_INLINE static uint32_t exception_macro_to_status_bits(int except) { return ((except & FE_INVALID) ? INVALID_STATUS : 0) | ((except & FE_DIVBYZERO) ? DIVBYZERO_STATUS : 0) | ((except & FE_OVERFLOW) ? OVERFLOW_STATUS : 0) | ((except & FE_UNDERFLOW) ? UNDERFLOW_STATUS : 0) | ((except & FE_INEXACT) ? INEXACT_STATUS : 0); } LIBC_INLINE static uint32_t exception_status_bits_to_macro(int status) { return ((status & INVALID_STATUS) ? FE_INVALID : 0) | ((status & DIVBYZERO_STATUS) ? FE_DIVBYZERO : 0) | ((status & OVERFLOW_STATUS) ? FE_OVERFLOW : 0) | ((status & UNDERFLOW_STATUS) ? FE_UNDERFLOW : 0) | ((status & INEXACT_STATUS) ? FE_INEXACT : 0); } }; // Enables exceptions in |excepts| and returns the previously set exceptions. LIBC_INLINE int enable_except(int excepts) { uint32_t new_excepts = FEnv::exception_macro_to_enable_bits(excepts); uint32_t fpscr = FEnv::get_fpscr(); int old = (fpscr >> FEnv::ExceptionControlBitPosition) & 0x3F; fpscr |= (new_excepts << FEnv::ExceptionControlBitPosition); FEnv::set_fpscr(fpscr); return FEnv::exception_enable_bits_to_macro(old); } // Disables exceptions in |excepts| and returns the previously set exceptions. LIBC_INLINE int disable_except(int excepts) { uint32_t disable_bits = FEnv::exception_macro_to_enable_bits(excepts); uint32_t fpscr = FEnv::get_fpscr(); int old = (fpscr >> FEnv::ExceptionControlBitPosition) & 0x3F; fpscr &= ~(disable_bits << FEnv::ExceptionControlBitPosition); FEnv::set_fpscr(fpscr); return FEnv::exception_enable_bits_to_macro(old); } // Returns the currently enabled exceptions. LIBC_INLINE int get_except() { uint32_t fpscr = FEnv::get_fpscr(); int enabled_excepts = (fpscr >> FEnv::ExceptionControlBitPosition) & 0x3F; return FEnv::exception_enable_bits_to_macro(enabled_excepts); } // Clears the exceptions in |excepts|. LIBC_INLINE int clear_except(int excepts) { uint32_t fpscr = FEnv::get_fpscr(); uint32_t to_clear = FEnv::exception_macro_to_status_bits(excepts); fpscr &= ~to_clear; FEnv::set_fpscr(fpscr); return 0; } // Returns the set of exceptions which are from the input set |excepts|. LIBC_INLINE int test_except(int excepts) { uint32_t to_test = FEnv::exception_macro_to_status_bits(excepts); uint32_t fpscr = FEnv::get_fpscr(); return FEnv::exception_status_bits_to_macro(fpscr & 0x9F & to_test); } // Set the exceptions in |excepts|. LIBC_INLINE int set_except(int excepts) { uint32_t fpscr = FEnv::get_fpscr(); FEnv::set_fpscr(fpscr | FEnv::exception_macro_to_status_bits(excepts)); return 0; } LIBC_INLINE int raise_except(int excepts) { float zero = 0.0f; float one = 1.0f; float large_value = FPBits::max_normal().get_val(); float small_value = FPBits::min_normal().get_val(); auto divfunc = [](float a, float b) { __asm__ __volatile__("flds s0, %0\n\t" "flds s1, %1\n\t" "fdivs s0, s0, s1\n\t" : // No outputs : "m"(a), "m"(b) : "s0", "s1" /* s0 and s1 are clobbered */); }; uint32_t to_raise = FEnv::exception_macro_to_status_bits(excepts); int result = 0; if (to_raise & FEnv::INVALID_STATUS) { divfunc(zero, zero); uint32_t fpscr = FEnv::get_fpscr(); if (!(fpscr & FEnv::INVALID_STATUS)) result = -1; } if (to_raise & FEnv::DIVBYZERO_STATUS) { divfunc(one, zero); uint32_t fpscr = FEnv::get_fpscr(); if (!(fpscr & FEnv::DIVBYZERO_STATUS)) result = -1; } if (to_raise & FEnv::OVERFLOW_STATUS) { divfunc(large_value, small_value); uint32_t fpscr = FEnv::get_fpscr(); if (!(fpscr & FEnv::OVERFLOW_STATUS)) result = -1; } if (to_raise & FEnv::UNDERFLOW_STATUS) { divfunc(small_value, large_value); uint32_t fpscr = FEnv::get_fpscr(); if (!(fpscr & FEnv::UNDERFLOW_STATUS)) result = -1; } if (to_raise & FEnv::INEXACT_STATUS) { float two = 2.0f; float three = 3.0f; // 2.0 / 3.0 cannot be represented exactly in any radix 2 floating point // format. divfunc(two, three); uint32_t fpscr = FEnv::get_fpscr(); if (!(fpscr & FEnv::INEXACT_STATUS)) result = -1; } return result; } LIBC_INLINE int get_round() { uint32_t mode = (FEnv::get_fpscr() >> FEnv::RoundingControlBitPosition) & 0x3; switch (mode) { case FEnv::TONEAREST: return FE_TONEAREST; case FEnv::DOWNWARD: return FE_DOWNWARD; case FEnv::UPWARD: return FE_UPWARD; case FEnv::TOWARDZERO: return FE_TOWARDZERO; default: return -1; // Error value. } return 0; } LIBC_INLINE int set_round(int mode) { uint16_t bits; switch (mode) { case FE_TONEAREST: bits = FEnv::TONEAREST; break; case FE_DOWNWARD: bits = FEnv::DOWNWARD; break; case FE_UPWARD: bits = FEnv::UPWARD; break; case FE_TOWARDZERO: bits = FEnv::TOWARDZERO; break; default: return 1; // To indicate failure } uint32_t fpscr = FEnv::get_fpscr(); fpscr &= ~(0x3 << FEnv::RoundingControlBitPosition); fpscr |= (bits << FEnv::RoundingControlBitPosition); FEnv::set_fpscr(fpscr); return 0; } LIBC_INLINE int get_env(fenv_t *envp) { FEnv *state = reinterpret_cast(envp); state->fpscr = FEnv::get_fpscr(); return 0; } LIBC_INLINE int set_env(const fenv_t *envp) { if (envp == FE_DFL_ENV) { uint32_t fpscr = FEnv::get_fpscr(); // Default status implies: // 1. Round to nearest rounding mode. fpscr &= ~(0x3 << FEnv::RoundingControlBitPosition); fpscr |= (FEnv::TONEAREST << FEnv::RoundingControlBitPosition); // 2. All exceptions are disabled. fpscr &= ~(0x3F << FEnv::ExceptionControlBitPosition); // 3. All exceptions are cleared. There are two reserved bits // at bit 5 and 6 so we just write one full byte (6 bits for // the exceptions, and 2 reserved bits.) fpscr &= ~(static_cast(0xFF)); FEnv::set_fpscr(fpscr); return 0; } const FEnv *state = reinterpret_cast(envp); FEnv::set_fpscr(state->fpscr); return 0; } } // namespace fputil } // namespace LIBC_NAMESPACE_DECL #endif // LLVM_LIBC_SRC___SUPPORT_FPUTIL_ARM_FENVIMPL_H