// SPDX-License-Identifier: BSD-2-Clause /* * Copyright (c) 2015, Linaro Limited */ #include #include "platform.h" #include /* * On ARM32 EABI defines both a soft-float ABI and a hard-float ABI, * hard-float is basically a super set of soft-float. Hard-float requires * all the support routines provided for soft-float, but the compiler may * choose to optimize to not use some of them. * * The AEABI functions uses soft-float calling convention even if the * functions are compiled for hard-float. So where float and double would * have been expected we use aeabi_float_t and aeabi_double_t respectively * instead. */ typedef unsigned aeabi_float_t; typedef unsigned long long aeabi_double_t; /* * Helpers to convert between float32 and aeabi_float_t, and float64 and * aeabi_double_t used by the AEABI functions below. */ static aeabi_float_t f32_to_f(float32_t val) { union { float32_t from; aeabi_float_t to; } res = { .from = val }; return res.to; } static float32_t f32_from_f(aeabi_float_t val) { union { aeabi_float_t from; float32_t to; } res = { .from = val }; return res.to; } static aeabi_double_t f64_to_d(float64_t val) { union { float64_t from; aeabi_double_t to; } res = { .from = val }; return res.to; } static float64_t f64_from_d(aeabi_double_t val) { union { aeabi_double_t from; float64_t to; } res = { .from = val }; return res.to; } /* * From ARM Run-time ABI for ARM Architecture * ARM IHI 0043D, current through ABI release 2.09 * * 4.1.2 The floating-point helper functions */ /* * Table 2, Standard aeabi_double_t precision floating-point arithmetic helper * functions */ aeabi_double_t __aeabi_dadd(aeabi_double_t a, aeabi_double_t b) { return f64_to_d(f64_add(f64_from_d(a), f64_from_d(b))); } aeabi_double_t __aeabi_ddiv(aeabi_double_t a, aeabi_double_t b) { return f64_to_d(f64_div(f64_from_d(a), f64_from_d(b))); } aeabi_double_t __aeabi_dmul(aeabi_double_t a, aeabi_double_t b) { return f64_to_d(f64_mul(f64_from_d(a), f64_from_d(b))); } aeabi_double_t __aeabi_drsub(aeabi_double_t a, aeabi_double_t b) { return f64_to_d(f64_sub(f64_from_d(b), f64_from_d(a))); } aeabi_double_t __aeabi_dsub(aeabi_double_t a, aeabi_double_t b) { return f64_to_d(f64_sub(f64_from_d(a), f64_from_d(b))); } /* * Table 3, double precision floating-point comparison helper functions */ int __aeabi_dcmpeq(aeabi_double_t a, aeabi_double_t b) { return f64_eq(f64_from_d(a), f64_from_d(b)); } int __aeabi_dcmplt(aeabi_double_t a, aeabi_double_t b) { return f64_lt(f64_from_d(a), f64_from_d(b)); } int __aeabi_dcmple(aeabi_double_t a, aeabi_double_t b) { return f64_le(f64_from_d(a), f64_from_d(b)); } int __aeabi_dcmpge(aeabi_double_t a, aeabi_double_t b) { return f64_le(f64_from_d(b), f64_from_d(a)); } int __aeabi_dcmpgt(aeabi_double_t a, aeabi_double_t b) { return f64_lt(f64_from_d(b), f64_from_d(a)); } /* * Table 4, Standard single precision floating-point arithmetic helper * functions */ aeabi_float_t __aeabi_fadd(aeabi_float_t a, aeabi_float_t b) { return f32_to_f(f32_add(f32_from_f(a), f32_from_f(b))); } aeabi_float_t __aeabi_fdiv(aeabi_float_t a, aeabi_float_t b) { return f32_to_f(f32_div(f32_from_f(a), f32_from_f(b))); } aeabi_float_t __aeabi_fmul(aeabi_float_t a, aeabi_float_t b) { return f32_to_f(f32_mul(f32_from_f(a), f32_from_f(b))); } aeabi_float_t __aeabi_frsub(aeabi_float_t a, aeabi_float_t b) { return f32_to_f(f32_sub(f32_from_f(b), f32_from_f(a))); } aeabi_float_t __aeabi_fsub(aeabi_float_t a, aeabi_float_t b) { return f32_to_f(f32_sub(f32_from_f(a), f32_from_f(b))); } /* * Table 5, Standard single precision floating-point comparison helper * functions */ int __aeabi_fcmpeq(aeabi_float_t a, aeabi_float_t b) { return f32_eq(f32_from_f(a), f32_from_f(b)); } int __aeabi_fcmplt(aeabi_float_t a, aeabi_float_t b) { return f32_lt(f32_from_f(a), f32_from_f(b)); } int __aeabi_fcmple(aeabi_float_t a, aeabi_float_t b) { return f32_le(f32_from_f(a), f32_from_f(b)); } int __aeabi_fcmpge(aeabi_float_t a, aeabi_float_t b) { return f32_le(f32_from_f(b), f32_from_f(a)); } int __aeabi_fcmpgt(aeabi_float_t a, aeabi_float_t b) { return f32_lt(f32_from_f(b), f32_from_f(a)); } /* * Table 6, Standard floating-point to integer conversions */ int __aeabi_d2iz(aeabi_double_t a) { return f64_to_i32_r_minMag(f64_from_d(a), false); } unsigned __aeabi_d2uiz(aeabi_double_t a) { return f64_to_ui32_r_minMag(f64_from_d(a), false); } long long __aeabi_d2lz(aeabi_double_t a) { return f64_to_i64_r_minMag(f64_from_d(a), false); } unsigned long long __aeabi_d2ulz(aeabi_double_t a) { return f64_to_ui64_r_minMag(f64_from_d(a), false); } int __aeabi_f2iz(aeabi_float_t a) { return f32_to_i32_r_minMag(f32_from_f(a), false); } unsigned __aeabi_f2uiz(aeabi_float_t a) { return f32_to_ui32_r_minMag(f32_from_f(a), false); } long long __aeabi_f2lz(aeabi_float_t a) { return f32_to_i64_r_minMag(f32_from_f(a), false); } unsigned long long __aeabi_f2ulz(aeabi_float_t a) { return f32_to_ui64_r_minMag(f32_from_f(a), false); } /* * Table 7, Standard conversions between floating types */ aeabi_float_t __aeabi_d2f(aeabi_double_t a) { return f32_to_f(f64_to_f32(f64_from_d(a))); } aeabi_double_t __aeabi_f2d(aeabi_float_t a) { return f64_to_d(f32_to_f64(f32_from_f(a))); } /* * Table 8, Standard integer to floating-point conversions */ aeabi_double_t __aeabi_i2d(int a) { return f64_to_d(i32_to_f64(a)); } aeabi_double_t __aeabi_ui2d(unsigned a) { return f64_to_d(ui32_to_f64(a)); } aeabi_double_t __aeabi_l2d(long long a) { return f64_to_d(i64_to_f64(a)); } aeabi_double_t __aeabi_ul2d(unsigned long long a) { return f64_to_d(ui64_to_f64(a)); } aeabi_float_t __aeabi_i2f(int a) { return f32_to_f(i32_to_f32(a)); } aeabi_float_t __aeabi_ui2f(unsigned a) { return f32_to_f(ui32_to_f32(a)); } aeabi_float_t __aeabi_l2f(long long a) { return f32_to_f(i64_to_f32(a)); } aeabi_float_t __aeabi_ul2f(unsigned long long a) { return f32_to_f(ui64_to_f32(a)); }